NZ623279B2 - Compositions and methods of detecting respiratory pathogens using nucleic acid probes and subsets of beads - Google Patents
Compositions and methods of detecting respiratory pathogens using nucleic acid probes and subsets of beads Download PDFInfo
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- NZ623279B2 NZ623279B2 NZ623279A NZ62327912A NZ623279B2 NZ 623279 B2 NZ623279 B2 NZ 623279B2 NZ 623279 A NZ623279 A NZ 623279A NZ 62327912 A NZ62327912 A NZ 62327912A NZ 623279 B2 NZ623279 B2 NZ 623279B2
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- New Zealand
- Prior art keywords
- beads
- amplicon
- primer
- detectable label
- seq
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- C12Q2537/00—Reactions characterised by the reaction format or use of a specific feature
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- C12Q2565/00—Nucleic acid analysis characterised by mode or means of detection
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- C12Q2565/00—Nucleic acid analysis characterised by mode or means of detection
- C12Q2565/50—Detection characterised by immobilisation to a surface
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- C12Q2600/00—Oligonucleotides characterized by their use
- C12Q2600/16—Primer sets for multiplex assays
Abstract
Disclosed is a method of screening a sample for a multiplicity of respiratory pathogens to detect a particular pathogen, the method comprising: (a) isolating nucleic acid from the sample, which nucleic acid comprises nucleic acid from one or more respiratory pathogens; (b) subjecting the nucleic acid to solid phase amplification with primer pairs comprising forward primers of SEQ ID NOs:1 to 16 or 33 or 35 and corresponding reverse primers of SEQ ID NOs:17 to 32 or 33 or 35, and wherein the oligonucleotide probes are selected from the group consisting of SEQ ID NOs:37 to 52 and 34 or 36 or with primer pairs and corresponding probes selected from 2 or more of the sequences listed in Table 8 (SEQ ID NOs:74 to 126 or SEQ ID NOs:53 or 54) amplification; - wherein the sequences are as defined in the complete specification; - wherein an aqueous primer pair directs the amplification of a region of nucleic acid from a respiratory pathogen, the number of primer pairs being selected on the basis of the number of pathogens desired to be screened and wherein at least one member of the primer pair comprises a first optically detectable label that is incorporated into a resulting amplicon following amplification; - wherein the amplicon is captured by hybridising to an oligonucleotide probe that is complementary to a region of the amplicon and immobilised to a bead in a beadset, the beadset having subsets of beads, each subset being homogenous with respect to bead size and, optionally, intensity of a second optically detectable label, thereby creating a heterogeneous beadset based on size and/or second detectable label intensity and wherein the number of subsets corresponds to the number of respiratory pathogens to be screened; (c) determining to which of the beads an amplicon has bound on the basis of the intensity of the first detectable label and, where amplicons are bound to multiple subsets of beads, distinguishing between the multiple subsets of beads on the basis of bead size and, optionally, on the basis of second optically detectable label intensity; - wherein binding of an amplicon to a particular subset of beads is indicative of the presence of a particular respiratory pathogen in the sample. leic acid to solid phase amplification with primer pairs comprising forward primers of SEQ ID NOs:1 to 16 or 33 or 35 and corresponding reverse primers of SEQ ID NOs:17 to 32 or 33 or 35, and wherein the oligonucleotide probes are selected from the group consisting of SEQ ID NOs:37 to 52 and 34 or 36 or with primer pairs and corresponding probes selected from 2 or more of the sequences listed in Table 8 (SEQ ID NOs:74 to 126 or SEQ ID NOs:53 or 54) amplification; - wherein the sequences are as defined in the complete specification; - wherein an aqueous primer pair directs the amplification of a region of nucleic acid from a respiratory pathogen, the number of primer pairs being selected on the basis of the number of pathogens desired to be screened and wherein at least one member of the primer pair comprises a first optically detectable label that is incorporated into a resulting amplicon following amplification; - wherein the amplicon is captured by hybridising to an oligonucleotide probe that is complementary to a region of the amplicon and immobilised to a bead in a beadset, the beadset having subsets of beads, each subset being homogenous with respect to bead size and, optionally, intensity of a second optically detectable label, thereby creating a heterogeneous beadset based on size and/or second detectable label intensity and wherein the number of subsets corresponds to the number of respiratory pathogens to be screened; (c) determining to which of the beads an amplicon has bound on the basis of the intensity of the first detectable label and, where amplicons are bound to multiple subsets of beads, distinguishing between the multiple subsets of beads on the basis of bead size and, optionally, on the basis of second optically detectable label intensity; - wherein binding of an amplicon to a particular subset of beads is indicative of the presence of a particular respiratory pathogen in the sample.
Description
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Compositions and methods of detecting respiratory pathogens
using nucleic acid probes and subsets of beads
FILING DATA
This application is associated with and claims priority from Australian Provisional
Patent Application No. 2011904105, filed on 4 October 2011, entitled "An Assay", the
entire contents of which, are incorporated herein by reference.
FIELD
The present disclosure is instructional for a multiplex nucleic acid amplification
assay to detect and identify multiple respiratory pathogens.
BACKGROUND
Bibliographic details of the publications referred to by author in this specification
are collected alphabetically at the end of the description.
[0004] Reference in this specification to any prior publication (or information derived
from it), or to any matter which is known, is not, and should not be taken as an
acknowledgment or admission or any form of suggestion that that prior publication (or
information derived from it) or known matter forms part of the common general
knowledge in the field of endeavour to which this specification relates.
The Australian Lung Foundation has reported that upper respiratory tract infections
account for approximately 3-4 million visits to general practitioners (G Ps) each year in
Australia, costing taxpayers more than AU$150 million in direct cost and considerably
more in indirect costs. Lower respiratory tract infections account for almost 3 million
visits to GPs each year in Australia. The social and economic impact is further
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compounded by the number of hospitalizations attributed to respiratory infection. For
example, community-acquired pneumonia is associated with an overall mortality rate in
Australia of approximately 12% per annum for hospitalized patients aged greater than 65
years. This mortality rate increases to approximately 20% if co-morbid diseases are present
(e .g. chronic obstructive pulmonary disease, congestive cardiac failure, diabetes).
Furthermore, up to 30,000 hospital admissions for asthma and up to 40,000 hospital
admissions for chronic obstructive pulmonary disease are precipitated by viral infections,
implicated in 50 to 80% of all hospitalizations for asthma and chronic obstructive
pulmonary disease. As a result, the direct and indirect cost burden of in Australia is
estimated to be more than AU$500 million each year.
Etiological agents associated with respiratory infection can be classified into
bacterial (i ncluding Bordetella pertussis), fungal and viral. Influenza types A or B viruses
cause epidemics of disease almost every winter. Seasonal vaccinations (f lu shots) can
prevent illness from Influenza Types A and B, but do not protect against Influenza Type C.
Respiratory syncytial virus (R SV) is the leading cause of acute lower respiratory tract
infections in infants and young children, with the majority of hospitalizations occurring in
infants less than 1 year of age. Worldwide, RSV is believed to be associated with an
annual mortality rate of 160,000-600,000 deaths. Those at increased risk of severe RSV
disease include premature infants, and infants with congenital heart disease, neuromuscular
disease, structural airway abnormalities and immunodeficiencies. Human parainfluenza
viruses (H PIVs) are second only to RSV as a common cause of lower respiratory tract
disease in young children. HPIVs can also cause serious lower respiratory tract disease
with repeat infection, including pneumonia, bronchitis, and bronchiolitis, especially among
the elderly and among patients with compromised immune systems.
Despite the magnitude of respiratory diseases worldwide, treatments are primarily
supportive in nature. The use of bronchodilators, corticosteroids and leukotriene receptor
antagonists ( e.g. montelukast) has generally failed to demonstrate conclusive clinical
benefit and antiviral drugs such as ribavirin have demonstrated only marginal clinical
benefit. Current approaches to the treatment and prevention of respiratory infections
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include second-generation monoclonal antibodies and the highly potent antiviral
compounds such as Oseltamivir (Ta miflu [Registered Trade Mark]) and Zanamivir
(R elenza [Registered Trade Mark]) for the treatment of Influenza. Vaccine compositions
are also in development. However, the effectiveness of existing treatment regimes is
largely dependent on identifying the respiratory pathogen in question. Unfortunately,
given the large number of possible respiratory pathogens and corresponding strains, the use
of standard diagnostics to identify a particular respiratory pathogen in a sample is time-
consuming, costly and frequently leads to incorrect or inconclusive diagnoses. A typical
diagnostic virology laboratory uses viral culture, immunofluorescence staining and
polymerase chain reaction (P CR) to screen for respiratory viruses. However, existing
techniques have significant limitations. For example, viral culture is time-consuming and
lacks the requisite sensitivity for detection, particularly of viruses that are labile during
transport and/or have fastidious growth requirements. Immunofluorescence staining is
insensitive, often leading to false-negative results and current PCR assays typically lack
the high-throughput detection capability to effectively handle a large number of samples
containing multiple targets.
There is a need to develop an assay to screen for multiple respiratory pathogens
with a high level of rapidity and sensitivity.
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SUMMARY
Provided herein is a method of screening a sample for a multiplicity of respiratory
pathogens to detect a particular pathogen, the method comprising:
( a ) isolating nucleic acid from the sample, which nucleic acid putatively
comprises a nucleic acid from one or more respiratory pathogens;
(b ) subjecting the nucleic acid to amplification, wherein an aqueous primer pair
directs the amplification of a region of nucleic acid from a respiratory pathogen, the
number of primer pairs being selected on the basis of the number of pathogens desired to
be screened and wherein at least one member of the primer pair comprises a first optically
detectable label that is incorporated into a resulting amplicon following amplification;
wherein the amplicon is captured by hybridizing to an oligonucleotide probe that is
complementary to a region of the amplicon and immobilized to a bead in a beadset, the
beadset having subsets of beads, each subset being homogenous with respect to bead size
and, optionally, intensity of a second optically detectable label, thereby creating a
heterogeneous beadset based on size and/or second detectable label intensity and wherein
the number of subsets corresponds to the number of respiratory pathogens to be screened;
(c ) determining to which of the beads an amplicon has bound on the basis of
the intensity of the first detectable label and, where amplicons are bound to multiple
subsets of beads, distinguishing between the multiple subsets of beads on the basis of bead
size and, optionally, on the basis of second optically detectable label intensity;
wherein binding of an amplicon to a particular subset of beads is indicative of the presence
of a particular respiratory pathogen in the sample.
[0010] In an embodiment, the amplification is a solid phase amplification.
In an embodiment, the amplicon initiated by extension of the primer comprising the
first optically detectable label serves as a template for hybridization and extension of an
oligonucleotide (he mi-nested primer) comprising a second optically detectable label,
wherein the oligonucleotide is immobilized to a bead in a bead set.
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Further taught is a method of screening a sample for a multiplicity of respiratory
pathogens to detect a particular pathogen, the method comprising:
(a ) isolating nucleic acid from the sample, which nucleic acid putatively
comprises a nucleic acid from one or more respiratory pathogens;
( b ) subjecting the nucleic acid to solid phase amplification; wherein an aqueous
primer pair directs the amplification of a region of nucleic acid from a respiratory
pathogen, the number of primer pairs being selected on the basis of the number of
pathogens desired to be screened and wherein at least one member of the primer pair
comprises a first optically detectable label that is incorporated into a resulting amplicon
following amplification, wherein the resulting amplicon initiated by extension of the
primer comprising the first optically detectable label serves as a template for hybridization
and extension of an oligonucleotide (he mi-nested primer) comprising a second optically
detectable label, wherein the oligonucleotide is immobilized to a bead in a beadset, the
beadset having subsets of beads, each subset being homogenous with respect to bead size
and, optionally, intensity of a second optically detectable label, thereby creating a
heterogeneous beadset based on size and/or second detectable label intensity and wherein
the number of subsets corresponds to the number of respiratory pathogens to be screened;
(c ) determining to which of the beads an amplicon has bound on the basis of
the intensity of the first detectable label and, where amplicons are bound to multiple
subsets of beads, distinguishing between the multiple subsets of beads on the basis of bead
size and, optionally, on the basis of second optically detectable label intensity;
wherein binding of an amplicon to a particular subset of beads is indicative of the
presence of a particular respiratory pathogen in the sample.
[0013] In an embodiment, the method comprises distinguishing between multiple subsets
of beads on the basis of second optically detectable label intensity.
In an embodiment, the respiratory pathogen is selected from the group consisting of
Influenza A, Influenza B, Influenza A H1N1, Influenza A H5N1, Respiratory Syncytial
Virus subtype A, Respiratory Syncytial Virus subtype B, Human Parainfluenza Virus 1,
Human Parainfluenza Virus 2, Human Parainfluenza Virus 3, Human Parainfluenza Virus
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4, Human Metapneumovirus, Human Adenovirus subtype B, Human Adenovirus subtype
C, Human Adenovirus subtype E, Human Enterovirus, Human RhinovirusBordetella
pertussis, Chlamydophila pneumoniae, Mycoplasma pneumoniae and other microbes from
the genera Streptococcus, Haemophilus, Moraxella, Pseudomonas, Klebsiella,
Stenotrophomonas, Acinetobacter, Staphylococcus, Mycoplasma, Legionella,
Chlamydophila, Mycobacterium, Coxiella, Nocardia, Pneumocystis, Nocardia, and
Aspergillus.
In an embodiment, the nucleic acid from the respiratory pathogen is selected from
the group consisting of the gene encoding Segment 7 of Influenza A matrix protein, the
gene encoding Segment 4 of the Influenza B hemagglutinin, the gene encoding Segment 4
of the 2009 H1N1 pandemic strain of Influenza A, the gene encoding Segment 4 of the
H5N1 pandemic strain of Influenza A, polymerase gene of the Respiratory Syncytial Virus
(t ypes A and B), the gene encoding hemagglutinin-neuraminidase glycoprotein of Human
Parainfluenza Virus 1, 2 and 3, phosphoprotein gene of Human Parainfluenza Virus 4, the
gene encoding the M2 region of the matrix protein of Human Metapneumovirus, the gene
encoding the Hexon region of Adenovirus Types B, C and E, 5'UTR region of Human
Rhinovirus/Enterovirus, the Insertion Element ( IS) 481 of Bordetella pertussis, the gene
encoding Major Outer Membrane Protein of Chlamidophila pneumoniae and the gene
encoding P1 Cytadhesin of Mycoplasma pneumoniae.
In an embodiment, the primer pair comprises a forward primer selected from the
group consisting of SEQ ID NOs:1 to 16 and SEQ ID NO:33 and 35 and a corresponding
reverse primer selected from the group consisting of SEQ ID NOs:17 to 32 and SEQ ID
NO:34 and 36.
In an embodiment, the oligonucleotide probe/hemi-nested primer is selected from
the group consisting of SEQ ID NOs:37 to 52. In an embodiment, the oligonucleotide
probe is a control oligonucleotide probe selected from SEQ ID NOs:53 and 54.
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In an embodiment, the method comprises amplifying a control nucleic acid
sequence using a primer pair comprising a forward primer selected from SEQ ID NO:33
and 35 and a corresponding reverse primer selected from SEQ ID NO:34 and 36.
[0019] In an embodiment, the method comprises subjecting the nucleic acid to
amplification conditions with 16 primer pairs comprising forward primers of SEQ ID
NOs:1 to 16 and corresponding reverse primers of SEQ ID NOs:17 to 32, and wherein the
oligonucleotide probes/hemi-nested primers are selected from the group consisting of SEQ
ID NOs:37 to 52.
In an embodiment, the method comprises amplifying a nucleic acid sequence using
a primer pair comprising a forward and reverse primer and corresponding probe selected
from SEQ ID NO:74 to126.
[0021] In an embodiment, the method comprises subjecting the nucleic acid to solid phase
amplification conditions with primer pairs comprising forward and reverse primers and
corresponding probe selected from SEQ ID NOs:74 to 126 and wherein the primers are
hemi-nested primers.
[0022] In an embodiment, the first and second optically detectable labels are fluorophores
selected from the group consisting of hydroxycoumarin, aminocoumarin,
methoxyciumarin, cascade blue, Lucifer yellow, NBD, Phyccerythrin (P E), PerCP,
allophycocyanin, hoechst 33342, DAPl, SYTOX Blue, hoechst 33258, chromomycin A3,
mithramycin, YOYO-I, SYTOX green, SYTOX orange, 7-AAD, acridine orange, TOTO-
1, To-PRO-I, thiazole orange, TOTO-3, TO-PRO-3, LDS 751, Alexa Fluor dyes including
Alexa Fluro-350, -430, -488, -532, -546, -555, -556, -594, -633, -647, -660, -680, -700 and
-750; BoDipy dyes, including BoDipy 630/650 and BoDipy 650/665; CY dyes, particulary
Cy2, Cy3, Cy3.5, Cy5, Cy 5.5 and Cy7; 6-FAM (Fluorescein); PE-Cy5, PE-Cy7,
Fluorescein dT; Hexachlorofluorescein (H ex); 6-carboxy-4', 5'-dichloro-2', T-
dimethoxyfluorescein (J OE); Oregon green dyes, including 488-X and 514; Rhodamine
dyes, including X-Rhodamine, Lissamine Rhodamine B, Rhodamine Green, Rhodamine
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Red and ROX; TRITC Tetramethylrhodamine (TMR ) ; Carboxytetramethylrhodamine
(TA MRA); Tetrachlorofluorescein (TET); Red 6B FluorX, BODIPY-FL and Texas Red.
In an embodiment, the first optically detectable label is AlexaFluor-647.
In an embodiment, the second optically detectable label is boron-dipyrromethene
(B oDipy)-TMR. In an embodiment, the second optically detectable label is attached to the
oligonucleotide probe. In an embodiment, the second optically detectable label is attached
to the oligonucleotide probe via an amino C6 modification of an internal thymidine residue
of the oligonucleotide probe.
In an embodiment, the oligonucleotide probe is a hemi-nested oligonucleotide. In
an embodiment, the oligonucleotide probe is covalently attached to the bead via a thiol or a
methacryl linkage.
In an embodiment, the size of the beads within each subset is selected from the
group consisting of 3.0m, 3.5m, 3.8m, 4. 3m, 5.0m, 5.2m and 5.7m in diameter.
Further taught herein is a kit comprising comprising two or more oligonucleotide
primer pairs selected from SEQ ID NOs:1 and 17, 2 and 18, 3 and 19, 4 and 20, 5 and 21, 6
and 22, 7 and 23, 8 and 24, 9 and 25, 10 and 26, 11 and 27, 12 and 28, 13 and 29, 14 and
, 15 and 31 and 16 and 32 and a corresponding probe selected from SEQ ID NOs:37 to
52, respectively.
[0028] Further taught herein is a kit comprising two or more oligonucleotide primer pairs
and a corresponding primer probe as listed in Table 8 (S EQ ID NOs:74 to 126).
Nucleotide and amino acid sequences are referred to by a sequence identifier
number (S EQ ID NO). A sequence listing is attached to the end of the specification and is
incorporated herein by reference. The SEQ ID NOs correspond numerically to the
sequence identifiers <400>1 (S EQ ID NO:1), <400>2 ( S EQ ID NO:2) etc. A summary of
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the sequence identifiers used throughout the subject specification is provided in Table 1. A
list of these sequences is provided in Table 2.
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Table 1
Summary of sequence identifiers
SEQUENCE
DESCRIPTION
ID NO:
1 Forward primer for segment 7 of influenza A matrix protein
2 Forward primer for segment 4 of influenza B hemagglutinin
3 Forward primer for segment 4 of H1N1
4 Forward primer for segment 4 of H5N1
Froward primer for polymerase gene of Respiratory syncytial virus (t ypes
A and B)
Forward primer for hemagglutinin-neuraminidase glycoprotein of Human
parainfluenza virus 1
Forward primer for primer for hemagglutinin-neuraminidase glycoprotein
of Human parainfluenza virus 2
Forward primer for hemagglutinin-neuraminidase glycoprotein of Human
parainfluenza virus 3
Forward primer for hemagglutinin-neuraminidase glycoprotein of Human
parainfluenza virus 4
Forward primer for gene encoding M2 region of matrix protein of Human
metapneumovirus
Forward primer for gene encoding the Hexon region of Adenovirus types
B and E
12 Forward primer for gene encoding the Hexon region of Adenovirus type C
13 Forward primer of 5'UTR region of Human rhinovirus/enterovirus
14 Forward primer from Bordetella pertussis
Forward primer from Chlamidophila pneumoniae
16 Forward primer from Mycoplasma pneumoniae
17 Reverse primer for segment 7 of influenza A matrix protein
18 Reverse primer for segment 4 of influenza B hemagglutinin
19 Reverse primer for segment 4 of H1N1
Reverse primer for segment 4 of H5N1
Reverse primer for polymerase gene of Respiratory syncytial virus (t ypes
A and B)
Reverse primer for hemagglutinin-neuraminidase glycoprotein of Human
parainfluenza virus 1
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SEQUENCE
DESCRIPTION
ID NO:
Reverse primer for hemagglutinin-neuraminidase glycoprotein of
Human parainfluenza virus 2
Reverse primer for hemagglutinin-neuraminidase glycoprotein of
Human parainfluenza virus 3
Reverse primer for hemagglutinin-neuraminidase glycoprotein of
Human parainfluenza virus 4
Reverse primer for gene encoding M2 region of matrix protein of
Human metapneumovirus
Reverse primer for gene encoding the Hexon region of Adenovirus
types B and E
Reverse primer for gene encoding the Hexon region of Adenovirus type
29 Reverse primer of 5'UTR region of Human rhinovirus/enterovirus
Reverse primer from Bordetella pertussis
31 Reverse primer from Chlamidophila pneumoniae
32 Reverse primer from Mycoplasma pneumoniae
33 Forward primer of MYL3
34 Reverse primer of MYL3
Forward primer of Matrix MS-2
36 Reverse primer of Matrix MS-2
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:1 and 17
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:2 and 18
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:3 and 19
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:4 and 20
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:5 and 21
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:6 and 22
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:7 and 23
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:8 and 24
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:9 and 25
H:\a ar\I nterwoven\N RPortbl\D CC\A AR\7527654_1. DOC-4/03/2015
SEQUENCE
DESCRIPTION
ID NO:
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:10 and 26
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:11 and 27
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:12 and 28
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:13 and 29
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:14 and 30
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:15 and 31
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:16 and 32
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:33 and 34
Oligonucleotide probe complementary to a region of the amplicon
generated by primer pairs SEQ ID NO:35 and 36
55 MS2P (R TI-C1)
56 InA (R TI-C2)
57 InB (R TI-C3)
58 H1 (R TI-C4)
59 H5 (R TI-C5)
60 RSVA (R TI-C5) - Obsolete (se e RTI-C18)
61 RSVB (R TI-C7) - Obsolete (se e RTI-C19)
62 Para1 (R TI-C8)
63 Para2 (R TI-C9)
64 Para3 (R TI-C10)
65 Para4 (R TI-C11)
66 HMPV (R TI-C12)
67 AdV (R TI-C13)
68 Rhino (R TI-C14)
69 B. pertussis IS481 (R TI-C15)
H:\a ar\ I nterwoven\N RPortbl\D CC\A AR\7527654_1. DOC-4/03/2015
SEQUENCE
DESCRIPTION
ID NO:
70 C. peneumoniae (RT I-C16)
71 M. pneumoniae (R TI-C17)
72 RSV-A Pol Control (R TI-C18)
73 RSV-B Pol Control (R TI-C19)
74 Forward primer Am-InfA2
75 Reverse primer InfA2
76 Acry InfA2
77 Forward primer Am-InfB-2
78 Reverse InfB-2
79 Acry AS InfB-2
80 Reverse primer H1N1
81 Forward primer H1N1
82 Acry H1N1
83 Forward primer Am-H5N1
84 Reverse primer H5N1
85 Acry AS-H5N1
86 Forward primer Am-RSV-3
87 Reverse primer RSV-3
88 Acry AS-RSV-3
89 Forward primer Am GB HPIV1
90 Reverse primer GB HPIV1
91 Acry GB HPIV1
92 Forward primer Am-Para2
93 Reverse primer Para2
94 Acry AS-Para2
95 Forward primer Am-Para3
96 Reverse primer Para3
97 Acry AS-Para3
H:\a ar\I nterwoven\N RPortbl\D CC\A AR\7527654_1. DOC-4/03/2015
SEQUENCE
DESCRIPTION
ID NO:
98 Forward primer Am-Para4
99 Reverse primer Para4
100 Acry GB HPIV-4 Pr1
101 Acry GB HPIV-4 Pr2
102 Forward primer Am-hMPV
103 Reverse primer hMPV
104 Acry AS-hMPV
105 Forward primer AdV
106 Reverse primer AdV
107 Acry AdV B/E
108 Acry AdV C
109 Reverse primer truncRhi
110 Forward primer T7truncRhi
111 Acry Rhi
112 Forward primer Bper
113 Reverse primer Bper
114 Acry Bper
115 Forward primer Cpn
116 Reverse primer Cpn
117 Acry Cpn
118 Forward primer Mpneu
119 Reverse primer Mpneu
120 Acry Mpneu
121 Reverse primer MS2-2
122 Forward primer MS2-2
123 Acry MS2-2
124 Forward primer MYL3
H:\a ar\ I nterwoven\N RPortbl\D CC\A AR\7527654_1. DOC-4/03/2015
SEQUENCE
DESCRIPTION
ID NO:
125 Reverse primer MYL3
126 Pap type ProbeMLC_Int Oligonucleotide
127 Forward primer Am-InfA
128 Reverse primer P-InfA
129 AS InfA
130 Forward primer alt Am-InfA
131 Reverse primer P-InfA
132 AS InfA
133 Forward primer InfB
134 Reverse primer InfB
135 InfB
136 Forward primer RSV
137 Reverse primer RSV
138 RSV
139 Forward primer Am-Para1
140 Reverse primer P-Para1
141 AS-Para1
H:\a ar\I nterwoven\ N RPortbl\ D CC\A AR\7527654_1. DOC-4/03/2015
Table 2
Summary of sequences
SEQUENCE ID
DESCRIPTION
1 CGAGGTCGAAACGTAYGTTCTYTCTAT
2 TACGGTGGATTAAACAAAAGCAAGCC
CCCAAGACAAGTTCATGGCCCAATCA
GCTCTGCGATCTAGATGGAGTGAAGCC
ACAGTCAGTAGTAGACCATGTGAATTC
TGGTGATGCAATATATGCGTATTCATC
CYCGTCCTGGAGTCATGCCATGCAA
CAAGTTGGCAYAGCAAGTTACAATTAGGA
GTTGATCAAGACAATACAATTACACTTGA
GACAAATCATMATGTCTCGYAARGCTCC
TGCCSCARTGGKCDTACATGCACATC
TGCCSCARTGGKCDTACATGCACATC
GAAACACGGACACCCAAAGTAGT
CCGGCCGGATGAACACCCATAAGCA
CATGAATGGCAAGTAGGAGCCTCTC
GAACCGAAGCGGCTTTGACCGCATC
GCCATTCCATGAGAGCCTCRAGATC
CAGGAGGTCTATATTTGGTTCCATTGGC
GCTTTTTGCTCCAGCATGAGGACAT
YCTTCTCCACTATGTAAGACCATTCCGG
RTCRATATCTTCATCACCATACTTTTCTGTTA
CCGGGTTTAAATCAGGATACATATCTG
CRTTAAGCGGCCACACATCTGCGT
GTCCCCATGGACATTCATTGTTTCCTGGT
TAAGTGCATCTATACGAACRCCTGCTC
CTATCWGGCCAACTCCAGTAATTGTG
H:\a ar\I nterwoven\N RPortbl\D CC\A AR\7527654_1. DOC-4/03/2015
SEQUENCE ID
DESCRIPTION
GCRCGGGCRAACTGCACCAG
GCRCGGGCRAACTGCACCAG
ACTCACTATAGGAGCCTGCGTGGCKGCC
GGGCCGCTTCAGGCACACAAACTTG
AGTTTTGGCTGAGCAATGCGGATGT
GCGTGGGCGTTTGCGGGTTTAACTT
GCACCCAGACAATACACACAGGTGT
GGCGGAAGTCAGCATGTGTCTG
GCACGCTCCTGCTACAGCCTCTTCC
CTTTTGCAGGACTTCGGTCGACGCC
GAATTCGGATCCAGTCTCTGCGCGATCTCGGCTTTGAG
GAATTCGGATCCGGTGTTTTCACCCATATTGGGCAATT
GAATTCGGATCCCATGCTGCCGTTACACCTTTGTTCG
GAATTCGGATCCCCGAGGAGCCAT CCAGCTACACTAC
GAATTCGGATCCGTTCTATAAGCTGGTATTGATGCAGG
GAATTCGGATCCCCTATATCTGCACATCCTTGAGTGATT
GAATTCGGATCCACCCCTGTGATGCAATTAGCAGGGCA
GAATTCGGATCCAGCACATTATGCCATGTCCATTTTATCC
GAATTCGGATCCGGTTCCAGAYAAWATGGGTCTTGCTA
GAATTCGGATCCTTGCCCCGYACTTCATATTTGCA
GAATTCGGATCCGCTTCGGAGTACCTGAGTCCGGGT
GAATTCGGATCCTCGGGCCAGGACGCCTCGGAGTAC
GAATTCGGATCCTCCTCCGGCCCCTGAATGYGGCTAA
GAATTCGGATCCTGCCCGATTGACCTTCCTACGTCGA
GAATTCGGATCCTGGTCTCGAGCAACTTTTGATGCTG
GAATTCGGATCCGGGCGCGCCTTATACGACCTCGATT
53 AAAGGGAGGACAGCTATGGACCAAACACAGACACAGAGAG
ACCCACAGACA
GAATTCGGATCCGAAGTGCCGCAGAACGTTGCGAACC
H:\a ar\ I nterwoven\N RPortbl\D CC\A AR\7527654_1. DOC-4/03/2015
SEQUENCE ID
DESCRIPTION
55 taatacgactcactatagggagaaattaaccctcactaaagggagagtttcggcttctccctcgacgc
acgctcctgctacagcctcttccctgtaagccaaaacttgacttacatcgaagtgccgcagaacgttg
cgaaccgggcgtcgaccgaagtcctgcaaaaggtcacccagggtaattttaaccttggtgttgcttta
gcagaggccaggtcgacagcctcacaactcgcgacgcaaaccattgcgctcgtgaaggcgtacac
tgccgctcgtcgcggtaattggcgccaggcgctccgctaccttgccctaaacgaagatcgaaagttt
cgatcaaaacacgtggccggcaggtggttggagttgcagttcggttggttaccactaatgagtgcgg
ccgc
56 taatacgactcactatagggagaaattaaccctcactaaagggagactttggccccatggaatgttatc
tcccttttaagcttcctatacagtttaactgctctgtccatgttatttggatccccattcccatttagggcatt
ttggacaaagcgtctacgctgcagtcctcgctcactgggcacggtgagcgtgaacacaaatcctaaa
atccccttagtcagaggtgacaggattggtcttgtctttagccattccatgagagcctcaagatctgtgt
tcttccctgcaaagacatcttcaagtctctgcgcgatctcggctttgagggggcctgacgggacgata
gagagaacgtacgtttcgacctcggttagaagactcatctttcaatatctagcggccgc
57 taatacgactcactatagggagaaattaaccctcactaaagggagacttctaagaaaccagcaatag
ctccgaagaaacccctttcctttaatagttttgcaggaggtctatatttggttccattggcaagcttcaaa
ggtgttttcacccatattgggcaatttcctatggcttttgcatgttctcctgtgtagtaaggcttgcttttgttt
aatccaccgtatttttcgtgaaggcaatctgcttaatttggtcttctccttctgtacaaatgtatggtacttct
actgttagtggattcgttgctgttttgttgttgtcgttctttgggacagcccaagccattgttgcgaaaaat
ccgtttctactggtaacgttagggcaagatcctgaggttccaagtctgtagggtcctcctggtgcctttt
ctgcattgataacgttagcggccgc
58 taatacgactcactatagggagaaattaaccctcactaaagggagatttatcattaatgtaggatttgct
gagctttgggtatgaatttccttttttaactagccatattaaatttttgtagaagctttttgctccagcatgag
gacatgctgccgttacacctttgttcgagtcatgattgggccatgaacttgtcttggggaatatctcaaa
cctttcaaatgatgacactgagctcaattgctctcttagctcctcataatcgatgaaatctcctgggtaac
acgttccattgtctgaactagatgtttccacaatgtaggaccatgagcttgctgtggagagtgattcaca
ctctggatttcccaggatccagccagcaatgttacatttacccaaatgcaatggggctacccctcttag
tttgcatagtttcccgttatgcttgtcttctagaaggttaacagagtgtgttactgttacattcttttctagtac
tgtgtctgcggccgc
59 aatacgactcactatagggagaaattaaccctcactaaagggagacacaaatttaaatgcaaattctg
cattgtaacgatccattggagcacatccataaagatagaccagccaccatgattgccagtgctaggg
aactcgccactgttgaataaattgacagtatttggtaagttcctattgattccaattttatttcagttcttcat
agtcgttgaaattccctgggtaacagaggtcattggctggattggccttctccactatgtaagaccattc
cggcacattgatgaattcgtcacacattgggtttccgaggagccatccagctacactacaatctcttaa
aattagaggcttcactccatctagatcgcagagcttcccgttgtgtgtctgcggccgc
60 taatacgactcactatagggagaaattaaccctcactaaagggagatagaaaatgtctttatgattcca
cgatttttattggatgctgtacatttagttttgccatagcatgacacaatggctcctagagatgtgataac
ggagctgcttacatctgtttttgaagtcataattttgcaatcatatgtgtacctctgtattctcccattatgcc
taggccagcagcattgcctaatactacactggagaagtgaggaaattgagtcaaagacaataatgat
gcttttgggttgttcaatatatggtagaaccctgcttctccacccaatttttgggcatattcatatgctccgt
tggatggtgtatttgctggatgacagaagttgatctttgttgagtgtatcattcaacttgactttgctaaga
gccatttttgtatttgccccatctttcatcttatgtctctccttaattttaaattactataattttcaggctccatt
tgaactatggagtgtggtgcggccgc
H:\a ar\ I nterwoven\N RPortbl\D CC\A AR\7527654_1. DOC-4/03/2015
SEQUENCE
DESCRIPTION
ID NO:
61 taatacgactcactatagggagaaattaaccctcactaaagggagaataatcccacgatttttgttgga
tgcagtgcatttagttttaccatagcatgacactatagctccaagagaagtaattactgagctgcttatgt
ctgtttttgatgtcatatactctcccattatgcctagacctgctgcattgcctaggaccacacttgagaag
ttaggaaattgagttaatgacagcaatgatgcttttggattgttcaatatatggtagaatccagcttctcct
cccaacttctgtgcatactcataattgggagtgtcaatattatctcctgtactacgttgaatagtgtatttg
ctggatgacagcagctgatccttatttaatgtatcatttaacttgactttgctaagagccatctttgtatttg
ccccaatttatgttattggctttacttttatttttaattactaaaacggattagctccttcttaactattgagcat
tgttgtttgaggaatagcttggtttggttgggttggttttttttgttggaatgcggccgc
62 taatacgactcactatagggagaaattaaccctcactaaagggagattgaaccagttgcagtctgggt
ttcctggtcgcgacaggactttatgaggcgcccaattaatggtcatggggttgttgatatctaatgatcc
tatttgcaggttggagtgccaacctgaaccccttgttcctgcagctattacagaacatgatttcctgttgt
cgttgatgtcataggtatgagaaattaccgggtttaaatcaggatacatatctgaatttaaggatatgtaa
cctaattgtaaaacctgatatgacttccctatatctgcacatccttgagtgattaagtttgatgaatacgca
tatattgcatcaccaattgataatgaaggtagtctaacacatcctgaaattgtggtggatccagaaagta
gacttggtccaggtaataatgagagcggccgc
63 taatacgactcactatagggagaaattaaccctcactaaagggagacattaagcggccacacatctg
cgtacacccctgtgatgcaattagcagggcaaaaacttgttgcattgcatggcatgactccaggacg
aggaacttgataggacggtacccattgagcctcaatgatcggagctgcaggattgattgtggcccac
tgccctgttgtatttggaagagatatgactctttcaataaaggtatcattataataatagaaagcaagtct
cagttcagctagatcagtcgtggcataatcttctttttcagaccttgtagctacatagcaatacaagaca
caacctcctggtatagcagtgactgaacagcttttgcgattgattccatcacttaggtaaatggttttcat
agtcctgcggccgc
64 taatacgactcactatagggagaaattaaccctcactaaagggagatggacatgaatgtccccatgg
acattcattgtttcctggtcttgatagcacattatgccatgtccattttatccttatatcactgtagtcagtaa
tgtcaattattcctaattgtaacttgctgtgccaacttgtagatcttgtatatataaagtatgagagatcctg
ggatttaagtcaggtaccaagtctgagtttacagttattatccctatctgtaatacttgatatgattttcctat
atcctgacaacctcgagtaattagatttgaggtgtaagcataaatcaggcggccgc
65 taatacgactcactatagggagaaattaaccctcactaaagggagactgttattttaagtgcatctatac
gaacacctgctcgtctctcatcggttttttgtttggttccagataatatgggtcttgctaatgagtcaagtg
taattgtattgtcttgatcaacaaattttgagacgtctccgttaccagtaacaattataggaacttgttctga
ttctttgtttaaactcctgagacttacttttgatgggactccaggatccattattttcattgttgtgattaagc
cctcaattgtggcaagtgaacctttgatttgttgagtgtcattctttgtttgctgaattgtattttgagtaagc
ataattttgtcaactttcccttcaatcctgtctagtctcacttctaatgccttaattgcggccgc
66 taatacgactcactatagggagaaattaaccctcactaaagggagaggaccatgctcactgcacttg
attagtgctttcactgtcttgcagggcatatgaagagtcattgtcagcgcctgctgataagtcctatctg
gccaactccagtaattgtggttaaacttgcactcacttcctctgttgcatttgccccgcacttcatatttgc
atggagccttgcgagacattatgatttgtcatcctagagctgtgctaatatattgtattcctatttctgcag
catatttgtaatcagtatgtttagcatatagaatttctccacacaaaagtgttatttcttgttgcaatgatga
gggtgtcactgcagttgttgtgcctacatctctttttattgtgtactgagactcttttaatatagcatgcttgt
atgatagatcactcaggtgaatcccttgaagagacattttcgcggccgc
H:\a ar\I nterwoven\N RPortbl\D CC\A AR\7527654_1. DOC-4/03/2015
SEQUENCE
DESCRIPTION
ID NO:
67 taatacgactcactatagggagaaattaaccctcactaaagggagaatggccaccccatcgatgctg
ccccaatgggcatacatgcacatcgccggacaggatgcttcggagtacctgagtccgggtctggtg
cagttcgcccgcgccacagacacctacttcaatctgggaaataagtttagaaatcccaccgtagcgc
cgacccacgatgtgaccaccgaccgtagccagcggctcatgttgcgcttcgtgacttgggacagaa
tatgctctatgccaactcagctcatgctctggacatgacctttgaggtggatcccatggatgagcccac
cctgctttatcttctcttcgaagttttcgacgtggtcagagtgcatcagccacaccgcggcatcatcga
ggcagtctacctgcgtacaccgttctcggccggtaacgctaccacgtaagcggccgc
68 taatacgactcactatagggagaaattaaccctcactaaagggagacaatagtagacctggcagatg
aggctagaaattccccactggcgacagtgttctagcctgcgtggctgcctgcacacccctttttgggc
tgtgaagccatatatttgacaaggtgtgaagagccccgtgtgctcacttttgagtcctccggcccctga
atgtggctaaccttaaccctgcagccattgcacacaatccagtgtgtatctggtcgtaatgagcaattg
cgggatgggaccaactactttgggtgtccgtgtttcattttttttccttttatattttgcttatggtgacaatgt
atatatagtatatatatatttgtcatcatgggcgctcaggtatctagacagaatgttgcggccgc
69 taatacgactcactatagggagaaattaaccctcactaaagggagactaggtgtgaagattcaatagg
ttgtatgcatggttcatccgaaccggatttgagaaactggaaatcgccaaccccccagttcactcaag
gagcccggccggatgaacacccataagcatgcccgattgaccttcctacgtcgactcgaaatggtc
cagcaattgatcgcccatcaagtttgtgtgcctgaagcggcccgcttgctcaccgacaatggctcgg
cctttcgcagccgcgccttcgccgcgctgtgccatgagctgggcatcaagcaccgctttacccgacc
ttaccgcccacagaccaatggcaaggccgaacgcttcatccagtcggccttgcgtgagtgggcttac
gctgcggccgc
70 taatacgactcactatagggagaaattaaccctcactaaagggagacttgcgctacttggtgcgacgc
tattagcttacgtgctggattttacggagactatgttttcgaccgtatcttaaaagtagatgcacctaaaa
cattttctatgggagccaacgctggcgtagcaacagctactggaacaaagtctgcgaccatcaattat
catgaatggcaagtaggagcctctctatcttacagactaaactctttagtgccatacattggagtacaat
ggtctcgagcaacttttgatgctgataacatccgcattgctcagccaaaactacctacagctgttttaaa
cttaactgcatggaacccttctttactaggaaatgccacagcattgtctactactgattcgttctcaggcg
gccgc
71 taatacgactcactatagggagaaattaaccctcactaaagggagagccagcaatttagctacaccc
gccctgacgaggtcgcgctgcgccacaccaatgccatcaacccgcgcttaaccccgtgaacgtatc
gtaacacgagcttttcctccctccccctcacgggtgaaaatcccggggcgtgggccttagtgcgcga
caacagcgctaagggcatcactgccggcagtggcagtcaacaaaccacgtatgatcccacccgaa
ccgaagcggctttgaccgcatcaaccacctttgcgttacgccggtatgacctcgccgggcgcgcctt
atacgacctcgatttttcgaagttaaacccgcaaacgcccacgcgcgaccaaaccgggcagatcac
ctttaacccctttggcggctttggtttgagtggggctgcaccccaacagtgaaacgcggccgc
72 taatacgactcactatagggagaaattaaccctcactaaagggagaaataattctgttaggacatacat
tagtaaattgttctactactgacattaagctaaggccaaagcttatacagttttggaatactatatcaatat
cttcatcaccatacttttctgttaatatgcgattaatagggctagtatcaaagtgataatttgtagttctata
agctggtattgatgcagggaattcacatggtctactactgactgtaaggcgatgcaaatagttaacact
taaatattgtggaaataattttttggctttctcatatgttaacccaagaattcctatgctaaggcggccgc
H:\a ar\I nterwoven\N RPortbl\D CC\A AR\7527654_1. DOC-4/03/2015
SEQUENCE
DESCRIPTION
ID NO:
73 taatacgactcactatagggagaaattaaccctcactaaagggagaataattctattaggacatatgtttg
tgaattgttccacaaccgacatcaggctaagaccaaaacttatgcaattttgaaacacaatgtcgatatct
tcatctccatacttttctgttaatacatgattgataggactagtatcgaaatgataatttgttgttctataagct
ggtattgatgcagggaattcacatggtctactactgactgttaaacggtgtaaataattgacacttagatat
tgtggaaacaactttttggctttttcatatgacagtccaagtgttccagtactcagtgcggccgc
CGAGGTCGAAACGTAYGTTCTYTCTAT
GCCATTCCATGAGAGCCTCRAGATC
AATTGAATTCGGATCCAGTCTCTGCGCGATCTCGGCTTTGAG
TACGGTGGATTAAACAAAAGCAAGCC
CAGGAGGTCTATATTTGGTTCCATTGGC
GAATTCGGATCCGGTGTTTTCACCCATATTGGGCAATT
GCTTTTTGCTCCAGCATGAGGACAT
CCCAAGACAAGTTCATGGCCCAATCA
AATTGAATTCGGATCCCGAACAAAGGTGTAACGGCAGCATG
GCTCTGCGATCTAGATGGAGTGAAGCC
YCTTCTCCACTATGTAAGACCATTCCGG
AATTGAATTCGGATCCCCGAGGAGCCATCCAGCTACACTAC
ACAGTCAGTAGTAGACCATGTGAATTC
RTCRATATCTTCATCACCATACTTTTCTGTTA
AATTGAATTCGGATCCGTTCTATAAGCTGGTATTGATGCAGG
TGGTGATGCAATATATGCGTATTCATC
CCGGGTTTAAATCAGGATACATATCTG
GAATTCGGATCCCCTATATCTGCACATCCTTGAGTGATT
CYCGTCCTGGAGTCATGCCATGCAA
CRTTAAGCGGCCACACATCTGCGT
GAATTCGGATCCACCCCTGTGATGCAATTAGCAGGGCA
CAAGTTGGCAYAGCAAGTTACAATTAGGA
GTCCCCATGGACATTCATTGTTTCCTGGT
GAATTCGGATCCAGCACATTATGCCATGTCCATTTTATCC
GTTGATCAAGACAATACAATTACACTTGA
H:\a ar\I nterwoven\N RPortbl\D CC\A AR\ 7527654_1. DOC-4/03/2015
SEQUENCE
DESCRIPTION
ID NO:
TAAGTGCATCTATACGAACRCCTGCTC
GAATTCGGATCC GGTTCCAGACAAAATGGGTCTTGCTA
GAATTCGGATCC GGTTCCAGATAATATGGGTCTTGCTA
GACAAATCATMATGTCTCGYAARGCTCC
CTATCWGGCCAACTCCAGTAATTGTG
GAATTCGGATCCTTGCCCCGYACTTCATATTTGCA
TGCCSCARTGGKCDTACATGCACATC
GCRCGGGCRAACTGCACCAG
AATTGAATTCGGATCCGCTTCGGAGTACCTGAGTCCGGGT
AATTGAATTCGGATCCTCGGGCCAGGACGCCTCGGAGTAC
GAAACACGGACACCCAAAGTAGT
ACTCACTATAGGAGCCTGCGTGGCKGCC
GAATTCGGATCCTCCTCCGGCCCCTGAATGYGGCTAA
CCGGCCGGATGAACACCCATAAGCA
GGGCCGCTTCAGGCACACAAACTTG
GAATTCGGATCCTGCCCGATTGACCTTCCTACGTCGA
CATGAATGGCAAGTAGGAGCCTCTC
AGTTTTGGCTGAGCAATGCGGATGT
GAATTCGGATCCTGGTCTCGAGCAACTTTTGATGCTG
GAACCGAAGCGGCTTTGACCGCATC
GCGTGGGCGTTTGCGGGTTTAACTT
GAATTCGGATCCGGGCGCGCCTTATACGACCTCGATT
CTTTTGCAGGACTTCGGTCGACGCC
GCACGCTCCTGCTACAGCCTCTTCC
AATTGAATTCGGATCCGAAGTGCCGCAGAACGTTGCGAACC
GCACCCAGACAATACACACAGGTGT
GGCGGAAGTCAGCATGTGTCTG
126 AAAGGGAGGACAGCTATGGACCAAACACAGACACAGAGAGA
CCCACAGACA
TRGGRTTTGTGTTCACGCTCACCGTG
H:\a ar\I nterwoven\N RPortbl\D CC\A AR\7527654_1. DOC-4/03/2015
SEQUENCE
DESCRIPTION
ID NO:
GGGCATTTTGGACAAAGCGTCTACGC
GAATTCGGATCCTGCAGTCCTCGCTCACTGGGCA
GACAAGACCAATCCTGTCACCTCTGAC
GGGCATTTTGGACAAAGCGTCTACGC
GAATTCGGATCCTGCAGTCCTCGCTCACTGGGCA
GCACCAGGAGGACCCTACARAMTTGGA
TTGGGACRGCCCAAGCCATTGTTGCG
ACCTCAGGRTCTTGCCCTAACGYTACCA
TTGGGWGGAGAAGCWGGWTTCTACCA
ATTATGCCTAGRCCWGCWGCATTGCC
ARYARTGATGCTTTTGGRTTGTTCAATAT
TGGCACTCCAACCTGCAAATAGGATCA
CCAGTTGCAGTCTTGGTTTCCTGGTCG
GAATTCGGATCCACAGGACTTYATGAGGCGCCCA
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BRIEF DESCRIPTION OF THE FIGURES
Figures 1A through D show the control construct insert sequences and their
identifiers.
Figure 2 is a photographical representation showing the confirmation of the
identity of RNA templates by specific RT-PCR.
Figure 3 is a photographical representation showing primer concentrations
resulting in efficient amplification of all target DNA templates.
Figure 4 is a photographical representation showing primer conditions resulting in
efficient amplification of RNA and DNA templates.
[0034] Figures 5A and B are photographical representations showing RT-PCR
amplification profiles in the absence or presence of background human chromosomal
DNA.
Figure 6 is a graphical representation showing an overview of the general primer
design process.
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DETAILED DESCRIPTION
Throughout this specification, unless the context requires otherwise, the word
"comprise" or variations such as "comprises" or "comprising", will be understood to imply
the inclusion of a stated element or integer or method step or group of elements or integers
or method steps but not the exclusion of any element or integer or method step or group of
elements or integers or method steps.
[0037] As used in the subject specification, the singular forms "a", "an" and "the" include
singular and plural aspects unless the context clearly dictates otherwise. Thus, for example,
reference to "a respiratory pathogen" includes a single respiratory pathogen, as well as two
or more different respiratory pathogens; reference to "an agent" includes a single agent, as
well as two or more agents; reference to "the disclosure" includes a single or multiple
aspects taught by the disclosure. The aspects taught herein are encompassed by the term
"invention". All such aspects are enabled within the width of the claims.
The present disclosure teaches the detection and differentiation of multiple
respiratory pathogens in a sample.
Enabled herein is a method of screening a sample for a multiplicity of respiratory
pathogens to detect a particular pathogen, the method comprising:
(a ) isolating nucleic acid from the sample, which nucleic acid putatively
comprises a nucleic acid from one or more respiratory pathogens;
(b ) subjecting the nucleic acid to amplification, wherein an aqueous primer pair
directs the amplification of a region of nucleic acid from a respiratory pathogen, the
number of primer pairs being selected on the basis of the number of pathogens desired to
be screened and wherein at least one member of the primer pair comprises a first optically
detectable label that is incorporated into a resulting amplicon following amplification;
wherein the amplicon is captured by hybridizing to an oligonucleotide probe that is
complementary to a region of the amplicon and immobilized to a bead in a beadset, the
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beadset having subsets of beads, each subset being homogenous with respect to bead size
and, optionally, intensity of a second optically detectable label, thereby creating a
heterogeneous beadset based on size and/or second detectable label intensity and wherein
the number of subsets corresponds to the number of respiratory pathogens to be screened;
( c ) determining to which of the beads an amplicon has bound on the basis of
the intensity of the first detectable label and, where amplicons are bound to multiple
subsets of beads, distinguishing between the multiple subsets of beads on the basis of bead
size and, optionally, on the basis of second optically detectable label intensity;
wherein binding of an amplicon to a particular subset of beads is indicative of the
presence of a particular respiratory pathogen in the sample.
In an embodiment, the amplification is a solid phase amplification.
In an embodiment, the amplicon initiated by extension of the primer comprising the
first optically detectable label serves as a template for hybridization and extension of an
oligonucleotide (he mi-nested primer) comprising a second optically detectable label,
wherein the oligonucleotide is immobilized to a bead in a beast set.
Further enabled is a method of screening a sample for a multiplicity of respiratory
pathogens to detect a particular pathogen, the method comprising:
(a ) isolating nucleic acid from the sample, which nucleic acid putatively
comprises a nucleic acid from one or more respiratory pathogens;
(b ) subjecting the nucleic acid to solid phase amplification; wherein an aqueous
primer pair directs the amplification of a region of nucleic acid from a respiratory
pathogen, the number of primer pairs being selected on the basis of the number of
pathogens desired to be screened and wherein at least one member of the primer pair
comprises a first optically detectable label that is incorporated into a resulting amplicon
following amplification, wherein the resulting amplicon initiated by extension of the
primer comprising the first optically detectable label serves as a template for hybridization
and extension of an oligonucleotide (he mi-nested primer) comprising a second optically
detectable label, wherein the oligonucleotide is immobilized to a bead in a beadset, the
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beadset having subsets of beads, each subset being homogenous with respect to bead size
and, optionally, intensity of a second optically detectable label, thereby creating a
heterogeneous beadset based on size and/or second detectable label intensity and wherein
the number of subsets corresponds to the number of respiratory pathogens to be screened;
( c ) determining to which of the beads an amplicon has bound on the basis of
the intensity of the first detectable label and, where amplicons are bound to multiple
subsets of beads, distinguishing between the multiple subsets of beads on the basis of bead
size and, optionally, on the basis of second optically detectable label intensity;
wherein binding of an amplicon to a particular subset of beads is indicative of the
presence of a particular respiratory pathogen in the sample.
The term "pathogen" refers to a microorganism or virus that is capable of
infecting or colonizing a host. A host may be a single cell or a subject comprising a
multiplicity of cells. Hence, a "host" includes a subject. Exemplary pathogens include
viruses, bacteria, fungi and eukaryotic microorganisms. A "respiratory pathogen" refers to
a pathogen that is capable of infecting or colonizing the respiratory tract of a host, also
referred to herein as a colonizing pathogen, an indigenous pathogen, a commensal
pathogen or a commensal organism. It will be understood by those skilled in the art that a
pathogen can be present in a healthy subject free from infection. In the normal, healthy
state, these pathogens do not cause infection while the subject does not develop respiratory
symptoms. However, following a trigger (e .g., poor health, stress), the pathogen can
become a causative pathogen of a chronic/acute respiratory infection.
Respiratory pathogens are known to those skilled in the art. Examples include,
but are not limited to, Influenza A, Influenza B, Influenza A H1N1, Influenza A H5N1,
Respiratory Syncytial Virus subtype A, Respiratory Syncytial Virus subtype B, Human
Parainfluenza Virus 1, Human Parainfluenza Virus 2, Human Parainfluenza Virus 3,
Human Parainfluenza Virus 4, Human Metapneumovirus, Human Adenovirus subtype B,
Human Adenovirus subtype C, Human Adenovirus subtype E, Human Enterovirus, Human
Rhinovirus, Bordetella pertussis, Chlamydophila pneumoniae and Mycoplasma
pneumoniae, and strains thereof. Also envisaged are microbes from the genera
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Streptococcus, Haemophilus, Moraxella, Pseudomonas, Klebsiella, Stenotrophomonas,
Acinetobacter, Staphylococcus, Mycoplasma, Legionella, Chlamydophila, Mycobacterium,
Coxiella, Nocardia, Pneumocystis, Nocardia, and Aspergillus, including those listed
above.
Taught herein is also a method of detecting and/or differentiating between one or
more particular strains of a respiratory pathogen in a sample. Reference herein to "strains"
includes any variants of the species or taxon of the analyte. Examples of "strains" of a
respiratory pathogen include sub-species of the pathogen, variants of the pathogen with
differing levels of virulence, variants of the pathogen that indicate different prognoses
when infecting or colonizing a host, biochemical variants of the pathogen and the like.
The term "sample", as used herein, is used interchangeably with the term
"analyte" to refer to any matter of composition that putatively comprises one or more
respiratory pathogens. Examples include biological samples from a subject, including, but
are not limited to, blood, serum, plasma, saliva, faeces, urine, lymph, amniotic fluid,
cerebrospinal fluid, tissue fluid, semen, exudate, pus, respiratory fluid and mucus and
swabs from topical sores, cancers and lesions and tissue or cell samples such as cell
scrapes, biopsies and the like.
Samples contemplated by the method disclosed herein also include industrial
samples such as air, water and soil and the like. Samples may also include ice, rock,
hydrothermal vents and air; health care environments including hospitals, hospital
equipment, surgical equipment, health care staff garments and the like; "industrial"
environments including manufacturing facilities, pharmaceutical facilities, breweries,
wineries and the like; and "laboratory" environments including fermenters, cultures,
benches, equipment and the like.
As used herein, the term "subject" refers to any organism that may be susceptible
to infection or colonization by a respiratory pathogen. Examples of a subject include, but
are not limited to, animals, plants, fungi and bacteria (which may be infected by
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bacteriophage). A subject includes a host cell or a multiplicity of host cells. As used
herein the term "animal" includes a mammal including a primate such as a lower primate
and a higher primer including a human. However, the term "animal" also specifically
includes livestock species such as cattle, horses, sheep, pigs, goats and donkeys as well as
laboratory animals. Examples of laboratory test animals include mice, rats, rabbits, guinea
pigs and hamsters. Rabbits and rodent animals, such as rats and mice, provide a convenient
test system or animal model as do primates and lower primates. Non-mammalian animals
such as avian species, zebrafish, amphibians (i ncluding cane toads) and Drosophila species
such as Drosophila melanogaster are also contemplated. The subject may also be a non-
animal such as a plant.
In an embodiment, the subject is human.
Respiratory infection in animals, particularly livestock species, can cause
significant economic losses. For example, bovine respiratory disease (B RD), which
includes upper respiratory tract infections, diphtheria and pneumonia, has been attributed
to more than 60-70% of sickness and deaths in feedlot cattle. Both viral and bacterial
agents can cause BRD and can be extremely difficult to control. Whilst the animals recover
from the disease in most cases, they typically present with some degree of long term
injury. For example, studies have shown 30-50% of all cattle showing signs of lung lesions
at slaughter are the result of past respiratory disease. To control respiratory diseases in this
setting, many livestock managers actively diagnose and treat outbreaks by quarantining
and treated the infected animals with antibiotic and/or antiviral medications. However,
these remedial efforts are typically expensive and often fail to cure the disease. Moreover,
the success of treatment invariably depends on the respiratory heath of the animal prior to
onset of the disease and identifying the respiratory pathogen(s ) at play. Thus, the method
disclosed herein has application to the livestock industry for identifying the respiratory
pathogen(s ) in an infected animal or population of animals, thereby allowing better
diagnosis and the implementation of more effective treatment regimes.
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In addition to affecting how animals respond to treatment, pathological damage
arising from a previously respiratory disease can adversely impact an animal's performance
at the feedlot. For instance, feedlot cattle with greater respiratory damage have been shown
to gain less weight than those animals with less respiratory damage. In addition, the meat
derived from cattle with greater damage is often of lower quality than the meat derived
from cattle with lesser damage.
In an embodiment, the subject is a livestock animal. In a related embodiment, the
respiratory pathogen is selected from a feedlot virus including, but not limited to, bovine
herpesvirus 1 (B HV-1 or IBR), parainfluenza 3 virus (P 13), bovine viral diarrhea virus
(B VDV) and bovine respiratory syncytial virus (B RSV) and a feedlot bacterium or
bacterium-like organism including, but not limited to, Mannheimia haemolytica,
Pasteurella multocida, Haemophilus somnus, Mycoplasma spp. and Chlamydia.
[0053] The terms "nucleic acid", "nucleotide" and "polynucleotide" are used
interchangeably herein and include RNA, cDNA, genomic DNA, synthetic forms and
mixed polymers, both sense and antisense strands, and may be chemically or
biochemically modified or may contain non-natural or derivatized nucleotide bases, as will
be readily appreciated by those skilled in the art. Such modifications include, for example,
labels, methylation, substitution of one or more of the naturally occuring nucleotides with
an analog (su ch as a morpholine ring), internucleotide modifications such as uncharged
linkages (e.g. methyl phosphonates, phosphotriesters, phosphoamidates, carbamates, etc.),
charged linkages ( e.g. phosphorothioates, phosphorodithioates, etc.), pendent moieties (e.g.
polypeptides), intercalators (e.g. acridine, psoralen, etc.), chelators, alkylators and
modified linkages ( e.g. -anomeric nucleic acids etc.). Also included are synthetic
molecules that mimic polynucleotides in their ability to bind a designated sequence via
hydrogen bonding and other chemical interactions. Such molecules are known in the art
and include, for example, those in which peptide linkages substitute for phosphate linkages
in the backbone of the molecule.
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Nucleic acids may be isolated from the subject sample using any method known
to those skilled in the art. Isolation of a nucleic acid is to be understood to mean a nucleic
acid that has generally been separated from other components with which it is naturally
associated or linked in its native state. In an embodiment, the isolated nucleic acid is at
least 50% free, or at least 75% free, or at least 90% free from other components with which
it is naturally associated. The degree of isolation expressed may relate to purity from
interfering substances.
DNA may be isolated from the sample using any convenient means known to the
skilled addressee. For example, in the case of a virus putatively expressed in a human cell,
guanidine or a functionally equivalent agent may be used to lyse the cells. In some
embodiments, the DNA is purified from the sample using a limiting amount of a DNA
binding agent such as, but not limited to, silica. By using a limiting amount of the DNA
binding agent, a uniform amount of DNA may be isolated from different samples as the
amount of DNA recovered in each case is equal to the maximum amount of DNA that can
be bound by the limiting amount of DNA binding agent. The DNA bound to the DNA
binding agent may then be recovered or eluted from the DNA binding agent using any
convenient means.
[0056] Depending on the circumstances, which would be evident to one skilled in the art,
RNA is isolated, for example, when the respiratory pathogen of interest is an RNA virus. If
RNA is isolated, the RNA may be amplified, or the RNA may be reverse transcribed into
cDNA using methods known to those skilled in the art, for subsequent amplification and
analysis. In an embodiment, the viral RNA or corresponding DNA is isolated from an
infected host cell.
The method taught herein comprises the use of specific primers to amplify a
nucleic acid sequence in a sample that is highly conserved across members of the taxon of
interest. Schematically, the amplified region has the general structure of:
C -X-C , wherein:
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C is a nucleotide sequence which is conserved across members of the target taxon and is
the binding site of the "forward" (F) p rimer;
X is a nucleotide sequence, part of which comprises a region conserved across members of
the target taxon; and
C is a nucleotide sequence which is conserved across members of the target taxon and is
the binding site of the corresponding "reverse" ( R ) pr imer.
Amplification from primer sites such as those described herein effectively
produces labeled nucleic acid strands (amplicons) that are then be loaded onto solid
supports following hybridization to oligonucleotide capture probes immobilized to beads.
In an embodiment, the labeled amplicons are loaded onto solid supports following
hybridization and extension of hemi-nested probe oligonucleotides immobilized to beads.
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from Influenza A. For example, the primer pair can be designed to amplify a region of the
gene encoding Segment 7 of Influenza A matrix protein. In an embodiment, the primer
pair comprises 5'AmMC6/CGAGGTCGAAACGTAYGTTCTYTCTAT (S EQ ID NO:1;
forward primer; F) and GCCATTCCATGAGAGCCTCRAGATC (S EQ ID NO:17;
reverse primer; R).
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from Influenza B. For example, the primer pair can be designed to amplify a region of the
gene encoding Segment 4 of Influenza B hemagglutinin. In an embodiment, the primer
pair comprises 5'AmMC6/TACGGTGGATTAAACAAAAGCAAGCC (S EQ ID NO:2;
forward primer; F) and CAGGAGGTCTATATTTGGTTCCATTGGC (S EQ ID NO:18;
reverse primer; R).
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In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from the 2009 H1N1 pandemic strain of Influenza A. For example, the primer pair can be
designed to amplify a region of the gene encoding Segment 4 of the 2009 H1N1 pandemic
strain of Influenza A. In an embodiment, the primer pair comprises
5'AmMC6/CCCAAGACAAGTTCATGGCCCAATCA (S EQ ID NO:3; forward primer;
F) a nd GCTTTTTGCTCCAGCATGAGGACAT (S EQ ID NO:19; reverse primer; R) .
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from the H5N1 pandemic strain of Influenza A. For example, the primer pair can be
designed to amplify a region of the gene encoding Segment 4 of the H5N1 pandemic strain
of Influenza A. In an embodiment, the primer pair comprises
'AmMC6/GCTCTGCGATCTAGATGGAGTGAAGCC (S EQ ID NO:4; forward primer;
F) a nd YCTTCTCCACTATGTAAGACCATTCCGG (S EQ ID NO:20; reverse primer; R) .
[0063] In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from the Respiratory Syncytial Virus (t ypes A and B). For example, the primer pair can be
designed to amplify a region of the polymerase gene of the Respiratory Syncytial Virus
(t ypes A and B). In an embodiment, the primer pair comprises
'AmMC6/ACAGTCAGTAGTAGACCATGTGAATTC (S EQ ID NO:5; forward primer;
F) and RTCRATATCTTCATCACCATACTTTTCTGTTA (S EQ ID NO:21; reverse
primer; R).
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from the Human Parainfluenza Virus 1. For example, the primer pair can be designed to
amplify a region of the gene encoding the hemagglutinin-neuraminidase glycoprotein of
Human Parainfluenza Virus 1. In an embodiment, the primer pair comprises
'AmMC6/TGGTGATGCAATATATGCGTATTCATC (S EQ ID NO:6; forward primer;
F) a nd CCGGGTTTAAATCAGGATACATATCTG (S EQ ID NO:22; reverse primer; R).
[0065] In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from the Human Parainfluenza Virus 2. For example, the primer pair can be designed to
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amplify a region of the gene encoding the hemagglutinin-neuraminidase glycoprotein of
Human Parainfluenza Virus 2. In an embodiment, the primer pair comprises
'AmMC6/CYCGTCCTGGAGTCATGCCATGCAA ( S EQ ID NO:7; forward primer; F)
and CRTTAAGCGGCCACACATCTGCGT (S EQ ID NO:23; reverse primer; R).
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from the Human Parainfluenza Virus 3. For example, the primer pair can be designed to
amplify a region of the gene encoding the hemagglutinin-neuraminidase glycoprotein of
Human Parainfluenza Virus 3. In an embodiment, the primer pair comprises
5'AmMC6/CAAGTTGGCAYAGCAAGTTACAATTAGGA (S EQ ID NO:8; forward
primer; F) and GTCCCCATGGACATTCATTGTTTCCTGGT (S EQ ID NO:24; reverse
primer; R).
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from the Human Parainfluenza Virus 4. For example, the primer pair can be designed to
amplify a region of the phosphoprotein gene of Human Parainfluenza Virus 4. In an
embodiment, the primer pair comprises
'AmMC6/GTTGATCAAGACAATACAATTACACTTGA (S EQ ID NO:9; forward
primer; F) and TAAGTGCATCTATACGAACRCCTGCTC (S EQ ID NO:25; reverse
primer; R).
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from the Human Metapneumovirus. For example, the primer pair can be designed to
amplify a region of the gene encoding the M2 region of the matrix protein of Human
Metapneumovirus. In an embodiment, the primer pair comprises
'AmMC6/GACAAATCATMATGTCTCGYAARGCTCC (S EQ ID NO:10; forward
primer; F) and CTATCWGGCCAACTCCAGTAATTGTG (S EQ ID NO:26; reverse
primer; R).
[0069] In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from Adenovirus Types B and/or E. For example, the primer pair can be designed to
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amplify a region of the gene encoding the Hexon region of Adenovirus Types B and E. In
an embodiment, the primer pair comprises TGCCSCARTGGKCDTACATGCACATC
(S EQ ID NO:11; forward primer; F) and 5'AmMC6/GCRCGGGCRAACTGCACCAG
(S EQ ID NO:27; reverse primer; R).
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from Adenovirus Type C. For example, the primer pair can be designed to amplify a
region of the gene encoding the Hexon region of Adenovirus Types C. In an embodiment,
the primer pair comprises 5'Phos/TGCCSCARTGGKCDTACATGCACATC (S EQ ID
NO:12; forward primer; F) and 5'AmMC6/GCRCGGGCRAACTGCACCAG ( S EQ ID
NO:28; reverse primer; R).
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from Human Rhinovirus/Enterovirus. For example, the primer pair can be designed to
amplify the 5'UTR region of Human Rhinovirus/Enterovirus. In an embodiment, the
primer pair comprises 5'AmMC6/GAAACACGGACACCCAAAGTAGT (S EQ ID
NO:13; forward primer; F) and ACTCACTATAGGAGCCTGCGTGGCKGCC (S EQ ID
NO:29; reverse primer; R).
[0072] In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from Bordetella pertussis. For example, the primer pair can be designed to amplify a
region of the Insertion Element (IS) 481 of Bordetella pertussis. In an embodiment, the
primer pair comprises CCGGCCGGATGAACACCCATAAGCA (S EQ ID NO:14;
forward primer; F) and 5'AmMC6/GGGCCGCTTCAGGCACACAAACTTG (S EQ ID
NO:30; reverse primer; R) .
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from Chlamidophila pneumoniae. For example, the primer pair can be designed to amplify
a region of the gene encoding Major Outer Membrane Protein of Chlamidophila
pneumoniae. In an embodiment, the primer pair comprises
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CATGAATGGCAAGTAGGAGCCTCTC (S EQ ID NO:15; forward primer; F) and
'AmMC6/AGTTTTGGCTGAGCAATGCGGATGT (S EQ ID NO:31; reverse primer; R).
In an embodiment, the primer pair is designed to amplify a region of nucleic acid
from Mycoplasma pneumoniae. For example, the primer pair can be designed to amplify a
region of the gene encoding P1 Cytadhesin of Mycoplasma pneumoniae. In an
embodiment, the primer pair comprises GAACCGAAGCGGCTTTGACCGCATC (S EQ
ID NO:16; forward primer; F) and 5'AmMC6/GCGTGGGCGTTTGCGGGTTTAACTT
(S EQ ID NO:32; reverse primer; R).
The present disclosure is instructional for amplification of control sequences. In an
embodiment, the control sequence may include a region of the genome of the subject from
which a biological sample is derived. However, the method disclosed herein is not in any
way limited to these particular control sequences and other control sequences that would
be evident to one of skill in the art are also contemplated, including artificially created
nucleic acid constructs comprising sequences derived from the genome of a respiratory
pathogen. Furthermore, the methods disclosed herein may also be performed without the
amplification of a control sequence. Where amplification of a control sequence is
performed, the amplicon that is generated is also referred to herein as a "control amplicon".
In an embodiment, the primer pair is designed to amplify a region of the MYL3
gene. For example, the primer pair can comprise
GCACCCAGACAATACACACAGGTGT ( S EQ ID NO:33; forward primer; F) and
'AmMC6/GGCGGAAGTCAGCATGTGTCTG (S EQ ID NO:34; reverse primer; R).
In an embodiment, the control sequence includes a gene sequence to determine that
intact RNA has been successfully isolated from a sample. For example, the primer pair can
be designed to amplify a region of the Matrix MS-2 gene. In an embodiment, the primer
pair comprises GCACGCTCCTGCTACAGCCTCTTCC (S EQ ID NO:35; forward primer;
F) and 5'AmMC6/CTTTTGCAGGACTTCGGTCGACGCC (S EQ ID NO:36; reverse
primer; R).
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Other primer pairs and probes are those listed in Table 8 (S EQ ID NOs:74 to 126).
Isolated DNA may be amplified using any DNA amplification protocol known to
those skilled in the art. A range of exemplary methods for the amplification of DNA which
in no way limit the method disclosed herein are presented in "DNA Amplification: Current
Technologies and Applications" (D emidov and Broude Eds. (2004 ) Horizon Bioscience).
Isolated RNA may be amplified using any RNA methods known in the art and number of
RNA amplification technologies have been developed. Two major categories of these are:
( i ) those that utilize thermal cycling such as RT-PCR and (i i) isothermal assays such as
nucleic acid sequence-based amplification (N ASBA) (C ompton (1991 ) Nature 350:91-92;
Kievits et al. (1991 ) J Virol. Methods 35:273-286) and transcription-mediated
amplification (TMA ) [Hill ( 1996 ) J. Clin. Ligand Assay 7P:43-51]. Isothermal assays may
be sub-divided, based on whether: (i ) they copy and amplify the target sequence, such as
TMA, NASBA and self-sustained sequence replication ( 3S R) [Guatelli et al. (1990 ) Proc.
Natl Acad. ScI USA 57:1874-1878; Chadwick et al. (1998 ) J. Virol. Methods 70:59-70; for
review see Chan and Fox (1999 ) Rev. Med. Microbiol. 70:185-196]; or (i i) they generate a
target-dependent signal which can be further amplified, e.g. invader assays (Lyamichev et
al. (1999 ) Nat. Biotechnol. 77:292-296; Ryan et al. ( 1999 ) MoI. Diagn. 4:135- 144).
However, it should be understood that the method disclosed herein also contemplates any
method of RNA amplification that would be evident to one of skill in the art. Furthermore,
it should be understood that the method disclosed herein also contemplates the use of
reverse transcriptase or a functional equivalent thereof to convert RNA to DNA which may
then be subsequently amplified.
In the method taught herein, at least one member of the primer pair comprises a
detectable label, referred to herein as a "first detectable label" or "first optically detectable
label", including, but not limited to, a molecule, atom or ion which emits fluorescence,
phosphorescence and/or incandescence.
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In an embodiment, the first optically detectable label is a "fluorescent marker" or
"fluorophore". Many different fluorescent markers will be familiar to those of skill in the
art, and the choice of fluorescent marker in no way limits the method disclosed herein.
Exemplary fluorescent markers comprise any fluorescent marker which is excitable using a
light source selected from the group below:
(i ) Argon ion lasers: comprise a blue, 488 run line, which is suitable for the excitation
of many dyes and fluorochromes that fluoresce in the green to red region. Tunable argon
lasers are also available that emit at a range of wavelengths (458 nm, 488 nm, 496 nm, 515
nm and others);
(i i) Diode lasers: have an emission wavelength of 635 nm. Other diode lasers which are
now available operate at 532 nm. Interestingly, this wavelength excites propidium iodide
(P I) optimally. PI staining is widely used for DNA analysis, live/dead counting and ploidy
determination. Blue diode lasers emitting light around 476 nm are also available;
(i ii) HeNe gas lasers: operate with the red 633 nm line;
(i v) HeCd lasers: operate at 325 nm;
(v ) 100 W mercury arc lamp: the most efficient light source for excitation of UV dyes
like Hoechst and DAPI.
Exemplary fluorophores (a lso referred to herein as a fluorochrome) include, but are
not limited to, hydroxycoumarin, aminocoumarin, methoxyciumarin, cascade blue, Lucifer
yellow, NBD, Phyccerythrin ( P E), PerCP, allophycocyanin, hoechst 33342, DAPl,
SYTOX Blue, hoechst 33258, chromomycin A3, mithramycin, YOYO-I, SYTOX green,
SYTOX orange, 7-AAD, acridine orange, TOTO-I, To-PRO-I, thiazole orange, TOTO-3,
TO-PRO-3, LDS 751, Alexa Fluor dyes including Alexa Fluro-350, -430, -488, -532, -546,
-555, -556, -594, -633, -647, -660, -680, -700 and -750; BoDipy dyes, including BoDipy
630/650 and BoDipy 650/665; CY dyes, particulary Cy2, Cy3, Cy3.5, Cy5, Cy 5.5 and
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Cy7; 6-FAM (Fluorescein); PE-Cy5, PE-Cy7, Fluorescein dT; Hexachlorofluorescein
(H ex); 6-carboxy-4', 5'-dichloro-2', T- dimethoxyfluorescein (J OE); Oregon green dyes,
including 488-X and 514; Rhodamine dyes, including X-Rhodamine, Lissamine
Rhodamine B, Rhodamine Green, Rhodamine Red and ROX; TRITC,
Tetramethylrhodamine (TMR ) ; Carboxytetramethylrhodamine (TA MRA);
Tetrachlorofluorescein (TET); Red 6B, FluorX, BODIPY-FL and Texas Red. In some
embodiments, the first detectable label is AlexaFluor-647.
In an embodiment, at least one member of a first primer pair is labeled with a
detectable label and at least one member of a second primer pair is labeled with a different
detectable label so as to allow differentiation between amplicons within a set of multiple
amplicons.
At least one member of a primer pair may be labeled using any convenient means
known to those skilled in the art. Exemplary methods include both pre- and post- synthesis
methods. Pre-synthesis labeling methods include labeling of a PCR primer that is
subsequently used for amplification of, and thereby incorporated into, an amplicon via
PCR. In this method, the label is typically attached to the 5' end of a primer suitable for the
amplification of the amplicon, although labeling at other positions within the primer, such
as 3' labeling or non-terminal labeling, is also contemplated.
A chemical linker may also be used between the label and the primer that is
labeled. Exemplary linker sequences will be readily ascertained by those of skill in the art,
and are likely to include linkers such as C6, C7 and C12 amino modifiers and linkers
comprising thiol groups. As will be readily ascertained, a primer may comprise the linker
and label, or the linker alone, to which the label may be attached at a later stage.
The method taught herein is useful in screening a sample for a multiplicity of
respiratory pathogens due to its ability to have two or more subsets of beads, the beads of
each subset being physiochemically distinguishable from those of another subset of the
basis of bead size and, optionally, the intensity of a detectable label immobilized on the
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beads. Thus, the beads within any one subset may have a common optically detectable
label and/or a common size. The beads within any one subset may also have a common
oligonucleotide probe. Hence, multiple respiratory pathogens may be detected using a
multiplicity of subsets of beads, referred to herein as a beadset.
In an embodiment, the beads comprise a "microparticle". As will be evident to
those of skill in the art, almost any material, homogenous or otherwise, may be used for the
microparticle. The microparticles contemplated herein may also comprise more than one
substance, and as such may comprise shells, alloys or mixtures of organic and/or inorganic
substances. Useful materials which may be used include materials selected from the group
consisting of silica (for example: quartz or glass), latex, titania, tin dioxide, yttria, alumina,
and other binary metal oxides (suc h as ZnO) , perovskites and other piezoelectric metal
oxides (suc h as BaTiO ), ZnS, sucrose, agarose and other polymeric beads. In some
embodiments, the microparticle comprises silica.
The term "physiochemically distinguishable", as used herein, refers to a measurable
difference in any of bead size, the presence or absence of a particular detectable label
and/or the intensity of a detectable label.
[0089] Beads contemplated for use in the method disclosed herein may be produced in any
convenient regular or irregular 3-dimensional shape. However, it is generally practical to
synthesize small spheres or spheroidal particles. Such spheres or spheroidal particles are
also referred to herein as "beads". Accordingly, in a related embodiment, the
"microparticles" are substantially spherical or spheroidal or comprise a "microsphere".
Although the beads may be referred to as "microspheres", the actual size of the
beads depends on a variety of factors and the beads may or may not actually comprise
measurements in the micrometer range. For example, the bead comprises a diameter ( or
equivalent measurement in a non-spheroidal particle) of about 300 nm to about 30m,
including 300nm, 350nm, 400nm, 450nm, 500nm, 550nm, 600nm, 650nm, 700nm, 750nm,
800nm, 850nm, 900nm 950nm, l.0m, 1.1m, 1.2m, 1.3m, 1.4m 1.5m, l.6m,
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1.7m, 1.8m, 1.9m, 2.0m, 2.1m, 2.2m, 2.3m, 2.4m, 2.5m, 2.6m, 2.7m, 2.8m,
2.9m, 3.0m, 3.1m, 3.2m, 3.3m, 3.4m, 3.5m, 3.6m, 3. 7m, 3.8m, 3.9m, 4.0m,
4.1m, 4.2m, 4.3m, 4.4m 4.5m, 4.6m 4.7m, 4.8m, 4.9m, 5.0m, 5.1m, 5.2m,
.3m, 5.4m, 5.5m, 5.6m, 5.7m, 5.8m, 5.9m, 6.0m, 6.lm, 6.2m , 6.3m 6.4m,
6.5m, 6.6m, 6.7m, 6.8m, 6.9m, 7.0m, 7.1m, 7.2m, 7.3m, 7.4m 7.5m,
7.6m, 7.7m, 7.8m, 7.9m, 8.0m, 8.1m, 8.2m, 8.3m, 8.4m, 8.5m, 8.6m, 8.7m,
8.8m, 8.9m, 9.0m, 9.1m, 9.2m, 9.3m, 9.4m, 9.5m, 9.6m 9.7m , 9.8m, 9.9m,
10m, l1m, 12m, 13m, 14m, 15m, 16m, 17m, 18m, 19m, 20m, 21m, 2 2m,
23m, 24m, 25m, 26m, 27m, 28m, 29m and 30m. In some embodiments, the
bead comprises a diameter (or equivalent measurement in a non-spheroidal particle) of
between 3m and 6m.
In an embodiment, the beads are AmpaSand beads produced by Genera
Biosystems, Victoria, Australia. However, the method described herein should not be
considered in any way limited to the use of these beads specifically.
The beads may be distinguished on the basis of the presence or absence of a
detectable label, referred to herein as a "second detectable labels" or "second optically
detectable label" and includes, but is not limited to, any molecule, atom or ion which emits
fluorescence, phosphorescence and/or incandescence. Convenient optically detectable
labels include those which emit in the ultraviolet (w avelength range of about 350nm to
about 3nm), visible (w avelength range of about 350nm to about 800nm, near infrared
(N IR) (w avelength range of about 800nm to about 1500nm) and/or infrared (IR)
(w avelength range of about 1500nm to about l0m) ranges. However, due to the ease of
detection, in some embodiments, the optically detectable label is detectable in the visible
wavelength range.
The optically detectable label may comprise one or more labels selected from the
group consisting of a fluorophore, a semiconductor particle, phosphor particle, a doped
particle and a nanocrystal or quantum dot. In a related embodiment, the second optically
detectable label is a fluorophore.
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There are many fluorescent dyes that are available in the art which may be used as
fluorophores in accordance with the method disclosed herein. An important property of a
fluorescent dye or other fluorophore that determines its potential for use is the excitation
wavelength of the fluorophore, which typically matches the available wavelength(s ) of the
light source. However, many different fluorescent dyes and other fluorophores will be
familiar to those of skill in the art, and the choice of fluorescent marker in no way limits
the method described herein. Particularly convenient fluorescent dyes which may be used
for the labeling of a substrate include those discussed supra with regard to labeling of the
PCR amplicon. However, when choosing a fluorescent label, the emission spectra of the
fluorescent label immobilized to the bead (se cond detectable label) should be distinct from
the emission spectrum of the detectable label used for the at least one member of the
primer pair (first detectable label).
[0095] Methods of fluorescently labeling beads and microspheres would be familiar to
those skilled in the art, including internal dyeing and external dyeing (s urface-labeling).
The two techniques produce beads with unique properties, each beneficial for different
applications. Internal dyeing produces extremely stable particles with typically narrow
fluorescence emissions. These beads often display a greater resistance to photobleaching.
As the fluorophore is inside the beads, surface groups are available for use in conjugating
ligands (p roteins, antibodies, nucleic acids, etc.) to the surface of the bead. For this reason,
internally labeled beads are typically used in analyte-detection and immunoassay
applications. Surface-labeling involves conjugation of the fluorophore to the bead surface.
Because the fluorophores are on the surface of the bead, they are able to interact with their
environment just as the fluorophores on a stained cell. The result is a bead standard that
exhibits the same excitation and emission properties as stained cell samples, under a
variety of different conditions, such as the presence of contaminants or changes in pH. The
"environmentally responsive" nature of surface-labeled beads makes them ideally suited
for mimicking biological samples. Externally labeled beads are frequently used as controls
and standards in a number of applications utilizing fluorescence detection. However, the
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method disclosed herein contemplates the association of a bead with a fluorescent label via
any means.
The second optically detectable label may also be incorporated into the
immobilized oligonucleotide probe, rather than being a label directly associated with the
bead per se. For example, the beads comprise an immobilized "tag" or oligonucleotide
probe. The tag may carry an internal amine (N H ) which is then modified by conjugation
with a succinimidyl ester of a dye. In some embodiments, the second detectable label is
BoDipy-TMR.
By mixing labeled and unlabeled oligonucleotide probes or labels and then
conjugating this mix to the beads, one can produce classes of beads with different levels of
the fluorescent marker and hence second detectable label intensity.
[0098] The second detectable label may be applied to a bead at a range of concentrations
or intensities, thereby providing another basis on which particular beads may be
"physiochemically distinguishable". For example, if the maximum detectable intensity of
the signal of a particular optically detectable is deemed to be 100%, the label may be
applied to a range of beads to give intensities of 0%, 2%, 4%, 6%, 8%, 10%, 15%, 20%,
25%, 30%, 35%, 40%, 45%, 50%, 60%, 70%, 80%, 90%, 100%.
In some embodiments, the beadset comprises 6 subsets of beads of 3.0m, 3.5m,
3.8m, 5.0m, 5.2m and 5.7m in diameter (or equivalent measurement in a non -
spheroidal particle) and wherein each of the 6 subsets of beads comprise a further 3 subsets
( se condary subsets) comprising 1) beads conjugated to unlabeled oligonucleotide probe
(TO :FLO = 0; No TMR), 2) beads conjugated to a mixed 1:50-200 ratio of
labeled:unlabeled oligonucleotide probe (T O:FLO = 50-200; Medium TMR) , respectively,
and 3) beads conjugated to a mixed 1:1.5-2 ratio of labeled:unlabeled oligonucleotide
probe (TO :FLO = 1.5-2; High TMR), r espectively.
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Reference to an oligonucleotide probe that is "immobilized" to the bead is reference
to an oligonucleotide attached to or otherwise associated with the bead. An
oligonucleotide probe can be attached to or otherwise associated with the bead by any
convenient means known to those skilled in the art. For example, the oligonucleotide
probe may be encapsulated in beads during their production or may be attached to their
surface post-production. The method used to associate the oligonucleotide probe with the
bead will depend on the material used, as would be readily ascertained by the skilled
addressee. In addition, further treatments, including silanization (c oating of the substrate
with silanes), may be performed on the beads prior to attachment of the oligonucleotide
probe in order to increase the binding of the probe to the bead.
Beads may be coated with any compound that will covalently attach, or otherwise
adsorb, to the surface of the bead, and in addition the oligonucleotide probe could also
have a chemical moiety for the attachment of an oligonucleotide probe, such as a thiol,
amine or carboxyl group. Examples of compounds with these characteristics include
amino-terminated silanes such as amino-propyltrimethoxysilane or amino-
propyltriethoxysilane. In addition to silanes, compounds such as poly-L-lysine that non-
covalently attach to the glass surface and electrostatically adsorb the phosphate groups of
the polynucleotide are also within the scope of the method disclosed herein. Therefore,
other compounds, including other silanes suitable for the attachment of an oligonucleotide
probe to a surface of the bead would be readily identified by the skilled person and the
method disclosed herein is not limited by the choice of compound.
For example, the oligonucleotide probe can be attached to the bead by physical
adsorption or chemical linking. In addition, beads may be further coated with an agent that
promotes or increases the adsorption or binding of the oligonucleotide probe to the surface
of the bead, such as amino-silanes. However, other agents that perform this function will
be readily identified by persons of skill in the art.
[0103] For example, the oligonucleotide probe can be attached to the bead via the
Universal Anchoring System (U AS) by Genera Biosystems, Victoria, Australia. Briefly,
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this system involves the use of a "bridge" nucleic acid molecule to ligate a nucleic acid
"tag" sequence on the substrate with a target sequence. The "bridge" sequence is partially
complementary to the tag sequence and partially complementary to the target sequence,
such that the bridge sequence may bind to both the tag and target sequences and hold them
in alignment such that the tag and target sequences may be ligated using a ligase. The UAS
is also commercially available. However, the method disclosed herein should not be
considered in any way limited to this particular method of linking a nucleic acid molecule
to a substrate.
[0104] Determination of whether binding has occurred between an amplicon and an
oligonucleotide probe may be done using any methodology known to those skilled in the
art that allows localization of a bound labeled amplicon to an oligonucleotide probe
immobilized to a physiochemically distinguishable bead. In an embodiment, flow
cytometry is used. The method disclosed herein is, however, in no way limited to the
particular flow cytometry method or apparatus.
Using flow cytometry, the size of a given bead may be determined by the light
scatter of the object. For example, flow cytometry can be used to distinguish between
beads of about 3.0m, 3.5m, 3.8m, 5.0m, 5.2m and 5.7m in diameter (o r equivalent
measurement in a non-spheroidal particle).
In addition to size detection, flow cytometers typically have one or more lasers and
detectors for the detection of fluorescence. There are many fluorophores that are useful for
flow cytometry, as herein described. A key property of a fluorophore that determines its
potential for use in a flow cytometric assay is the excitation wavelength; that is, it must
match the available wavelengths of the light source. Flow cytometers can also be used to
distinguish between subsets of beads based on the intensity of fluorescence; namely, the
intensity of the second detectable label. For instance, the present inventors have
determined that flow cytometry is able to distinguish between beads labeled with levels of
a second optically detectable label equivalent to No TMR, Medium TMR and High TMR.
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In another aspect, there is provided a beadset for screening a sample for a
multiplicity of respiratory pathogens to detect a particular pathogen, wherein the beadset
comprises a plurality of subsets of beads wherein:
(a ) the beads of each subset are homogenous with respect to size;
(b ) the beads within each subset are coupled to a nucleic acid oligonucleotide
probe that is capable of binding to an analyte specific region of the genome of a respiratory
pathogen; and
(c ) optionally, the beadset comprises a subset of beads labeled with a detectable
label with each subset of beads having a different detectable label intensity to create a
heterogeneous mixture of beads based on the intensity of the detectable label;
wherein the subset bead identity and therefore the type and/or strain of respiratory
pathogen is identifiable on the basis of bead size and/or detectable label intensity.
The beadset may comprise 2, 3, 4, 5, 6, 7, 8, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19,
or more subsets of beads, each subset comprising an oligonucleotide probe that is
complementary to a region of the amplicon generated following amplification with the
primer pair(s ). In an embodiment, the oligonucleotide probe comprise a nucleic acid
selected from the group consisting of SEQ ID NOs:37 to 54. Reference to these sequence
specific oligonucleotide probes includes nucleic acid molecules having at least 90%
identity to these sequences or capable of hybridizing thereto or their complementary forms
under low stringency conditions. Reference to at least 90% includes 90, 91, 92, 93, 94, 95,
96, 97, 98, 99 and 100%.
The number of subsets of beads in a beadset will typically correspond to the
number of analytes (i .e., types and/or strains of respiratory pathogens) to be screened. The
beadset may also include one or more additional subsets for the detection of a control
sequence, as herein described.
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The term "oligonucleotide probe" is used herein to denote a polynucleotide
immobilized to a bead (i.e., attached to or otherwise associated with the bead). Each
oligonucleotide probe comprises a polynucleotide comprising a sequence that is
complementary to a region of an amplicon generated in accordance with the methods
described herein. An oligonucleotide probe may also comprise a sequence that is
complementary to a control sequence, as herein described.
Accordingly, a beadset of oligonucleotide probes may comprise:
[B -CX , B -CX , B -cX , .B -cX , B -cY, B -cZ]
1 1 2 2 3 3 n n y z
wherein:
B , B , B , B are each physiochemically distinguishable beads;
1 n y z
cX is a polynucleotide immobilized to a bead wherein said polynucleotide comprises a
nucleotide sequence which is complementary to a particular nucleic acid sequence which is
specific to a particular type and/or strain of a respiratory pathogen ( i.e., a type- and/or
strain- specific sequence);
n is the number of respiratory pathogens or particular strains of a subject pathogen to be
detected using the beadset;
cY is an optional member of the beadset and is a polynucleotide immobilized to a bead
wherein said polynucleotide comprises a nucleotide sequence which is complementary to a
sequence which is conserved among the pathogens or strains of a pathogen;
cZ is an optional member of the beadset and is a polynucleotide immobilized to a bead
wherein said polynucleotide comprises a nucleotide sequence which is complementary to a
control sequence which is amplified from a multicellular subject. In some embodiments,
the control sequence is a human genomic DNA sequence. In some embodiments, the
control sequence is derived from the human MYL3 gene.
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The oligonucleotide probe may be attached to or otherwise associated with the
beads during their production or may be attached to their surface post-production. The
choice method used to associate the polynucleotide with the bead will depend on the
material used, as would be readily ascertained by the skilled artisan. In addition, further
treatments, including silanization (c oating of the substrate with silanes), may be performed
on the beads prior to attachment of the polynucleotide in order to increase the binding of
said polynucleotide to the bead.
[0113] As used herein, the phrase "bound to, or otherwise associated with" refers to any
process by which a molecule may be associated with a bead. Exemplary modes by which
such associations may be mediated include, but are not limited to: covalent binding,
hydrogen bonding, van der Waals forces, ionic bonding, metallic bonding, polar bonding
and dative (c ovalent) bon ding and the like.
A molecule including an oligonucleotide probe may also be attached to a
microspheroidal particle via an agent that promotes or increases the adsorption or binding
of the oligonucleotide probe to the surface of the bead, such an agent is referred to herein
as a "linker". For example, polynucleotides may be associated with a microspheroidal
particle via a linker which comprises a thiol, amine or carboxyl group. Examples of
suitable linkers include amino-terminated silanes such as amino-propyltrimethoxysilane or
amino- propyltriethoxysilane. In addition to silanes, compounds such as poly-L-lysine that
non- covalently attach to surfaces such as glass and electrostatically adsorb the phosphate
groups of a polynucleotide are also envisaged. Therefore, other molecules, including other
silanes, which are suitable to promote the binding or association of an oligonucleotide
probe to the surface of a bead would be readily identified by the skilled artisan, and the
method disclosed herein is not limited by the choice of linker.
By "complementary", it is to be understood that the oligonucleotide probe should
hybridize to an amplicon generated according to the methods described herein under low
stringency conditions. Preferably the immobilized oligonucleotide probe should hybridize
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to the amplicon under medium stringency conditions, and most preferably the immobilized
oligonucleotide probe should hybridize to the amplicon under high stringency conditions.
In an embodiment, where the primer pair is SEQ ID NOs:1 and 17, the
complementary oligonucleotide probe is 5'ThioMC6-D/AAT
/iAmMC6T/GAATTCGGATCCAGTCTCTGCGCGATCTCGGCTTTGAG (S EQ ID
NO:37).
In an embodiment, where the primer pair is SEQ ID NOs:2 and 18, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCGGTGTTTTCACCCATATTGGGCAATT (S EQ
ID NO:38).
In an embodiment, where the primer pair is SEQ ID NOs:3 and 19, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCCATGCTGCCGTTACACCTTTGTTCG (S EQ
ID NO:39).
In an embodiment, where the primer pair is SEQ ID NOs:4 and 20, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCCCGAGGAGCCAT CCAGCTACACTAC (S EQ
ID NO:40).
In an embodiment, where the primer pair is SEQ ID NOs:5 and 21, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCGTTCTATAAGCTGGTATTGATGCAGG (S EQ
ID NO:41).
In an embodiment, where the primer pair is SEQ ID NOs:6 and 22, the
complementary oligonucleotide probe is 5'ThioMC6-
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D/AAT/iAmMC6T/GAATTCGGATCCCCTATATCTGCACATCCTTGAGTGATT
(S EQ ID NO:42).
In an embodiment, where the primer pair is SEQ ID NOs:7 and 23, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCACCCCTGTGATGCAATTAGCAGGGCA (S EQ
ID NO:43).
In an embodiment, where the primer pair is SEQ ID NOs:8 and 24, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCAGCACATTATGCCATGTCCATTTTATCC
(S EQ ID NO:44).
In an embodiment, where the primer pair is SEQ ID NOs:9 and 25, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCGGTTCCAGAYAAWATGGGTCTTGCTA
(S EQ ID NO:45).
In an embodiment, where the primer pair is SEQ ID NOs:10 and 26, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCTTGCCCCGYACTTCATATTTGCA ( S EQ ID
NO:46).
In an embodiment, where the primer pair is SEQ ID NOs:11 and 27, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCGCTTCGGAGTACCTGAGTCCGGGT (S EQ ID
NO:47).
In an embodiment, where the primer pair is SEQ ID NOs:12 and 28, the
complementary oligonucleotide probe is 5'ThioMC6-
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D/AAT/iAmMC6T/GAATTCGGATCCTCGGGCCAGGACGCCTCGGAGTAC (S EQ ID
NO:48).
In an embodiment, where the primer pair is SEQ ID NOs:13 and 29, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCTCCTCCGGCCCCTGAATGYGGCTAA (S EQ
ID NO:49).
In an embodiment, where the primer pair is SEQ ID NOs:14 and 30, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCTGCCCGATTGACCTTCCTACGTCGA (S EQ
ID NO:50).
In an embodiment, where the primer pair is SEQ ID NOs:15 and 31, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCTGGTCTCGAGCAACTTTTGATGCTG (S EQ
ID NO:51).
In an embodiment, where the primer pair is SEQ ID NOs:16 and 32, the
complementary oligonucleotide probe is 5'ThioMC6-
D/AAT/iAmMC6T/GAATTCGGATCCGGGCGCGCCTTATACGACCTCGATT (S EQ
ID NO:52).
In an embodiment, where the primer pair is SEQ ID NOs:33 and 34, the
complementary oligonucleotide probe is
'Acryd/AAT/iAmMC6T/AAAGGGAGGACAGCTATGGACCAAACACAGACACAGA
GAGACCCACAGACA ( S EQ ID NO:53).
In an embodiment, where the primer pair is SEQ ID NOs:35 and 36, the
complementary oligonucleotide probe is 5'ThioMC6-
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D/AAT/iAmMC6T/GAATTCGGATCCGAAGTGCCGCAGAACGTTGCGAACC (S EQ
ID NO:54).
In an embodiment, the primer pairs and corresponding probes are selected from
those listed in Table 8 ( S EQ ID NOs:74 to 126). In an embodiment, 2 or more primer
pairs and corresponding probes are selected. By "2 or more" includes from about 2 to
about 18, such as 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17 or 18.
Conditions of low, medium and high stringency would be known to those skilled in
the art. For example, low stringency includes from at least about 0 to at least about 15%
v/v formamide (i ncluding 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9%, 10% 11%, 12%, 13%
and 14% v/v formamide) and from at least about 1 M to at least about 2 M salt for
hybridization, and at least about 1 M to at least about 2 M salt for washing conditions.
Medium stringency may include, for example, from at least about 16% v/v to at least about
30% v/v formamide, including 16%, 17%, 18%, 19%, 20%, 21%, 22%, 23%, 24%, 24%,
26%, 27%, 28%, 29% and 30% v/v formamide, and from at least about 0.5 M to at least
about 0.9 M salt for hybridization, and at least about 0.5 M to at least about 0.9 M salt for
washing conditions. High stringency may include, for example, from at least about 31 %
v/v to at least about 50% v/v formamide and from at least about 0.01 M to at least about
0.15 M salt for hybridization, and at least about 0.01 M to at least about 0.15 M salt for
washing conditions. The temperature of the hybridization and wash steps may be altered
and higher temperatures used to replace formamide and/or to give alternative stringency
conditions.
[0136] In an embodiment, the oligonucleotide probe of a subset of beads is labeled with a
second detectable label, which allows the method disclosed herein to differentiate between
multiple respiratory pathogens or between multiple members of a class of respiratory
pathogens. It is generally convenient to use a second detectable label that can be readily
differentiated from the first detectable label, for example, on the basis of their respective
wavelengths of fluorescence.
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An oligonucleotide probe may be labeled with a detectable label, as herein
described, using any convenient means, including those exemplified hereinbefore with
respect to labeling of the strain-specific amplicon. For example, a chemical linker can be
used between the label and the oligonucleotide probe which is labeled. Exemplary linker
sequences will be readily ascertained by those of skill in the art, and are likely to include
linkers such as C6, C7 and C12 amino modifiers and linkers comprising thiol groups. As
will be readily ascertained, a primer may comprise the linker and label, or the linker alone,
to which the label may be attached at a later stage. In some embodiments, the linker is a
C6 amino acid modification.
In an embodiment, the label used is a fluorophores (a lso referred to herein as a
fluorochrome) selected from: hydroxycoumarin, aminocoumarin, methoxyciumarin,
cascade blue, Lucifer yellow, NBD, Phyccerythrin (P E), PerCP, allophycocyanin, hoechst
33342, DAPl, SYTOX Blue, hoechst 33258, chromomycin A3, mithramycin, YOYO-I,
SYTOX green, SYTOX orange, 7-AAD, acridine orange, TOTO-I, To-PRO-I, thiazole
orange, TOTO-3, TO-PRO-3, LDS 751, Alexa Fluor dyes including Alexa Fluro-350, -
430, -488, -532, -546, -555, -556, -594, -633, -647, -660, -680, -700 and -750; BoDipy
dyes, including BoDipy 630/650, BoDipy 650/665 and BoDipy-TMR; CY dyes,
particulary Cy2, Cy3, Cy3.5, Cy5, Cy 5.5 and Cy7; 6-FAM (Fluorescein); PE-Cy5, PE-
Cy7, Fluorescein dT; Hexachlorofluorescein (Hex); 6-carboxy-4', 5'-dichloro-2', T-
dimethoxyfluorescein (J OE); Oregon green dyes, including 488-X and 514; Rhodamine
dyes, including X-Rhodamine, Lissamine Rhodamine B, Rhodamine Green, Rhodamine
Red and ROX; TRITC, Tetramethylrhodamine (TMR ); Carboxytetramethylrhodamine
(TA MRA); Tetrachlorofluorescein (TET ); Red 6B, FluorX, BODIPY-FL and Texas Red.
In some embodiments, the second detectable label is BoDipy-TMR.
In an embodiment, the oligonucleotide probe is labeled with more than one
detectable label that further allow differentiation between beads within a beadset.
[0129] In an embodiment, the amount of labeled oligonucleotide probe attached to or
otherwise associated with a bead within a beadset can be controlled to produce a bead with
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a predetermined or requisite second detectable label intensity, as hereinbefore described.
Such methods are known to those skilled in the art. For example, a mixture of labeled and
unlabeled oligonucleotide probes can be brought into contact with the beads, wherein ratio
of labeled and unlabeled oligonucleotide probes dictates the amount of labeled
oligonucleotide probe attached to or otherwise associated with a bead within a beadset, and
hence the intensity of the second detectable label on each bead. The mixture of labeled and
unlabeled oligonucleotide probes can be prepared, for example, using the two sequential
formulae indicated below:
1) H = G*C*(( E/D)-1)/ F
Where H = Vol ( L) of unlabeled stock oligonucleotide (oligonucleotide probe) r equired
G = Vol ( L) of labeled oligonucleotide required
C = Concentration of labeled oligonucleotide
E = desired TO:FLO ratio
D = TO:FLO ratio of stock labeled oligonucleotide
F = Concentration of unlabeled stock oligonucleotide
2) W ater ( L) = (0.01* (( G*C) + (H *F) ) )-( G+H)
Where G = Vol ( L) of labeled oligonucleotide required
C = Concentration of labeled oligonucleotide
H = Vol ( L) of unlabeled stock oligonucleotide required [derived from 1)]
F = Concentration of unlabeled stock oligonucleotide
Thus, the beads B B , B , B of the beadsets may be physiochemically
1 n y z
distinguishable beads. The term "physiochemically distinguishable" refers to any physical
or chemical characteristic which allows one bead, e.g. B , to be differentiated from another
bead, e.g. B . Accordingly, the physiochemically distinguishable beads allow
differentiation of multiple respiratory pathogens or strains thereof. In accordance with the
method disclosed herein, the beads of the beadset are distinguishable on the basis of size
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and/or second detectable label intensity. In some embodiments, the term
"physiochemically distinguishable" refers to a measurable difference in any of bead size,
the presence or absence of a particular optically detectable label and/or the intensity of the
optically detectable label.
In an embodiment, the beads within the beadsets are distinguishable on the basis of
size, the level of intensity of the second detectable label, the type of fluorophore and the
sequence of the oligonucleotide probe immobilized thereon.
[0132] The present disclosure further teaches a diagnostic kit for use in accordance with
the method disclosed herein, including diagnosing respiratory infection in a human subject,
determining the presence of a respiratory pathogen in a sample and/or assessing the risk of
a human subject developing a respiratory infection.
[0133] In an embodiment, the kit comprises a beadset comprising a subset of beads,
wherein the beads within each comprise an oligonucleotide probe immobilized to the beads
of a physiochemically distinguishable subset of beads, wherein the oligonucleotide probe
is complementary to a nucleotide sequence of a respiratory pathogen. Optionally, the kit
may comprise a primer pair capable of binding to conserved sequences among different
strains of respiratory pathogens to generate an amplicon that comprises a distinct
nucleotide sequence for a particular strain of respiratory pathogen, wherein the amplicon
generated is putatively complementary to an oligonucleotide probe immobilized to the
beads of the kit.
[0134] In an embodiment, the kit comprises at least two primer pairs comprising a forward
primer selected from SEQ ID NOs:1 to 16 and SEQ ID NOs:33 and 35 and a
corresponding reverse primer selected from SEQ ID NOs:17 to 32 and SEQ ID NOs:34
and 36 and at least two complementary oligonucleotide probes selected from SEQ ID
NOs:37 to 54.
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The specification further provides analytes detected by the method disclosed
herein.
Also enabled herein is a kit comprising labeled or pre-labeled beads that may be
used in the methods disclosed herein. In an embodiment, taught herein is a kit comprising
two or more oligonucleotide primer pairs selected from SEQ ID NOs:1 and 17, 2 and 18, 3
and 19, 4 and 20, 5 and 21, 6 and 22, 7 and 23, 8 and 24, 9 and 25, 10 and 26, 11 and 27,
12 and 28, 13 and 29, 14 and 30, 15 and 31 and 16 and 32 and a corresponding probe
selected from SEQ ID NOs:37 to 52, respectively. In an embodiment, taught herein is a kit
comprising two or more oligonucleotide primer pairs and a corresponding primer probe as
listed in Table 8 (S EQ ID NOs:74 to 126). By "two or more" or "at least 2" includes from
2 to about 18 including 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17 or 18.
Aspects taught herein are further described by the following non-limiting
Examples.
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EXAMPLE 1
Primer Design
General considerations with respect to multiplex primer design included:
In silico melting temperatures (Tºm s ) of greater than 58ºC, where possible
%GC content of 40-65%, where possible
Avoid runs of more than 3 consecutive Gs or Cs
Amplicon length minimized (t o less than 150bp where possible)
[0139] In the case of RNA targets, the AlexaFluor-labeled (5 amino modified) primer was
the primer responsible for priming the cDNA synthesis from the RNA template during RT-
PCR. Probe oligonucleotides were synthesized with a 5 thiol (Thi o) or acrydite (A mM)
modification to enable coupling to silica beads, and an internal amino modification was
made to the probe oligonucleotides to allow labeling with fluorescent dye (BoDipy-TMR).
Amplification primer pairs (Forward and Reverse) were designed at regions highly
conserved across all strains analyzed, with particular emphasis on maximizing
conservation and minimizing degeneracy at the 3 ends.
Influenza A
Target amplicon alternatives: Segment 7 (MP )
Target Gene: Segment 7 (MP )
Number of sequences analyzed: 16026
Control Construct: RTI-C2
[0140] Comments: Sequences for Influenza A from human hosts were obtained through the
Influenza Primer Design Resource (IPDR). A total of 16026 sequences of the Influenza A
Matrix Protein ( MP ) were used to generate the consensus sequence that was then used to
create a consensus sequence file in Vector NTI. Primers were designed at regions highly
conserved across all strains with particular emphasis on maximizing conservation and
minimizing degeneracy at the 3 ends.
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Primers/Probe 1: Obsolete
Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
Am-InfA F /5AmMC6/TRGGRTTTGTGT 60 50 72
TCACGCTCACCGTG (S EQ
ID NO:127)
P-InfA R GGGCATTTTGGACAAAGC 61 54
GTCTACGC (S EQ ID NO:128)
AS InfA P /5ThioMC6- 62 64 46
D/AAT/iAmMC6T/GAATTCG
GATCCTGCAGTCCTCGCTC
ACTGGGCA (S EQ ID
NO:129)
The efficiency of target amplification using Primers/Probe 1 was deemed to be too
great for practical diagnostic purposes. Repeat tests confirmed that a positive InfA signal
was sporadically observed in samples devoid of Influenza A input template. Due to the
irregularity of these false positive results, spot contamination of the workspace
environment with low amounts of Influenza A was accepted to be the likely cause.
Consequently, the forward primer was re-designed (a lt Am-InfA F) such that the amplicon
length was increased and amplification efficiency reduced (se e Primers/Probe 2, below):
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Primers/Probe 2: Obsolete
Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
(bp ) (bp )
alt Am- /5AmMC6/GACAAGACCAA 59 52 110
InfA F TCCTGTCACCTCTGAC
(S EQ ID NO:130)
P-InfA R GGGCATTTTGGACAAAGC 61 54
GTCTACGC (S EQ ID
NO:131)
AS InfA P /5ThioMC6- 62 64 84
D/AAT/iAmMC6T/GAATTC
GGATCCTGCAGTCCTCGC
TCACTGGGCA (S EQ ID
NO:132)
The use of alt Am-InfA F (P rimers/Probe 2) resulted in the highly sensitive
detection of Influenza A target DNA. However, false-positive results continued to be
obtained under these amplification conditions. As a consequence, an alternative set of
primers/probe allowing the amplification of Influenza A was designed and synthesized
Primers/Probe 3 below
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Primers/Probe 3:
Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
Am-InfA2 F /5AmMC6/CGAGGTCGAAA 58 48 122
CGTAYGTTCTYTCTAT
(S EQ ID NO:1)
InfA2 R GCCATTCCATGAGAGCCT 58 52
CRAGATC ( S EQ ID NO:17)
InfA2 Pr /5ThioMC6-D/AAT 63 58 69
/iAmMC6T/GAATTCGGATC
CAGTCTCTGCGCGATCTC
GGCTTTGAG (S EQ ID
NO:37)
Titration of Influenza A Primers/Probe 3 resulted in amplification/labeling
conditions that allowed the detection of 400 copies and even 100 copies of the synthetic
Influenza A construct. Furthermore, no false-positives were observed over 3 independent
experiments involving a total of 26 designated Water controls and 23 designated
HeLa/MS2 controls. Furthermore, under these conditions, these primers were shown to
efficiently detect the HealthScope Positive Control for InfA/H1N1.
Influenza B
Target amplicon alternatives: Segment 1 (P B2) a nd Segment 4 (HA)
Target Gene: Segment 4 ( H A)
Number of sequences analyzed: 2980
Control Construct: RTI-C3
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Primers/Probe 1: Obsolete
Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
InfB F GCACCAGGAGGACCCTAC 63 59 97
ARAMTTGGA (S EQ ID
NO:133)
InfB R TTGGGACRGCCCAAGCCAT 64 58
TGTTGCG (S EQ ID NO:134)
InfB P ACCTCAGGRTCTTGCCCTA 61 61 70
ACGYTACCA (S EQ ID
NO:135)
In the context of the multiplex scenario, there was in general poor detection of the
Influenza B control construct and confirmed Influenza B positive clinical specimens.
While primary amplification appeared to be efficient (a s judged by band intensity
following gel electrophoresis of PCR products), loading onto beads either via hybridization
following lambda Exonuclease digestion, or via a solid phase amplification procedure
appeared very poor. Thus, an additional set of primers/probe was designed to allow an
alternative probe sequence to be utilized (se e Primers/Probe 2, below).
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Primers/Probe 2:
Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
Am-InfB-2 F /5AmMC6/TACGGTGGATT 57 42 124
AAACAAAAGCAAGCC
(S EQ ID NO:2)
P-InfB-2 R CAGGAGGTCTATATTTG 58 46
GTTCCATTGGC ( S EQ ID
NO:18)
AS InfB-2 P /5ThioMC6- 57 42 64
D/AAT/iAmMC6T/GAATT
CGGATCCGGTGTTTTCAC
CCATATTGGGCAATT
( S EQ ID NO:38)
Influenza A (H 1N1 2009)
Target amplicon alternatives: Segment 4 (HA)
Target Gene: Segment 4 (H A) of the 2009 H1N1 Pandemic strain of Influenza
Number of sequences analyzed: 4839
Control Construct: RTI-C4
Comments: The selected primers/probe were designed to discriminate the 2009
pandemic swine flu from other swine (and human) HI subtype viruses.
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
(bp ) (bp )
Am-H1N1 /5AmMC6/CCCAAGACAAG 59 50 78
F TTCATGGCCCAATCA ( S EQ
ID NO:3)
P-H1N1 R GCTTTTTGCTCCAGCATG 58 48
AGGACAT (S EQ ID NO:19)
AS-H1N1 P /5ThioMC6- 59 55 47
D/AAT/iAmMC6T/GAATTC
GGATCCCATGCTGCCGTT
ACACCTTTGTTCG (S EQ ID
NO:39)
Influenza A (H 5N1)
Target amplicon alternatives: Segment 4 (HA)
Target Gene: Segment 4 (H A) of the H5N1 Pandemic strain of Influenza
Number of sequences analyzed: 2757
Control Construct: RTI-C5
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
Am-H5N1 /5AmMC6/GCTCTGCGATCTAG 61 56 128
F ATGGAGTGAAGCC ( S EQ ID
NO:4)
P-H5N1 R YCTTCTCCACTATGTAAGACC 58 50
ATTCCGG (S EQ ID NO:20)
AS-H5N1 P /5ThioMC6- 60 60 84
D/AAT/iAmMC6T/GAATTCGGA
TCCCCGAGGAGCCATCCAGCT
ACACTAC (S EQ ID NO:40)
Respiratory Syncytial Virus (Ty pes A & B)
Target amplicon alternatives: Polymerase; Glycprotein/Fusion; Nucleoprotein
Target Gene: Polymerase Gene
Number of sequences analyzed: 14
Control Construct: RTI-C18 and RTI-C19
Comments: Highly conserved nucleoprotein and polymerase genes well suited for
detection of both RSV-A and RSV-B. However, inefficient amplification using the initial
primers (Primers/Probe 1) targeting the nucleoprotein gene (c ontrol constructs RTI-C6
and RTI-C7) led to the re-design of primers/probe targeting the polymerase gene (c ontrol
constructs RTI-C18 and RTI-C19; see Primers/Probe 2, below).
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Primers/Probe 1: Nucleoprotein - Obsolete
Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
RSV F TTGGGWGGAGAAGCWGGW 59 50 122
TTCTACCA ( S EQ ID NO:136)
RSV R ATTATGCCTAGRCCWGCWG 62 54
CATTGCC (S EQ ID NO:137)
RSV P ARYARTGATGCTTTTGGRTT 53/55* 31 56
GTTCAATAT (S EQ ID NO:138)
Primers/Probe 2: Polymerase
Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
(bp ) (bp )
Am-RSV-3 F /5AmMC6/ACAGTCAGTA 55 41 126
GTAGACCATGTGAATTC
(S EQ ID NO:5)
P-RSV-3 R RTCRATATCTTCATCAC 54 28
CATACTTTTCTGTTA
(S EQ ID NO:21)
AS-RSV-3 P /5ThioMC6- 54 42 53
D/AAT/iAmMC6T/GAATT
CGGATCCGTTCTATAAG
CTGGTATTGATGCAGG
(S EQ ID NO:41)
Human Parainfluenza Virus Type 1 (H PIV-1)
Target amplicon alternatives: HN
Target Gene: HN
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Number of sequences analyzed: 30
Control Construct: RTI-C8
Comments: While the primary amplification product using the Primers/Probe 1
sequences below appeared highly efficient from the synthetic template (a s judged by gel
electrophoresis), loading onto the beads and therefore solid phase detection was poor.
Thus, an alternative set of Primers/Probe was designed and synthesized (Primers/Probe 2).
Following primer concentration optimization, Solid Phase detection sensitivity was not
dramatically enhanced using the new primers/probe set. However, Primers/Probe 2 was
ultimately utilized following a direct sequence comparison of the two primer sets
indicating that Primers/Probe 2 would likely detect a higher proportion of the HN database
sequences analyzed.
Primers/Probe 1: Obsolete
Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
Am-Para1 F /5AmMC6/TGGCACTC 60 48 108
CAACCTGCAAATAGG
ATCA (S EQ ID NO:139)
P-Para1 R CCAGTTGCAGTCTTG 62 56
GTTTCCTGGTCG ( S EQ
ID NO:140)
AS-Para1 P /5ThioMC6- 60 59 51
D/AAT/iAmMC6T/GAA
TTCGGATCCACAGGA
CTTYATGAGGCGCCC
A (S EQ ID NO:141)
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Primers/Probe 2:
Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
(bp ) (bp )
Am GB /5AmMC6/TGGTGATGCAA 54 37 131
HPIV1 F TATATGCGTATTCATC
(S EQ ID NO:6)
P GB CCGGGTTTAAATCAGGAT 54 41
HPIV1 R ACATATCTG (S EQ ID
NO:22)
GB /5ThioMC6- 55 41 60
HPIV1 P D/AAT/iAmMC6T/GAATTC
GGATCCCCTATATCTGCA
CATCCTTGAGTGATT (S EQ
ID NO:42)
Human Parainfluenza Virus Type 2 (H PIV-2)
Target amplicon alternatives: HN
Target Gene: HN
Number of sequences analyzed: 13
Control Construct: RTI-C9
Comments: A total of 18 sequences were aligned using the EMBL-EBI software
and a highly conserved region for which there was data for 13/18 sequences was identified.
From the resulting consensus sequence, the following primers/probe sequences were
identified.
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) ( bp )
Am-Para2 F /5AmMC6/CYCGTCCTGGA 63 60 90
GTCATGCCATGCAA (SEQ
ID NO:7)
P-Para2 R CRTTAAGCGGCCACACAT 62 58
CTGCGT ( S EQ ID NO:23)
AS-Para2 P /5ThioMC6- 62 54 52
D/AAT/iAmMC6T/GAATTC
GGATCCACCCCTGTGATG
CAATTAGCAGGGCA ( S Eq
ID NO:43)
Human Parainfluenza Virus Type 3 (H PIV-3)
Target amplicon alternatives: HN
Target Gene: HN
Number of sequences analyzed: 5 complete genome sequences and 18 HN sequences
Control Construct: RTI-C10
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) ( bp )
Am- /5AmMC6/CAAGTTGGCAYAGC 58 41 123
Para3 F AAGTTACAATTAGGA ( S EQ ID
NO:8)
P-Para3 GTCCCCATGGACATTCATTGTT 61 48
R TCCTGGT (S EQ ID NO:24)
AS-Para3 /5ThioMC6- 56 39 63
P D/AAT/iAmMC6T/GAATTCGGA
TCCAGCACATTATGCCATGTCC
ATTTTATCC (S Eq ID NO:44)
Human Parainfluenza Virus Type 4 (H PIV-4)
Target amplicon alternatives: Phosphoprotein (P ) g ene
Target Gene: P gene
Number of sequences analyzed: 40
Control Construct: RTI-C11
Comments: Alignment of 40 sequences of 4a (22) and 4b (18 ) phosphoprotein
genes with the only complete genome sequence in the NCBI database (H PIV 4b;
Accession number EU627591) using the EMBL-EBI software resulted in a consensus
sequence that could be used to design primers/probe.
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
Am-Para4 F /5AmMC6/GTTGATCAAGACA 53 31 109
ATACAATTACACTTGA (S EQ
ID NO:9)
P-Para4 R TAAGTGCATCTATACGAACR 59* 46*
CCTGCTC (S EQ ID NO:25)
AS-Para4 P /5ThioMC6- 59* 44* 75
D/AAT/iAmMC6T/GAATTCGG
ATCCGGTTCCAGAYAAWATG
GGTCTTGCTA (S Eq ID NO:45)
*Based on EU627591
Human Metapneumovirus (h MPV)
Target amplicon alternatives: Nucleoprotein (N) , Matrix (M )
Target Gene: M2 region of Matrix
Number of sequences analyzed: 74
Control Construct: RTI-C12
[0150] Comments: A consensus sequence of the M2 gene was initially made from
alignments of 12 complete genome sequences using software at EMBL-EBI, and from this
primers/probe was designed. These primers were then checked against Contig 4 of the
Matrix and NC_004148 assembly that assembled all hMPV matrix sequences with the
hMPV reference sequence (N C_004148).
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
Am-hMPV F /5AmMC6/GACAAATCATM 58 45 109
ATGTCTCGYAARGCTCC
(S EQ ID NO:10)
P-hMPV R CTATCWGGCCAACTCCAG 56 46
TAATTGTG (S EQ ID NO:26)
AS-hMPV P /5ThioMC6- 58 46 80
D/AAT/iAmMC6T/GAATTC
GGATCCTTGCCCCGYACT
TCATATTTGCA (S EQ ID
NO:46)
Adenovirus (Ty pes B, C and E) (A dV)
Target amplicon alternatives: Hexon
Target Gene: Hexon
Number of sequences analyzed: 247 Hexon sequences and 15 complete genome sequences
Control Construct: RTI-C13
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) ( bp )
P-AdV F TGCCSCARTGGKCDTACATG 62 54 82
CACATC (S EQ ID NO:11/12)
AdV R /5AmMC6/GCRCGGGCRAACT 64 70
GCACCAG ( S EQ ID NO:27/28)
AdV B/E P /5ThioMC6- 63* 63 44
D/AAT/iAmMC6T/GAATTCGG
ATCCGCTTCGGAGTACCTGA
GTCCGGGT (S Eq ID NO:47)
AdV C P /5ThioMC6- 64* 63 56
D/AAT/iAmMC6T/GAATTCGG
ATCCTCGGGCCAGGACGCC
TCGGAGTAC (S EQ ID NO:48)
*calculated in Vector NTI
Rhinovirus/Enterovirus (R hV)
Target amplicon alternatives: 5UTR (unt ranslated region)
Target Amplicon: 5UTR
Number of sequences analyzed: 962 5UTR sequences and 138 complete genome
sequences
Control Construct: RTI-C14
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Primary Nested
Name Sequence Tºm* %GC Amplicon Amplicon
( bp ) (bp )
truncRhi R /5AmMC6/GAAACACGGAC 54 48 209
ACCCAAAGTAGT ( S EQ ID
NO:13)
P-T7truncRhi F ACTCACTATAGGAGCCTG 55 75
CGTGGCKGCC (S EQ ID
NO:29)
Rhi P /5ThioMC6- 69 60 120
D/AAT/iAmMC6T/GAATTC
GGATCCTCCTCCGGCCCC
TGAATGYGGCTAA (S EQ
ID NO:49)
Bordetella pertussis (B per)
Target amplicon alternatives: IS481; ptx
Target Gene: Segment 4 ( H A)
Number of sequences analyzed: 2980
Control Construct: RTI-C15
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
P-Bper F CCGGCCGGATGAACACCCA 63 60 105
TAAGCA ( S EQ ID NO:14)
Bper R /5AmMC6/GGGCCGCTTCAGG 63 60
CACACAAACTTG (S EQ ID
NO:30)
Bper P /5ThioMC6- 61 56 80
D/AAT/iAmMC6T/GAATTCGG
ATCCTGCCCGATTGACCTTC
CTACGTCGA (S EQ ID NO:50)
Chlamidophila pneumoniae (C pn)
Target amplicon alternatives: MOMP
Target Gene: MOMP
Number of sequences analyzed: 19
Control Construct: RTI-C16
Comments: primers/probe located within a highly conserved region of the Major
Outer Membrane Protein (MO MP).
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
P-Cpn F CATGAATGGCAAGTAGGAGC 57 52 122
CTCTC (S EQ ID NO:15)
Cpn R /5AmMC6/AGTTTTGGCTGAGC 60 48
AATGCGGATGT (S EQ ID
NO:31)
Cpn P /5ThioMC6- 58 48 53
D/AAT/iAmMC6T/GAATTCGGA
TCCTGGTCTCGAGCAACTTTT
GATGCTG ( S EQ ID NO:51)
Mycoplasma pneumoniae (Mpn eu)
Target amplicon alternatives: P1 Cytadhesin, 16s rRNA and ATPase
Target Gene: P1 Cytadhesin
Number of sequences analyzed: 212
Control Construct: RTI-C17
Comments: Consensus was finally derived from 5 sequences from a highly
conserved region of the P1 cytadhesin gene.
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
P-Mpneu GAACCGAAGCGGCTTTGACCG 63 60 114
F CATC (S EQ ID NO:16)
Mpneu R /5AmMC6/GCGTGGGCGTTTGC 63 56
GGGTTTAACTT (S EQ ID NO:32)
Mpneu P /5ThioMC6- 63 60 55
D/AAT/iAmMC6T/GAATTCGGA
TCCGGGCGCGCCTTATACGAC
CTCGATT (S EQ ID NO:52)
MS-2 phage (MS -2)
Target amplicon alternatives: Matrix
Target Gene: Matrix
Number of sequences analyzed: 2 complete genomes
Control Construct: RTI-C1
Comments: The MS-2 control was used to determine that in-tact RNA has been
successfully extracted using the recommended nucleic acid purification procedure. Purified
MS2 RNA was added to reaction tubes immediately after addition of the lysis solution
within the nucleic acid extraction/purification procedure.
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Primary Nested
Name Sequence Tºm %GC Amplicon Amplicon
( bp ) (bp )
P-MS2-2 GCACGCTCCTGCTACAGC 63 64 102
F CTCTTCC (S EQ ID NO:35)
MS2-2 R /5AmMC6/CTTTTGCAGGA 62 60
CTTCGGTCGACGCC (S EQ
ID NO:36)
MS2-2 P /5ThioMC6- 63 60 51
D/AAT/iAmMC6T/GAATTC
GGATCCGAAGTGCCGCAG
AACGTTGCGAACC (S EQ
ID NO:54)
Human
Target amplicon alternatives: MYL3, -actin
Target Gene: MYL3
Number of sequences analyzed: 1
Control: RNase free HeLa genomic preparation (Q iagen)
Comments: The purpose of this internal control was to establish adequate specimen
amount and integrity. The MYL3 gene is a single copy gene that is expressed primarily in
cardiac tissue. In contrast, the -actin gene has multiple copies and pseudogenes, and is
highly expressed in all tissues.
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Primary Nested
Name Sequence Tºm* %GC Amplicon Amplicon
(bp ) ( bp )
P-MYL3 GCACCCAGACAATACACA 59 52 131
F CAGGTGT (S EQ ID NO:33)
MYL3 R /5AmMC6/GGCGGAAGTCAG 59 59
CATGTGTCTG (S EQ ID
NO:34)
PapType /5Acryd/AAT/iAmMC6T/AAA 64 58 87
ProbeML GGGAGGACAGCTATGGAC
C_Int CAAACACAGACACAGAGA
Oligo GACCCACAGACA ( S EQ ID
NO:53)
*calculated on Vector NTI
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EXAMPLE 2
Unlabeled Oligonucleotide Preparation
All oligonucleotides were ordered desalted from Integrated DNA Technologies
( IDT). Following 3 rounds of ethanol precipitation, primers were dissolved in water such
that a theoretical concentration of approximately 400 M was achieved based on the
datasheet provided by IDT.
Unlabeled probe oligonucleotides were ordered desalted from IDT and following 3
rounds of ethanol precipitation were dissolved in water such that a theoretical
concentration of approximately 400 M was achieved based on the datasheet provided by
IDT. Unlabeled stock oligonucleotides were stored at -20ºC.
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EXAMPLE 3
Oligonucleotide labeling with Bodipy-TMR and AlexaFluor647
Primer and probe oligonucleotides synthesized with an amine modification at the
C6 position of an internal thymidine nucleotide were labeled overnight with a 15 fold
molar excess of the succinimidyl ester of the appropriate dye (Invitrogen) in the presence
of 0.1M Carbonate Buffer pH 9.0. Oligonucleotides were then subjected to 3 rounds of
ethanol precipitation to remove unconjugated dye and adjusted with unlabeled (but
otherwise identical) oligonucleotides to achieve desired labeled to unlabeled
oligonucleotide ratios. The final concentration and TO:FLO of labeled oligonucleotides
was adjusted using the formulae below:
V0 = V2 C2 ( ( T F1/TF0)- 1) / C0
Vw = (1/ Ct ( ( V 2 C2) + (V 0 C0)) ) ( V 2 + V0)
Where:
V0 Unlabeled oligo required to add
V2 Volume of Labeled oligo to be used for adjustment
C2 Conc. Of Labeled oligo to be used for adjustment
TF1 Target TO:FLO
TF0 Initial TO:FLO
C0 Conc. Of Unlabeled oligo
Vw Volume of water required to add.
Ct Target conc.
In general, for labeled primer oligonucleotides, the ratio of labeled to unlabeled
oligonucleotide was 1:1.8. For labeled probe oligonucleotides designed to be conjugated to
the high TMR and medium TMR beads, the ratio of labeled to unlabeled oligonucleotide
was 1:2 and 1:100, respectively. TO:FLO adjusted labeled primer oligonucleotides were
stored at -20ºC.
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EXAMPLE 4
Bead Silanization, Probe Coupling and Bead Pooling
A volume of 5 L of bead mix prepared in this way was used per RT-PCR
reaction.Silica beads (Bangs Laboratories Inc.) were washed 3 times in water and pelleted
beads were then treated with 1.55M HNO for 30min at room temperature. Beads were
then washed 5 times in water and 3 times in Isopropanol. In a round bottomed flask,
approximately 1 10 beads in 95mL Isopropanol were then brought to the boil and 0.5mL
water and 5mL of freshly opened 3-mercaptopropyl trimethoxysilane ( 3 MPTS; Sigma)
added. Silanization was carried out for 23-25h under reflux after which beads were washed
3 times in Isopropanol and dried at 45ºC for 40min in a vacuum concentrator. Dried beads
were then heat cured for 16-24h at 105ºC before being stored at room temperature under
Argon gas. For probe oligonucleotide coupling, silanized beads were weighed and
resuspended in 0.1M MES buffer ( S igma Aldrich) adjusted to pH 4.75 and then coupled to
probe oligonucleotides (IDT) via a 5 -Acrydite (T rade Mark) modification in the presence
of 1% w/v ammonium persulfate (APS) before being washed and then resuspended in
Acquisition Buffer (10m M Tris-Cl, 0.5mM EDTA, 0.0125% w/v NaN , 0.01% v/v Triton
X-100). Individual bead solutions were then counted in a Z1 Coulter Particle Counter
( B eckman Coulter) and adjusted to 2.1 10 beads/mL before being pooled in equimolar
ratios and adjusted to a final concentration of 1.26 10 beads/mL. Specifically, bead
pooling was performed by mixing equal proportions of each (18 ) coupled bead populations
at 2.1 10 beads/mL followed by the addition of Acquisition Buffer equivalent to 2/3 the
volume of the mixed beads. See Table 3.
For Example: Pooling 10 L of each bead
18 10 L individual beads = 180 L
Add 2/3 180 L = 120 L of Acquisition Buffer
Final Volume = 180 L + 120 L = 300 L beadpool
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A volume of 5 L of bead mix prepared in this way was used per RT-PCR reaction.
It should also be noted that initial experiments involved the resuspension of pooled beads
in a buffer similar to Acquisition Buffer but with reduced Triton X-100 (0. 001% v/v Triton
X-100). Subsequent experimental data (nv3p g8) showed equivalent results were obtained
when beads were pooled in either Acquisition Buffer or the Acquisition Buffer with
reduced Triton X-100 (0.001% v/v Triton X-100). Thus, for convenience and
manufacturing processes more in line current protocols, beadpools were ultimately
assembled in Acquisition Buffer.
[0161] Once a primer pair was decided upon, the control construct was then designed.
Control constructs were obtained from GenScript in 100ug lyophilized form in which a
synthetically made DNA insert of approximately 500bp was blunt cloned into polylinker of
the in-house vector pUC57. In general, the synthetically made DNA inserts were designed
with the following key features:
1) 5 T7 and T3 promoters for e fficient in vitro transcription;
2) Target amplicon plus >20bp or flanking sequence;
3) Alternative amplicons (e .g. HealthScope or other literature) with >20bp of flanking
sequence;
4) 3 Not I restriction site for linearization of template allowing transcription
termination (e nsuring that no internal Not I sites are present in the pathogen sequences).
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Table 3
Volumes of 100 M Probe Oligonucleotide Required /mg of Beads
Bead Size Vol (uL) of 100uM oligo
( um) per mg beads
Probe oligo ID Sequence TO:FLO
InfA2 Pr /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC AGTCTCTGCGCGATCTCGGCTTTGAG 5.66 na 17.5
AS InfB-2 P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC GGTGTTTTCACCCATATTGGGCAATT 5.20 120.00 34
AS-H1N1 P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC CATGCTGCCGTTACACCTTTGTTCG 3.00 na 73
AS-H5N1 P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC CCGAGGAGCCATCCAGCTACACTAC 5.01 na 34
AS-RSV-3 P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC GTTCTATAAGCTGGTATTGATGCAGG 3.77 na 72
GB HPIV1 P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC CCTATATCTGCACATCCTTGAGTGATT 3.77 2.00 72
AS-Para2 P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC ACCCCTGTGATGCAATTAGCAGGGCA 3.49 2.00 53
AS-Para3 P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC AGCACATTATGCCATGTCCATTTTATCC 3.00 2.00 73
.66 80.00 17.5
AS-Para4 P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC GGTTCCAGAYAAWATGGGTCTTGCTA
AS-hMPV P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC TTGCCCCG ACTTCATATTTGCA 3.77 75.00 72
AdV B/E P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC GCTTCGGAGTACCTGAGTCCGGGT 5.20 na 34
AdV C P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC TCGGGCCAGGACGCCTCGGAGTAC 5.20 na 34
Rhi P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC TCCTCCGGCCCCTGAATGYGGCTAA 5.01 100.00 34
.66 2.00 17.5
Bper P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC TGCCCGATTGACCTTCCTACGTCGA
Cpn P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC TGGTCTCGAGCAACTTTTGATGCTG 5.20 1.50 34
Mpneu P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC GGGCGCGCCTTATACGACCTCGATT 5.01 2.00 34
MS2-2 P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCC GAAGTGCCGCAGAACGTTGCGAACC 3.49 na 53
/5Acryd/AAT/iAmMC6T/AAAGGGAGGACAGCTATGGACCAAACACAGACACAGAGAGACCCACAGACA
3.49 100.00 53
PapType ProbeMLC_Int Oligo
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EXAMPLE 5
Control Construct Design and Construction
For the RNA viruses, particular care was taken to ensure that upon RNA
transcription of the insert, the correct (genomic) se nse RNA was produced.
All control constructs were designed and saved in Vector-NTI for record purposes.
Hard copies of the vector diagrams were archived. The sequences as submitted to
GenScript are given in Figure 1. It should be noted that due to a necessary primer/probe re-
design for respiratory syncytial virus, additional control constructs were designed and
synthesized for this pathogen. Control constructs RTI-C18 and RTI-C19 encompassing
portions of the RSV Polymerase gene are those templates targeted by the final RSV
primers/probe.
[0164] In vitro transcription using the synthetic control construct templates was performed
using the Ambion Megascript kit according to the manufacturers instructions. Briefly,
lyophilized DNA templates were dissolved in RNase free water to approximately 1 g/ l
and 10 g linearized with the restriction enzyme Not I for 2 hours at 37ºC in 1 NEBuffer
3 + BSA. Reactions were then heat inactivated for 20 min at 65ºC and the nucleic acid
purified using the Qiagen gel extraction kit according to the manufacturers instructions.
DNA eluted into 100 l of nuclease free water was then subjected to ethanol precipitation
with the final DNA pellet dissolved in 12 l of nuclease free water. An aliquot of each
DNA sample was then quantified using the spectrophotometer.
[0165] In vitro transcription was performed on 1 g of the freshly prepared DNA templates
and allowed to proceed for 3h and 30min at 37ºC in the thermocycler. 1 L of Turbo
DNase was then added and reactions incubated for a further 15min at 37ºC to remove all
traces of the input DNA template. RNA was recovered using the RNeasy kit as per
manufacturers instructions and eluted in 50 L of RNA Storage Solution (Ambion). RNA
was quantified in triplicate using the spectrophotometer and RNA integrity and
concentration confirmed by denaturing agarose gel electrophoresis. The identity of the
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transcribed RNA was confirmed by PCR with primers designed to amplify specific internal
sequences (se e Figure 2).
In general, aliquots of the RNA stock solutions were diluted to 1 10 copies/ L in
RNA Storage Solution (A mbion) and stored at -20ºC until required. Optimization of the
assay was routinely performed on known amounts of RNA freshly diluted from the 1 10
copies/ L stock tubes.
No obvious degradation of the RNA stocks (st ored in RNA Storage Buffer) was
observed after 1 month storage at -20ºC as determined by denaturing agarose gel
electrophoresis and spectrophotometry.
EXAMPLE 6
Solid Phase RT-PCR
One Step RT-PCRs were set up essentially according to the manufacturers
instructions (Q iagen). Briefly, 10 L of a master mix containing 1 reaction buffer,
dNTPs, oligonucleotides (se e body text for oligonucleotide sequences) and enzyme mix
were added to 5 L of preplated beads. Sample (10 L) was then added and plates sealed
and spun at 300 g for 1min. Trays were then subjected to incubations of 50ºC for 20min
and 95ºC for 15min before being cycled ( 45 cycles) as follows: 95ºC for 30sec, 60ºC
30sec and 72ºC for 1min. A final extension step of 2min at 72ºC was included prior to
initiating an hybridization profile that involved an initial incubation of 90ºC for 30sec and
then the stepwise reduction of incubation temperature by 1ºC every 15sec for 65 cycles
such that a final temperature of 25ºC was achieved.
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EXAMPLE 7
Data Acquisition and Analysis
Following Solid Phase RT-PCR cycling, plates were spun for 1min at 1000 g and
pelleted beads washed 5 times in 120 L of Sheath Buffer (8m M NaCl, 0.0001% v/v Triton
X-100) with a spin at 300 g for 1min between addition of wash buffer to pellet beads.
Alternatively, plate washes were performed in a Hydrospeed platewasher ( Tecan) allowing
a 5min bead settling time between cycles of gentle aspiration and dispense. Beads were
finally resuspended in 80 L to 120 L of Sheath Buffer prior to analysis on the
FACSArray Flow Cytometer ( B D Biosciences). Data exported as FCS 2.0 files was then
analyzed using either FCS Express (D e Novo Software) or customized analysis software
(G enera Biosystems).
EXAMPLE 8
PCR Optimization
Annealing Temperature I: Flanking primers (i nternal probe oligonucleotide absent)
The annealing temperatures for primer pairs that allowed efficient PCR
amplification of target templates was initially determined using gradient PCRs and HotStar
Taq in Qiagen RT-PCR buffer. PCRs were performed on 10000 copies of the target
template (10 L of 1000 copies/ L) . To ensure a broad range of annealing temperatures
would be assessed a gradient of annealing temperatures from 52-70 ºC was used. This
translated to temperatures of 51.8ºC, 52.2ºC, 53.3ºC, 55.0ºC, 57.1ºC, 59.5ºC, 61.9ºC,
64.3ºC, 66.5ºC, 68.2ºC, 69.5ºC and 70.0ºC across wells within each row of the Eppendorf
Mastercycler Ep S used in this experiment. PCRs were cycled as follows: 95ºC 15min and
then 40 cycles of 95ºC 30sec, grad 52-70ºC 30sec, 72ºC 30sec with a final extension of
10min.
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In all cases, 5 L of PCR product was run down a 2.5% TAE Agarose gel (r un at
150V) and DNA was visualized on a UV transilluminator following staining in SYBR-safe
dye (Invitrogen) for 20min at a final 2 concentration. The annealing temperature resulting
in efficient PCR amplification (a s judged by band intensity) for each primer set was then
determined and is shown below in Table 4, below:
Table 4
Annealing Temperatures for First-Generation Primers
Pathogen T°anneal
Influenza A* 61.9
Influenza B* 64.3
Influenza A H1N1 61.9
Influenza A H5N1 66.5
RSV-A* 61.9
RSV-B* 64.3
Parainfluenza 1 61.9
Parainfluenza 2 66.5
Parainfluenza 3 61.9
Parainfluenza 4 61.9
Metapneumovirus 59.5
Adenovirus 61.9
Rhinovirus* 64.3
B. pertussis 61.9
C. pneumoniae 64.3
M. pneumoniae 61.9
MS2 Phage* 70
*results obtained on early primer pairs that are different to those used in the final assay.
Consistent with the in silico predictions, the annealing temperatures allowing
maximal amplification of target templates was generally high (> 59ºC) and varied from
59.5ºC to 70ºC. An annealing temperature of 60ºC allowed for the efficient amplification
of all targets and was therefore initially selected as the annealing temperature for the solid
phase RT-PCR component of the assay. It should be reiterated that some of this data was
derived from first-generation primer pairs not used in the final assay.
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Multiplex PCRs: DNA Template; No Background DNA
PCR reactions (i n the absence of reverse transcription) using DNA templates were
initially conducted with a primer mix containing 0.6 M (f inal) concentration of each
primer (a s recommended by the manufacturer for use with the Qiagen One-step RT-PCR
kit). Under these conditions, all targets were amplified as judged by visualizing bands
following PAGE electrophoresis for 4h at 100V through 15% w/v TBE pre-cast gels
(B iorad). Poor amplification was reproducibly noted for RSV-A, hMPV and RhV.
Subsequent experiments in which primer-pair concentrations within the primer mix were
modulated identified primer mixes that facilitated the efficient amplification of all target
analytes (se e Figure 3).
Multiplex RT-PCRs: RNA Template +/- Background DNA
[0174] Using primer concentrations established in DNA template experiments, initial RT-
PCRs on 10000 copies of RNA targets showed inefficient amplification of a variety of
target analytes, including MS2, RSV-A, Para3, Para4, hMPV, AdV and RhV. Optimization
experiments modulating the duration (20m in vs 30min) and temperature (40ºC vs 45ºC vs
50 vs 55 vs 60) of the RT step did not results in more efficient amplification of target
templates as judged by PAGE analysis. Thus, the manufacturers recommendation of 50ºC
for 20min was used for all subsequent reverse transcription steps.
Experiments in which primer-pair concentrations within the primer mix were
modulated, and primers/probe combinations were redesigned for MS2 and RSV identified
primer mixes that facilitated the visible amplification (b y polyacrylamide gel
electrophoresis) of all target analytes except RhV (se e Figure 4).
The subsequent addition of RNAse-free background HeLa chromosomal DNA (t o a
final concentration of approximately 2500 cell equivalents per reaction) did not
significantly alter the amplification profile as judged by PAGE analysis (se e Figure 5
below).
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EXAMPLE 9
Asymmetric RT-PCR
To optimize loading of PCR products onto beads during the Solid Phase RT-PCR,
primers were carefully titrated in order to introduce a level of asymmetry into the
amplification of target analytes. Specifically, for each analyte the unlabeled primer (of the
same sense as that of the probe oligonucleotide) was serially reduced to a greater than 50
fold molar deficit when compared to the labeled primer. The resulting asymmetric
amplification profile was expected to allow an excess of the nascent strands available for
subsequent successful priming with the probe oligonucleotide to accumulate. Indeed, in
most cases more efficient loading onto beads was observed with decreasing amounts of the
unlabeled primers. However, molar ratios of unlabeled:labeled primers that gave optimal
loading of PCR products onto cognate beads ranged from 1:1 to 1: 6, respectively (se e
Table 5, below).
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Table 5
Primer Concentrations Directing Efficient Bead-based Detection Following RT-PCR
Amplification of Target Analytes
Final Primer Ratio
Primer
Concentration (uM) (Labeled/Unlabeled)
InfA2 R 0.4
Am-InfA2 F* 0.6
P-InfB-2 R 0.2
Am-InfB-2 F* 1.2
P-H1N1 R 0.4
Am-H1N1 F* 0.6
P-H5N1 R 0.2
Am-H5N1 F* 1.2
P-RSV-3 R 0.8
1.25
Am-RSV-3 F* 1
GB P-HPIV1 R 1
GB HPIV1 F* 1
P-Para2 R 0.15
3.33
Am-Para2 F* 0.5
Para3 R 0.5
Am-Para3 F* 1.2
Para4 R 0.7
1.29
Am-Para4 F* 0.9
P-hMPV R 0.6
1.33
Am-hMPV F* 0.8
P-AdV F 0.35
2.57
AdV R* 0.9
P-T7truncRhi F 0.6
1.33
truncRhi R* 0.8
P-Bper F 0.1
Bper R* 0.4
P-Cpn F 0.4
Cpn R* 1
P-Mpneu F 0.2
Mpneu R* 0.4
P-MS2-2 F 0.4
Am-MS2-2 R* 1
hum f 0.075
.33
hum R* 0.4
*AlexaFluor 647 -labeled primers
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EXAMPLE 10
Analyte Detection Sensitivities
Preliminary analyte detection sensitivities were defined following amplification
and detection of known amounts of synthetic control constructs using RTIplots threshold
values established. Washes ( 6) were conducted using 1 Sheath buffer. Unambiguous
calls were successfully made for the following copies of synthetic constructs (se e Table 6):
Table 6
Confirmed Analyte Detection Sensitivities
Copies Detected
Analyte
Influenza A 400
Influenza B
H1N1 400
H5N1 2000
2000
RSV (A&B)
Parainfluenza 1 2000
Parainfluenza 2 2000
5000
Parainfluenza 3
Parainfluenza 4 2000
hMPV 2000
AdV 2000
RhV 10000
B. pertussis
C. pneumophila 2000
M. pneumophila
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EXAMPLE 11
Detection Sensitivities of RSV-A vs RSV-B
Preliminary data analyzing the sensitivity of detection of RSV (R SV-A and RSV-
B) involved using an equimolar mixture of both the C18 and C19 control constructs (se e
Figure 1 for sequences) as a target template. Therefore, to obtain independent detection
sensitivity data for both RSV-A and RSV-B, known copies of either construct was
independently assessed using the multiplex assay according to the present invention. The
assay allowed the successful detection of 125 copies of the RSV-A construct (C 18) and
250 copies of the RSV-B construct (C 19) following analysis using RTIplots software (w ith
a threshold setting of 400 for RSV).
EXAMPLE 12
Clinical Data
A preliminary evaluation of the assay was conducted in a blinded fashion on an
enriched set of 72 archived samples (Ta ble 7) for which data generated via viral isolation
from cell culture were recorded. Samples were either stored at -80ºC as nucleic acid or as
clinical specimens that required re-extraction prior to assaying. A summary of the findings
of this study are shown in Figure 6. It should be noted that the viral culture data from 3
samples indicated a coinfection; thus the total number of samples (72 ) is equal to the 62
analyte-positive samples plus the 13 analyte-negative samples minus 3 to account for
coinfected samples.
[0181] Briefly, the data indicate a 95% concordance of the assay with cell culture data for
analyte positive samples (e xcluding indeterminate RTIplex results from the analysis).
Furthermore, of the 13 samples for which virus was unable to be isolated and/or identified
following culture, the assay was able to detect pathogens in 7 (54% ) of these samples.
Furthermore, from these 72 clinical specimens, the assay detected a total of 24 analytes
previously unreported by the cell culture techniques. Many of these additionally identified
analytes have been confirmed by PCR-based methods (pe rformed at the Department of
Molecular Microbiology, Royal Womens Hospital, Melbourne, Victoria, Australia.
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Table 7
Cell culture data analysis on archived clinial specimens
2009 Archived Clinical Specimens
Cell Culture Data Analysis
RTIplex POS; Unreported Cell Culture
Concordant % Concordance
Cell Culture MM PCR POS Notes Cell Culture Infections/Coinfections
RTIplex* with Cell Culture
NEG identified by RTIplex
InfA 11 NT 10 91% 0
InfB 4 NT 4 100% 0
H1N1 NT (4/7) (8) na 0
H5N1 NT - - na 0
RSV 13 NT 12 92% *RTIplex Hu IC NEG (IND) 2
Para1 0 - - na 1
Para2 9 NT 7 78% *RTIplex Hu IC NEG (IND) 1
Para3 11 1/1 11 100% 0
Para4 NT - - na 0
hMPV 3 NT 3 100% 0
AdV 4 NT 4 100% 2
RhV NT - - na 9
Bper 3 NT 3 100% 4
Cpn 0 - - na 0
Mpneu 4 NT 3 75% 5
Total 62 na 57 92% (9 5% if exclude INDs) 24
No Isolation 13 na 5 na 7
NT = Not Tested
MM = Department of Molecular Microbiology, Royal Womens Hospital, Melbourne, Victoria, Australia
IND = Indeterminant
na = not applicable
Hu IC = human internal control
EXAMPLE 13
Oligonucleotide primers and probes used in the assay method
Table 8 provides a list of primers and capture probes used in the assay method and
kit for respiratory pathogens. At least two primer pairs and corresponding probes are used
in the kit. By "at least two" means 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17 or 18.
Those skilled in the art will appreciate that aspects of aspects described herein are
susceptible to variations and modifications other than those specifically described. It is to
be understood that these aspects include all such variations and modifications. These
aspects also include all of the steps, features, compositions and compounds referred to or
indicated in this specification, individually or collectively, and any and all combinations of
any two or more of the steps or features.
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Table 8
Primers and capture probes used in the assay method for rspiratory pathogens
Analyte Target Primary Oligo ID Sequence (5 '-3')
Amplicon
Length (b p)
Influenza A Segment 7 MP 122 Am-InfA2 F /5AmMC6/CGAGGTCGAAACGTAYGTTCTYTCTAT
InfA2 R GCCATTCCATGAGAGCCTCRAGATC
Acry InfA2 Pr /5Acryd/AATTGAATTCGGATCCAGTCTCTGCGCGATCTCGGCTTTGAG
Influenza B Segment 4 HA 124 Am-InfB-2 F /5AmMC6/TACGGTGGATTAAACAAAAGCAAGCC
InfB-2 R CAGGAGGTCTATATTTGGTTCCATTGGC
Acry AS InfB-2 P /5Acryd/AAT/iAmMC6T/GAATTCGGATCCGGTGTTTTCACCCATATTGGGCAATT
Influenza A Segment 4 HA 78 H1N1 R /5AmMC6/GCTTTTTGCTCCAGCATGAGGACAT
H1N1( 2 009)
H1N1 F CCCAAGACAAGTTCATGGCCCAATCA
Acry H1N1 P /5Acryd/AATTGAATTCGGATCC CGAACAAAGGTGTAACGGCAGCATG
Influenza A Segment 4 HA 128 Am-H5N1 F /5AmMC6/GCTCTGCGATCTAGATGGAGTGAAGCC
H5N1 ( A vian)
H5N1 R YCTTCTCCACTATGTAAGACCATTCCGG
Acry AS-H5N1 P /5Acryd/AATTGAATTCGGATCCCCGAGGAGCCATCCAGCTACACTAC
RSV (A &B) Polymerase 126 Am-RSV-3 F /5AmMC6/ACAGTCAGTAGTAGACCATGTGAATTC
RSV-3 R RTCRATATCTTCATCACCATACTTTTCTGTTA
Acry AS-RSV-3 P /5Acryd/AATTGAATTCGGATCCGTTCTATAAGCTGGTATTGATGCAGG
HPIV-1 HN 131 Am GB HPIV1 F /5AmMC6/TGGTGATGCAATATATGCGTATTCATC
GB HPIV1 R CCGGGTTTAAATCAGGATACATATCTG
Acry GB HPIV1 P /5Acryd/AAT/iAmMC6T/GAATTCGGATCCCCTATATCTGCACATCCTTGAGTGATT
HPIV-2 HN 90 Am-Para2 F /5AmMC6/CYCGTCCTGGAGTCATGCCATGCAA
Para2 R CRTTAAGCGGCCACACATCTGCGT
Acry AS-Para2 P /5Acryd/AAT/iAmMC6T/GAATTCGGATCCACCCCTGTGATGCAATTAGCAGGGCA
HPIV-3 HN 123 Am-Para3 F /5AmMC6/CAAGTTGGCAYAGCAAGTTACAATTAGGA
Para3 R GTCCCCATGGACATTCATTGTTTCCTGGT
Acry AS-Para3 P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCCAGCACATTATGCCATGTCCATTTTATCC
HPIV-4 Phosphoprotein 109 Am-Para4 F /5AmMC6/GTTGATCAAGACAATACAATTACACTTGA
Para4 R TAAGTGCATCTATACGAACRCCTGCTC
Acry GB HPIV-4 Pr1 /5Acryd/AAT/iAmMC6T/GAATTCGGATCC GGTTCCAGACAAAATGGGTCTTGCTA
Acry GB HPIV-4 Pr2 /5Acryd/AAT/iAmMC6T/GAATTCGGATCC GGTTCCAGATAATATGGGTCTTGCTA
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Analyte Target Primary Oligo ID Sequence ( 5 '-3')
Amplicon
Length (b p)
hMPV M2 109 Am-hMPV F /5AmMC6/GACAAATCATMATGTCTCGYAARGCTCC
hMPV R CTATCWGGCCAACTCCAGTAATTGTG
Acry AS-hMPV P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCCTTGCCCCGYACTTCATATTTGCA
AdV ( B ,C&E) Hexon 82 AdV F TGCCSCARTGGKCDTACATGCACATC
AdV R /5AmMC6/GCRCGGGCRAACTGCACCAG
Acry AdV B/E P /5Acryd/AATTGAATTCGGATCC GCTTCGGAGTACCTGAGTCCGGGT
Acry AdV C P /5Acryd/AATTGAATTCGGATCC TCGGGCCAGGACGCCTCGGAGTAC
RhV 5'UTR 209 truncRhi R /5AmMC6/GAAACACGGACACCCAAAGTAGT
T7truncRhi F ACTCACTATAGG AGCCTGCGTGGCKGCC
Acry Rhi P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCCTCCTCCGGCCCCTGAATGYGGCTAA
B. pertussis IS481 105 Bper F CCGGCCGGATGAACACCCATAAGCA
Bper R /5AmMC6/GGGCCGCTTCAGGCACACAAACTTG
Acry Bper P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCCTGCCCGATTGACCTTCCTACGTCGA
C. pneumoniae MOMP 122 Cpn F CATGAATGGCAAGTAGGAGCCTCTC
Cpn R /5AmMC6/AGTTTTGGCTGAGCAATGCGGATGT
Acry Cpn P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCCTGGTCTCGAGCAACTTTTGATGCTG
M. pneumoniae P1 Cytadhesin 114 Mpneu F GAACCGAAGCGGCTTTGACCGCATC
Mpneu R /5AmMC6/GCGTGGGCGTTTGCGGGTTTAACTT
Acry Mpneu P /5ThioMC6-D/AAT/iAmMC6T/GAATTCGGATCCGGGCGCGCCTTATACGACCTCGATT
MS2 RNA Matrix 102 MS2-2 R /5AmMC6/CTTTTGCAGGACTTCGGTCGACGCC
Control
MS2-2 F GCACGCTCCTGCTACAGCCTCTTCC
Acry MS2-2 P /5Acryd/AATTGAATTCGGATCC GAAGTGCCGCAGAACGTTGCGAACC
Human Control MYL3 131 MYL3 F GCACCCAGACAATACACACAGGTGT
MYL3 R /5AmMC6/GGCGGAAGTCAGCATGTGTCTG
PapType ProbeMLC_Int /5Acryd/AAT/iAmMC6T/AAAGGGAGGACAGCTATGGACCAAACACAGACACAGAGAGACCCACAGAC
Oligo A
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BIBLIOGRAPHY
Chadwick et al. (1998 ) J. Virol. Methods 70:59-70
Chan and Fox (1999 ) Rev. Med. Microbiol. 70:185-196
Compton (1991 ) Nature 350:91-92
Demidov and Broude Eds. (2004 ) Horizon Bioscience
Guatelli et al. (1990 ) Proc. Natl Acad. ScI USA 57:1874-1878
Hill (1996 ) J. Clin. Ligand Assay 7P:43-51
Kievits et al. (1991 ) J Virol. Methods 35:273-286
Lyamichev et al. (1999 ) Nat. Biotechnol. 77:292-296
Ryan et al. (1999 ) MoI. Diagn. 4:135 97 -
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Claims (2)
1. A method of screening a sample for a multiplicity of respiratory pathogens to detect a particular pathogen, the method comprising: (a ) isolating nucleic acid from the sample, which nucleic acid comprises nucleic acid from one or more respiratory pathogens; (b ) subjecting the nucleic acid to solid phase amplification with primer pairs comprising forward primers of SEQ ID NOs:1 to 16 or 33 or 35 and corresponding reverse primers of SEQ ID NOs:17 to 32 or 33 or 35, and wherein the oligonucleotide probes are selected from the group consisting of SEQ ID NOs:37 to 52 and 34 or 36 or with primer pairs and corresponding probes selected from 2 or more of the sequences listed in Table 8 (S EQ ID NOs:74 to 126 or SEQ ID NOs:53 or 54) amplification; wherein an aqueous primer pair directs the amplification of a region of nucleic acid from a respiratory pathogen, the number of primer pairs being selected on the basis of the number of pathogens desired to be screened and wherein at least one member of the primer pair comprises a first optically detectable label that is incorporated into a resulting amplicon following amplification; wherein the amplicon is captured by hybridizing to an oligonucleotide probe that is complementary to a region of the amplicon and immobilized to a bead in a beadset, the beadset having subsets of beads, each subset being homogenous with respect to bead size and, optionally, intensity of a second optically detectable label, thereby creating a heterogeneous beadset based on size and/or second detectable label intensity and wherein the number of subsets corresponds to the number of respiratory pathogens to be screened; (c ) determining to which of the beads an amplicon has bound on the basis of the intensity of the first detectable label and, where amplicons are bound to multiple subsets of beads, distinguishing between the multiple subsets of beads on the basis of bead size and, optionally, on the basis of second optically detectable label intensity; wherein binding of an amplicon to a particular subset of beads is indicative of the presence of a particular respiratory pathogen in the sample.
2. The method of Claim 1 wherein the amplicon initiated by extension of the primer comprising the first optically detectable label serves as a template for hybridization and H:\ a ar\ I nterwoven\ N RPortbl\D CC\A AR\7527654_1. DOC-
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| AU2011904105A AU2011904105A0 (en) | 2011-10-04 | An assay | |
| AU2011904105 | 2011-10-04 | ||
| PCT/AU2012/001208 WO2013049891A1 (en) | 2011-10-04 | 2012-10-04 | Compositions and methods of detecting respiratory pathogens using nucleic acid probes and subsets of beads |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| NZ623279A NZ623279A (en) | 2015-08-28 |
| NZ623279B2 true NZ623279B2 (en) | 2015-12-01 |
Family
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