NZ732182B2 - Targeted rna editing - Google Patents
Targeted rna editing Download PDFInfo
- Publication number
- NZ732182B2 NZ732182B2 NZ732182A NZ73218215A NZ732182B2 NZ 732182 B2 NZ732182 B2 NZ 732182B2 NZ 732182 A NZ732182 A NZ 732182A NZ 73218215 A NZ73218215 A NZ 73218215A NZ 732182 B2 NZ732182 B2 NZ 732182B2
- Authority
- NZ
- New Zealand
- Prior art keywords
- sequence
- editing
- oligonucleotide construct
- rna
- oligonucleotide
- Prior art date
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Abstract
RNA editing is achieved using oligonucleotide constructs comprising (i) a targeting portion specific for a target nucleic acid sequence to be edited and (ii) a recruiting portion capable of forming an intramolecular stem-loop structure, and capable of binding and recruiting a nucleic acid editing entity naturally present in the cell. The nucleic acid editing entity, such as ADAR, is redirected to a preselected target site by means of the targeting portion, thereby promoting editing of preselected nucleotide residues in a region of the target RNA which corresponds to the targeting portion. tity naturally present in the cell. The nucleic acid editing entity, such as ADAR, is redirected to a preselected target site by means of the targeting portion, thereby promoting editing of preselected nucleotide residues in a region of the target RNA which corresponds to the targeting portion.
Description
TARGETED RNA EDITING
This application claims the benefit of United Kingdom patent applications 1422511.4,
1512467.0, 1512595.8, and 1521987.6 (filed December 17th 2014, July 16th 2015, July
17th 2015, and December 14th 2015 respectively), the complete contents of each of which
are hereby incorporated herein by reference for all purposes.
TECHNICAL FIELD
The invention is in the field of RNA editing, whereby the nucleotide sequence of a target
RNA sequence is modified e.g. to correct a mutation.
BACKGROUND ART
RNA editing is a natural process through which eukaryotic cells alter the sequence of RNA
molecules, often in a site-specific and precise way, thereby increasing the repertoire of
genome encoded RNAs by several orders of magnitude. RNA editing enzymes have been
described for eukaryotic species throughout the animal and plant kingdoms, and these
processes play an important role in managing cellular homeostasis in metazoans from the
simplest life forms, such as Caenorhabditis elegans, to humans. Examples of RNA editing
are adenosine to inosine and cytidine to uridine conversions through enzymes called
adenosine deaminase and cytidine deaminase, respectively. The most extensively studied
RNA editing system is the adenosine deaminase enzyme. Adenosine deaminase is a
multidomain protein, comprising a recognition domain and a catalytic domain. The
recognition domain recognizes a specific dsRNA sequence and/or conformation, whereas
the catalytic domain converts an adenosine into inosine in a nearby, more or less
predefined, position in the target RNA, by deamination of the nucleobase. Inosine is read as
guanine by the translational machinery of the cell, meaning that, if an edited adenosine is in
a coding region of a mRNA or pre-mRNA, it can recode the protein sequence. A to I
conversion may also occur in 5’ non-coding sequence of a target mRNA, creating new
translational start sites upstream of the original start site, which gives rise to N-terminally
extended proteins. In addition, A to I conversions may take place in splice elements in
introns or exons in pre-mRNAs, thereby altering the pattern of splicing. Exons may be
included or skipped, as a consequence of such RNA editing. The adenosine deaminases
are part of the extensive family of enzymes called adenosine deaminases acting on RNA
(ADAR), including human deaminases hADAR1, hADAR2 and hADAR3.
The use of oligonucleotides to edit a target RNA is known in the art, e.g. see Montiel-
Gonzalez et al. (Proceedings of the National Academy of Sciences 2013 November 5,
2013, vol. 110, no. 45, pp. 18285–18290). The authors described the targeted editing of a
target RNA using a genetically engineered fusion protein, comprising an adenosine
deaminase domain of the hADAR1 protein, fused to the so-called B-box binding domain of
bacteriophage lambda protein N. The natural recognition domain of hADAR1 had been
removed to eliminate the substrate recognition properties of the natural ADAR and replace
it by the B-box recognition domain of lambda N-protein. The B-box is a short stretch of RNA
of 17 nucleotides that is recognized by the N-protein B-box binding domain. The authors
created an antisense oligonucleotide comprising a guide RNA part that is complementary to
the target sequence for editing fused to a B-box portion for sequence specific recognition by
the N-domain-deaminase fusion protein. The authors elegantly showed that the guide RNA
oligonucleotide faithfully directed the adenosine deaminase fusion protein to the target site,
resulting in gRNA-directed site-specific A to I editing of the target RNA.
A disadvantage of the proposed method is the need for a fusion protein consisting of the B-
box binding domain of bacteriophage lambda N-protein, genetically fused to the adenosine
deaminase domain of a truncated natural ADAR protein. This requires the target cells to be
either transduced with the fusion protein, which is a major hurdle, or that the target cells are
transfected with a nucleic acid construct encoding the engineered adenosine deaminase
fusion protein for expression in the target cells. The latter constitutes no minor obstacle
when editing is to be achieved in a multicellular organism, such as in therapy against
human disease.
Vogel et al. (Angewandte Chemie. Int. Ed. 2014, 53, 6267-71) disclose editing of eCFP and
Factor V Leiden coding RNAs using a benzylguanine substituted guideRNA and a
genetically engineered fusion protein, comprising the adenosine deaminase domains of
ADAR1 or 2 genetically fused to a SNAP-tag domain (an engineered O6-alkylguanine-DNA-
alkyl transferase). Although the genetically engineered artificial deaminase fusion protein
could be targeted to a desired editing site in the target RNAs in Hela cells in culture, using
covalently linked guide RNA (through benzylguanine), this system suffers from similar
drawbacks as the genetically engineered ADARs described above, in that it is not clear how
to apply the system without having to genetically modify the ADAR first and subsequently
transfect or transduct the cells harboring the target RNA, to provide the cells with this
genetically engineered protein. Clearly, this system is not readily adaptable for use in
humans, e.g. in a therapeutic setting.
Another editing technique which uses oligonucleotides is known as CRISPR/Cas9 system,
but this editing complex acts on DNA. The latter method suffers from the same drawback as
the engineered ADAR systems described above, as it requires co-delivery to the target cell
of the CRISPR/Cas9 enzyme, or an expression construct encoding the same, together with
the guide oligonucleotide.
Hence, there remains a need for new techniques which can utilise endogenous cellular
pathways to edit endogenous nucleic acids in mammalian cells, even in whole organisms,
without the problems associated with the methods of the prior art.
DISCLOSURE OF THE INVENTION
The present invention does away with the drawbacks of the methods according to the prior
art by providing a targeted approach to RNA editing using oligonucleotide constructs
comprising a targeting portion specific for the target nucleic acid sequence to be edited and
a recruiting portion capable of binding and recruiting a nucleic acid editing entity naturally
present in the cell. The function of the recruiting portion of the oligonucleotide construct is to
selectively bind with sufficient affinity to a RNA editing entity endogenous to and resident in
the cell, redirecting such entity to a preselected target site by means of the targeting portion
of the oligonucleotide construct of the invention, thereby promoting the editing of
preselected nucleotide residues in a region of the target RNA corresponding to the targeting
portion of the oligonucleotide construct.
The targeting portion of the oligonucleotide construct usually comprises an antisense
oligonucleotide sequence that is complementary to the target site in the RNA sequence to
be edited. One preferred embodiment of such a targeted approach for editing target RNA is
an oligonucleotide construct comprising two portions, a targeting portion, comprising an
antisense sequence complementary to the target RNA sequence, and a recruiting portion
comprising a recognition sequence for an RNA editing enzyme.
The recruiting portion may comprise a dsRNA in the form of a hairpin structure, with a stem
and a loop. The hairpin may reside upstream (5’) or downstream (3’) of the targeting portion
(preferably upstream). Alternatively, the recruiting portion of the oligonucleotide construct
may interrupt the targeting portion in such a way that part of the targeting portion lies
upstream of the recruiting portion and part of the targeting portion lies downstream of the
recruiting portion, causing the recruiting portion of the oligonucleotide construct to loop out
after the oligonucleotide construct anneals to the target RNA.
According to another embodiment, the recruiting portion comprises a dsRNA segment that
mimics, i.e. is identical or similar in structure to, an RNA sequence known to be edited by
naturally occurring RNA editing entities. This RNA sequence known to be a natural
substrate for RNA editing comprises a dsRNA segment, preferably comprising a single RNA
segment that folds back upon itself through complementary nucleobase pairing, thereby
forming a hairpin or stem-loop structure. Two examples of known edited RNA sequences
that have been characterised in great detail are in the B-subunit of the 3-aminohydroxy-
-methylisoxazole propionic acid (AMPA) subtype glutamate receptor (GluR-B). This
model system comprises two frequently edited sites wherein DNA encoded AGA is edited to
IGA, resulting in an arginine-to-glycine substitution (R/G site) and a distinct glutamine-to-
arginine substitution (Q/R site). The GluR-B (R/G) site is known to comprise of a stem-loop
structure consisting of 71 nucleotides comprising 3 mismatches, 2 A·C and one G·U wobble
base pairs. Interestingly, the loop consists of a well conserved pentaloop structure GCUAA
structure that conforms to a phylogenetically conserved GCUMA sequence, wherein M is A
or C (Aruscavage P.J. & Bass B.L. RNA. 2000; 6: 257-269). There seems to be some
preference for editing of the two wobble adenosines, with an increasing efficiency when the
base opposite the edited adenosine is selected from cytidine or uridine, cytidine being
preferred.
This structure may conveniently be used as is, or be adapted when used in an
oligonucleotide construct according to the invention, as a recruiting portion, by reducing or
increasing the number of wobble nucleobase pairs in the stem to modify the specificity of
editing and/or redirect editing to preferred site(s) in the target RNA sequence. In addition, or
alternatively, the recognition site of the GluR-B for hADAR1 may be modified by shortening
the stem without abolishing the recognition altogether. Such shortening may be convenient
from a manufacturability or cost of good perspective, and the like.
An example of a recruiting portion derived from the GluR-B domain comprises the
a b a
sequence: 5’-(AUAN ) UAUAACAAUAUgcuaaAUGUUGUUAUA(N UAU) -3’, wherein N
and N are each single nucleotides which may be A, G, C or U, with the proviso that N and
N form a mismatch base pair upon the formation of a stem-loop structure, and n is 1 or 0
(i.e. SEQ ID NOs: 6 & 7). A useful example of such a recruiting portion includes this
sequence where n=1, with further extensions in the 5' and 3' directions e.g. where each
extension is from 1 to 10 nucleotides long (or longer e.g. 1 to 20 nucleotides or more). For
instance, extending 3 further nucleotides in each direction gives (SEQ ID NO: 23)
’-GGAAUAN UAUAACAAUAUgcuaaAUGUUGUUAUAN UAUCCC-3’, as seen within SEQ
ID NOs: 20-22 (in which N =N =G). This further extension may improve correction
efficiency.
Another example of a recruiting portion based on full-length natural GluR-B receptor
substrate is 5'-GUGGAAUAN UAUAACAAUAUgcuaaAUGUUGUUAUAN UAUCCCAC-3'
(SEQ ID NO: 24; extended sequence relative to preceding paragraph underlined), as used
below in the Examples. The full-length GluR-B receptor recruiting portion in combination
with targeting portions for the A1AT-transcript with the G to A mutation in position 9989
associated with A1AT-deficiency is described in Example 4. The full-length GluR-B receptor
recruiting portion in combination with targeting portions for the LRRK2 transcript with the
G2019S mutation, associated with Parkinson’s disease, is described in Example 5.
The recruiting portion may be linked at the 5’ or 3’ end to a targeting portion, optionally via a
linker “L” that comprises one or more nucleotides, an oligopeptide or another chemical
linker, such as polyethylene glycol (PEG).
The targeting portion may comprise a sequence that is complementary to the target RNA
sequence represented by the general formula:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
N N N N N N N N N N N N N N N N N CN N N (SEQ ID NO: 8),
1 20
wherein N to N , depending on the complementary sequence in the target RNA sequence,
preferably forms a mismatch base pair
each independently are A, G, C or U, wherein N
with its opposing nucleotide in the target RNA sequence when the targeting portion is
16
annealed to its target RNA sequence, and N and N form wobble base pairs with their
opposing nucleotide in the target RNA sequence when the targeting portion is annealed to
its target RNA sequence, and C is cytidine opposite the adenosine in the target RNA
sequence that is a target for deamination.
Mismatch basepairs are G-A, C-A, U-C, A-A, G-G, C-C, U-U basepairs. Wobble base pairs
are: G-U, I-U, I-A, and I-C basepairs. The targeting portion may be longer than 20
nucleotides, as much as 200 nucleotides or more, although it is believed that longer than 50
is not necessary, and shorter than 40 is preferred. Still more preferred are recruiting
portions shorter than 30 nucleotides, preferably shorter than 25 nucleotides.
Preferably, the targeting portion comprises 2’-O methyl groups in each position which
opposes an adenosine when the targeting portion is annealed to the target RNA sequence
if that adenosine in the target RNA sequence is not a target for editing. More generally, to
protect the targeting portion from degradation by nucleases it is preferred that all
nucleotides comprise 2'-O-methyl groups, except for the nucleotide opposite the target
adenosine and said opposite nucleotide’s neighbouring nucleotides (one 5' and one 3'),
which should comprise 2'-OH groups.
According to a preferred embodiment, the recruiting portion comprises a DNA sequence:
1 n 1 n
(CG) N -N (CG) wherein each of N to N may be the same or different and selected from
3 3,
guanosine, adenosine, thymidine, cytidine and inosine, ‘n’ is between 2 and 20, preferably
between 2 and 10, more preferably between 2 and 5, still more preferably between 3 and 5,
most preferably 4 or 5. Thus there are three CG repeats flanking up to 20 intermediate
nucleotides. This DNA sequence is capable of forming a stem-loop structure. According to a
further preferred embodiment, the recruiting portion of the oligonucleotide construct is a
DNA structure comprising the sequence: (CG) T (CG) , wherein n is an integer from 3 – 5,
3 n 3
preferably 4, (CGCGCGTTTTCGCGCG; SEQ ID NO: 5). This DNA sequence is capable of
forming a stem-loop structure. Moreover, it has been described in the art that the
(CG) T (CG) sequence forms a Z-DNA conformation under physiological conditions and
3 4 3
that this Z-DNA structure is recognised and bound by hADAR1 (FEBS letters 458:1 1999
Sep 10 pg 27-31). As above for the dsRNA recruiting portion, this Z-DNA recruiting portion
may lie upstream or downstream of the targeting portion, or interrupt the targeting portion
separating the targeting portion in an upstream segment and a downstream segment,
whereby the DNA recruiting portion loops out when the targeting portions anneal to the
target RNA. According to this embodiment, the cytidine bases are preferably
-methylcytidine, to reduce potential immunogenicity associated with CpG sequences.
The oligonucleotides according to the present invention comprise a targeting portion (i.e. a
portion that targets the oligonucleotide to the correct position in the target RNA sequence)
and a recruiting portion (i.e. a portion that has as primary function to recruit the editing
entity, e.g. an ADAR, and is not necessarily complementary, preferably not complementary,
with the target RNA in the region of the adenosine(s) that are the target(s) for editing). This
bipartite structure clearly distinguishes oligonucleotides of the invention from known
oligonucleotides such as those disclosed in the prior art (e.g. WO2014/011053,
WO2005/094370, and Woolf et al, 1995. PNAS USA 92, 8298-8302) which are essentially
complementary to the target over their entire length, and do not comprise a recruitment
portion (certainly not one that is not complementary to the target RNA, but instead has
affinity for the editing entity, as with the present invention). It is therefore preferred
according to the invention to provide an oligonucleotide construct for the site-directed
editing of a nucleotide in a target RNA sequence in a eukaryotic cell, said oligonucleotide
construct comprising:
(a) a targeting portion, comprising an antisense sequence complementary to part of
the target RNA; and
(b) a recruiting portion that is not complementary to the target RNA sequence and is
capable of binding and recruiting an RNA editing entity naturally present in said
cell and capable of performing the editing of said nucleotide.
More preferably, the present invention provides an an oligonucleotide construct for the site-
directed editing of a nucleotide in a target RNA sequence in a eukaryotic cell, said
oligonucleotide construct comprising:
(a) a targeting portion, comprising an antisense sequence complementary to part
of the target RNA; and
(b) a recruiting portion capable of forming an intramolecular stem-loop structure,
capable of binding and recruiting an RNA editing entity naturally present in said cell, and
capable of performing the editing of said nucleotide.
In accordance with a further embodiment, the invention provides an oligonucleotide
construct comprising:
(a) a targeting portion, comprising an antisense sequence complementary to part of the
target RNA; and
(b) a recruiting portion that is capable of forming an intramolecular stem loop structure,
of binding and recruiting an RNA editing entity naturally present in said cell , and of
performing the editing of said nucleotide.
According to yet another embodiment, the recruiting portion may be an aptamer selected for
binding to the editing entity resident in the cell. Procedures to select aptamers are well
known in the art. Aptamers that bind to the editing entity without abolishing the deaminase
activity can be selected as recruiting portion and readily fused to the targeting portion of the
oligonucleotide construct according to the invention, using any type of linker including
regular (phosphodiester) or modified (e.g. phosphorothioate or phosphorodithioate)
internucleosidic linkage, peptidyl linkage, or any other chemical linkage, such as
polyethylene glycol.
According to yet another embodiment of the invention, an antibody, antibody fragment,
binding domain thereof, or a camelid antibody, that binds to an editing entity resident in the
cell without abolishing the editing activity, may be selected as a recruiting portion and fused
to the targeting portion of the oligonucleotide construct according to the invention.
The term “oligonucleotide construct” may refer to a single oligonucleotide, a complex of two
or more oligonucleotides (including an aptamer) with affinity to each other (antisense
complementarity or otherwise), or a complex of an oligonucleotide and a proteinaceous
binding portion (such as an antibody, antibody fragment or binding domain), which may be
linked directly or via a PEG or other linker.
Thus, the present invention provides oligonucleotide constructs and methods for site
specific editing of target RNA sequences in a cell, without the need to transduce or transfect
the cell with genetically engineered editing enzymes. Due to the design of the
oligonucleotide constructs the editing entities, such as ADARs, are recruited and directed to
editing sites chosen by the experimenter. These oligonucleotide constructs and methods of
the invention can conveniently be used to make changes in target RNA sequences, for
example to reverse mutations that are involved in, or cause, disease, thereby alleviating the
symptoms of the disease. The RNA editing entities are known to edit their substrates very
efficiently, with frequencies far exceeding oligonucleotide mediated DNA or RNA repair.
This is of great advantage when used in treating disease.
The targeting portion and the recruiting portion in an oligonucleotide construct according to
the invention may be directly adjacent. Alternatively, the targeting portion and the recruiting
portion may be linked covalently through a linker. The linker may comprise non-specific
nucleotide residues (non-specific in the sense that they are not necessarily complementary
to the target RNA sequence nor have affinity to an editing entity resident in the cell),
(oligo)peptide linkers, or other chemical linkers. According to yet another embodiment, the
targeting portion and the recruiting portion may be provided as two separate – i.e. non-
covalently linked – oligonucleotide sequences comprising antisense complementarity
capable of forming a dsRNA or a hybrid DNA:RNA structure. The formation of such dsRNA
or hybrid oligonucleotide construct may take place prior to administration to the cell or the
subject to be treated, or after administration of the two separate oligonucleotides, in vitro, or
in vivo, e.g. in the subject to be treated.
The invention provides a method for making a change in a target RNA sequence in a
eukaryotic, preferably a mammalian cell, comprising steps of: (i) introducing into said cell an
oligonucleotide construct comprising a targeting portion, which comprises a sequence that
is sufficiently complementary to the target RNA sequence to bind by nucleobase pairing to
said target RNA and a recruiting portion, that comprises a sequence that is recognised by
an RNA editing entity that is naturally present in said eukaryotic, preferable mammalian,
cell; (ii) allowing sufficient time for the RNA editing entity to perform an editing reaction on
the target RNA sequence; and (iii) identifying the presence of the change in the RNA
sequence. According to a preferred embodiment, the editing reaction is carried out by said
editing entity on one or more nucleobases within the region of overlap between the target
RNA sequence and the targeting portion of the oligonucleotide construct. According to a
preferred embodiment, the targeting portion of the oligonucleotide construct comprises a
mismatch opposite the nucleobase(s) to be edited. According to a further preferred
embodiment the editing reaction comprises an A to I conversion by deamination of the
adenosine nucleobase in the target RNA sequence. Preferred in accordance with the latter
method is one wherein the oligonucleotide construct comprises a C opposite the adenosine
to be edited. According to another preferred method, the editing reaction is a C to U
conversion through deamination of the cytidine nucleobase; it is preferred in accordance
with the latter method that the targeting portion of the oligonucleotide construct comprises
an A opposite the C in the target RNA sequence to be edited.
The invention also provides a method for editing a mutant CFTR target RNA sequence in a
human cell, comprising steps of: (i) introducing into said cell an oligonucleotide construct
comprising a targeting portion that is complementary to the CFTR target RNA sequence
and a recruiting portion capable of recruiting a hADAR editing entity; and (ii) allowing
sufficient time for the hADAR editing entity to edit nucleobases at or near a region of
overlap between the target RNA sequence and the targeting portion of the oligonucleotide
construct. In a preferred embodiment according to the invention the mutant CFTR target
RNA (a pre-mRNA or mRNA) comprises a G551D mutation, and the editing reaction causes
an adenosine to be converted into an inosine thereby reversing the G551D mutation in said
target RNA sequence. There are two codons for aspartic acid (D); GAU and GAC. Hence, a
cystic fibrosis patient with the G551D mutation may have either mutation GAU or GAC in
the position corresponding to codon 551 of the CFTR protein. Deamination of the A in the
second position of the codon will lead to formation of an I, which will be read by the
translational machinery as a G. Hence, deamination of the A in the second position of the
mutated codon creates GIU or GIC, respectively, which are de facto read as GGU and
GGC. Both GGU and GGC encode glycine, so that, RNA editing of both mutated G551D
codons by an adenosine deaminase will yield a proper glycine encoding triplet, effectively
reversing the mutation to a normal CFTR protein.
It will be clear to a person skilled in the art, that the G551D mutation is used as an example
only and in no way to limit the scope of the invention. There are literally thousands of
genetic diseases caused by single base pair substitutions that are amenable for reversal
using oligonucleotide constructs and methods according to the invention, recruiting either a
deaminase, such as the adenosine deaminases described in detail herein, or a cytidine
deaminase.
The recruitment of cytidine deaminase to a target site works in the same way as for the
adenosine deaminases hADAR1 and hADAR2. However, cytidine deaminases have
different binding requirements and recognize different structures in their target RNA
sequences that determine editing of the cytidine. One particularly well studied cytidine
aminase is human Apobec1. The general principle of RNA editing using an oligonucleotide
construct to target an editing site and to recruit a resident, naturally present, editing entity
remains the same for cytidine deaminases, and is part of the invention disclosed and
claimed herein.
DETAILED DESCRIPTION OF THE INVENTION
The oligonucleotide constructs according to the invention are unique in that they combine
two essential functions; they bind to naturally present RNA editing entities with a certain
affinity and they bind through antisense complementary (Watson-Crick) base pairing to the
site in the target RNA sequence where editing is to take place, thereby recruiting the RNA
editing entities to the editing site. A “naturally present” entity is present in a cell without the
need of prior human intervention. Hence, a truncated or recombinant enzyme (such as
described in Montiel-Gonzalez et al., and Vogel et al.) is not naturally present in a cell; they
may be present in a cell, but only after human intervention (transduction or transfection).
The invention can thus operate using wild-type RNA editing entities which are endogenous
to a cell.
It will be understood that such recruiting need not be quantitative, in that all RNA editing
entities resident in the cell will be recruited for editing of the target RNA sequence of choice.
It is expected, and even considered desirable, if a percentage of resident editing entities
remain available to act on their natural substrates. In addition, in certain embodiments,
e.g. where the recruiting portion of the oligonucleotide construct is a dsRNA sequence
comprising adenosines, the catalytic domain of the RNA editing entity, once recruited by the
oligonucleotide construct, may act on the recruiting portion of the oligonucleotide construct,
as well as on the editing substrate in the dsRNA portion created by the annealing of the
targeting portion to the complementary sequence in the target RNA sequence. This is not a
problem under all circumstances, as there may be applications where over-editing is
desirable. In cases where over-editing is to be avoided, a targeting portion may be
chemically modified in its entirety, for example by providing all nucleotides with a 2’-O-
methylated sugar moiety, except in the nucleotide(s) opposite the target adenosine(s) and
the two nucleotides (one 5' and one 3') flanking each nucleotide opposing the target
adenosine. In general, an adenosine in a target RNA can be protected from editing by
providing an opposing nucleotide with a 2'-OMe group, or by providing a guanine or adenine
as opposing base, as these two nucleobases are able to prevent editing of the opposing
adenosine.
The oligonucleotide constructs
The recruiting portion of the oligonucleotide constructs according to the invention are
characterized by a dsRNA or dsDNA structure. One way of establishing a double stranded
oligonucleotide structure in a single molecule is by establishing a palindromic sequence that
is capable of folding back upon itself over at least part of its length. Such stem-loop
structures may arise from (1) artificial RNA sequences capable of forming a stem-loop
structure, (2) artificial DNA sequences capable of forming a stem-loop structure, (3) RNA
sequences taken from known substrate RNAs for editing entities resident in the cell. For
example, an oligonucleotide construct according to the invention may comprise a recruiting
portion similar in sequence to the natural recognition site for the editing activity, or it may
mimic that recognition site in an aptamer-like fashion. Each of these embodiments will be
described in more detail below. In addition, those of skill in the art will be capable of making
designing and recruiting portions based on each of the embodiments described in greater
detail. Methods to design and test nucleic acid structures that have affinity for proteins are,
as such, well known in the art.
The targeting portion of an oligonucleotide construct according to the invention should have
sufficient overlap and complementarity to the target site to allow for sequence specific
hybridisation of the oligonucleotide construct with the target RNA sequence. The length and
the amount of overlap may vary from target to target but may be routinely determined by a
person having ordinary skill in the art. In general, longer sequences provide more specificity
– and consequently fewer off-target effects, e.g. through non-specific binding – and stronger
binding to the target site. The targeting portion of the oligonucleotide construct according to
the invention should normally be longer than 10 nucleotides, preferably more than 11, 12,
13, 14, 15, 16 still more preferably more than 17 nucleotides. The targeting portion is
preferably shorter than 200 nucleotides, more preferably shorter than 100 nucleotides, still
more preferably shorter than 50 nucleotides, still more preferable 25 or fewer nucleotides.
According to one embodiment, the invention provides an oligonucleotide construct for
making a desired change at one or more specific positions in a target RNA sequence in a
cell, by recruiting a RNA editing entity naturally present in said cell, having the sequence 5’-
X-(Y-X') -L-Z-3’, wherein X is complementary to the target RNA sequence downstream of
the specific position, X' is complementary to the target RNA sequence upstream of the
specific position, Y comprises one or more nucleotides (e.g. up to 10, preferably between 1
and 5, more preferably between 1 and 3, such as 1 or 2) which is/are not complementary to
the target RNA sequence, n is an integer from 1 to 10 (preferably from 1 to 5, more
preferably from 1 to 3, or 1), L is a linker sequence that is optional and may comprise any
number of nucleotides including zero, and Z is a sequence that is recognised by and binds
to said RNA editing entity. L may also consist of a different chemical linkage, such as a
(oligo)peptide linkage, or PEG linkage.
When n is greater than or equal to 1 the targeting portion of the oligonucleotide construct is
not perfectly complementary to the target RNA sequence, but instead comprises one or
more mismatches, or wobble bases, which serve to enhance the specificity, by increasing
the frequency of editing of the opposing nucleotide in the target RNA sequence. When n is
two or more, X' occurs more than once and two or more X' may be identical depending on
the sequence of the complementary bases in the target RNA sequence, but in all likelihood,
the two or more X' are not identical. When n is 0, the targeting portion is perfectly
complementary to the target RNA sequence over the entire length of the targeting portion,
i.e. without any mismatches, to the target RNA sequence. This embodiment is likely to
cause RNA editing by adenosine deaminase in a non-specific way, meaning all adenosines
in the overlapping region between target portion of the oligonucleotide construct and the
target RNA sequence are equally likely to become converted to inosine. Any non-specific
editing of adenosines can be limited, by making sure that the adenosines that should not be
targeted, or at least at a lower frequency, encounter an opposite nucleotide with a 2’-O
modified ribose moiety, such as a 2'-OMe, as the latter is known to reduce the efficiency of
editing of the opposite adenosine. Alternatively, or additionally, an opposing base being a
guanine or adenine may be provided, as these nucleobases generally impede deamination
of the opposing base.
According to another embodiment, the invention provides an oligonucleotide construct for
making a desired change at a specific position in a target RNA sequence in a cell, by
recruiting a RNA editing entity naturally present in said cell, having the sequence 5’-Z-L-(X'-
Y) -X-3’, wherein X is complementary to the target RNA sequence upstream of the specific
position, X' is complementary to the target RNA sequence downstream of the specific
position, Y comprises one or more nucleotides which is/are not complementary to the target
RNA sequence (e.g. up to 10, preferably from 1 to 5, more preferably from 1 to 3, such as 1
or 2), n is an integer from 1 to 10 (preferably from 1 to 5, more preferably from 1 to 3, or 1),
L is a linker sequence that is optional and may comprise any number of nucleotides
including zero, and Z is a sequence that is recognised by and binds to said RNA editing
entity. L may also consist of a different chemical linkage, such as a (oligo)peptide linkage.
When n is greater than or equal to 1 the targeting portion of the oligonucleotide construct is
not perfectly complementary to the target RNA sequence, but instead comprises one or
more mismatches, or wobble bases, which serve to enhance the specificity, by increasing
the frequency of editing of the opposing nucleotide in the target RNA sequence. When n is
two or more, X' occurs more than once and two or more X’ may be identical depending on
the sequence of the complementary bases in the target RNA sequence, but in all likelihood,
the two or more X' are not identical. When n is 0, the targeting portion is perfectly
complementary to the target RNA sequence over the entire length of the targeting portion,
i.e. without any mismatches, to the target RNA sequence. This embodiment is likely to
cause RNA editing by adenosine deaminase in a non-specific way, meaning all adenosines
in the overlapping region between target portion of the oligonucleotide construct and the
target RNA sequence are equally likely to become converted to inosine. Any non-specific
editing of adenosines can be limited, by making sure that the adenosines that should not be
targeted, or at least at a lower frequency, encounter an opposite nucleotide with a 2’-O
modified ribose moiety, such as a 2’-OMe, as the latter is known to reduce the efficiency of
editing of the opposite adenosine.
An oligonucleotide of the invention can be a hybrid DNA/RNA molecule i.e. including both
deoxyribo- and ribo-nucleotides within the same oligocnucleotide.
Recruiting portion: preferred embodiments
The recruiting portion should be long enough to provide a structure, such as a stem-loop
RNA or DNA structure, preferably in the Z-RNA or Z-DNA conformation, that is recognized
by the editing entity according to the invention. If the editing entity is hADAR1, nucleic acid
sequences are known that provide for recognition and binding by the Z-alpha domain of the
150kDa variant of hADAR1.
Recruiting portions from artificial RNA or DNA stem-loop structures
An example of an artificial RNA or DNA stem-loop structure, being a preferred recruiting
portion according to the invention, comprises the sequence (RY or YR) N (RY or YR) ,
n m n
wherein R, Y and N represent either ribonucleotides or desoxyribonucleotides and wherein
R is A or G, Y is T, U or C, N is A, G, C, T or U, n is 3 or more, m is 1 or more (preferably m
is 2 or more, more preferably m is 3 or more, still more preferably m is 4 or more) and
wherein N forms a loop and the two (RY) or (YR) sequences either form a dsRNA stem
structure (when all nucleotides are ribonucleotides) or dsDNA structure (when all
nucleotides are desoxyribonucleotides) via complementary Watson-Crick nucleobase
pairing. The recruiting portion preferably consists of all ribonucleotides or all
desoxyribonucleotides, although a recruiting portion comprising both ribo- and
desoxyribonucleotides is not excluded.
Especially preferred examples of recruiting portions known to bind to hADAR1 are (i) the
T (CG) wherein n is 3 and m is 4 or more, preferably
DNA structures represented by (CG)
n m n
4 or 5, which has a tendency to form so-called Z-DNA structures, (ii) RNA structures
represented by the formula (RY) N (RY) , wherein R is A or G, Y is C or U, N is any A, G,
n m n
C, or U and wherein N may all be the same or different, n is 3 or more, m is 4 or more,
preferably 4 or 5, which has a tendency to form Z-RNA structures. Z-DNA and Z-RNA
structures differ from their more common counterparts (for dsDNA the B conformation is the
most common form, whereas for dsRNA the A-form is most common) by the fact that the
double helix is left-handed as opposed to A and B forms, which are both right-handed, and
the nucleobases in the backbone of Z-DNA and Z-RNA are spatially arranged in a zigzag
arrangement (hence the prefix “Z”).
Recruiting portions from natural substrate RNAs
Non Z-RNA forming dsRNA sequences forming stem-loop structures and bulges also come
into play as recruiting portions. Various dsRNA structures, with stem-loops and mismatches
or wobble base pairs, other than the GluR-B described in some detail above, have been
described in the art that interact with the binding domain of editing entities, such as GluR-C
and GluR-D, 5-HT serotonine receptors and several pri- and pre-miRNAs and miRNAs.
Preferred loops in the recruiting portions of the oligonucleotide constructs according to the
invention conform to the tetra- or pentaloop conserved sequences UNCG, wherein N may
be any A, G, C or U, or GCUMA, wherein M is A or C, respectively. When the recruiting
portion comprises a stem loop segment from a known RNA editing site in the art, the stem
may be taken “as is” or may altered in sequence or length, shortened, or modified in some
other way, to alter its characteristics, such as affinity for the RNA editing entity, or for
reasons of manufacturability or handling, cost, or any other reason, as long as the recruiting
function is not entirely impaired. These structures can readily be made in vitro and tested
for their ability to bind to, recruit, and redirect editing entities. Several editing entities are
known in the art that can be obtained commercially, including hADARs, and tested in
assays for binding to dsRNA or dsDNA structures in oligonucleotide constructs according to
the invention. Such assays are readily available to those having ordinary skill in the art of
protein-nucleic acid interactions, and include an electrophoretic mobility shift assay (EMSA).
Two examples of known edited RNA sequences that have been characterised in great
detail are in the B-subunit of the 3-aminohydroxymethylisoxazole propionic acid
(AMPA) subtype glutamate receptor (GluR-B). This model system comprises two frequently
edited sites wherein DNA encoded AGA is edited to IGA, resulting in an arginine-to-glycine
substitution (R/G site) and a distinct glutamine-to-arginine substitution (Q/R site). The GluR-
B (R/G) site is known to comprise of a stem-loop structure consisting of 71 nucleotides
comprising 3 mismatches, 2 A·C and one G·U wobble base pairs. Interestingly, the loop
consists of a well conserved pentaloop structure GCUAA structure that conforms to a
phylogenetically conserved GCUMA sequence, wherein M is A or C (Aruscavage P.J. &
Bass B.L. RNA. 2000; 6: 257-269). There seems to be some preference for editing of the
two wobble adenosines, with an increasing efficiency when the base opposite the edited
adenosine is selected from cytidine or uridine, cytidine being preferred.
This structure may conveniently be used as is, or be adapted when used in an
oligonucleotide construct according to the invention, as a recruiting portion, by reducing or
increasing the number of wobble nucleobase pairs in the stem to modify the specificity of
editing and/or redirect editing to preferred site(s) in the target RNA sequence. In addition, or
alternatively, the recognition site of the GluR-B for hADAR1 may be modified by shortening
the stem without abolishing the recognition altogether. Such shortening may be convenient
from a manufacturability or cost of good perspective, and the like.
An example of a recruiting portion derived from the GluR-B domain, being a preferred
embodiment according to the invention, comprises the sequence:
a b a b
'-(AUAN ) UAUAACAAUAUgcuaaAUGUUGUUAUA(N UAU) -3', wherein N and N are
each single nucleotides which may be A, G, C or U, with the proviso that N and N form a
mismatch base pair upon the formation of a stem-loop structure, and n is 1 or 0 (i.e. SEQ ID
NOs: 6 & 7).
Another preferred recruiting portion comprises or consists of the sequence
c a b d
'-GUGGN AUAN UAUAACAAUAUgcuaaAUGUUGUUAUAN UAUN CCAC-3' (SEQ ID
a b c d a
NO: 25), where: N , N , N , and N each may be a nucleotide A, G, C or U, provided that N
b c d
& N form a mismatch basepair and N & N form a mismatch basepair upon stem loop
formation; and whereby the gcuaa pentanucleotide forms a loop and the upstream and
downstream sequences adjacent to gcuaa form a stem by base-pairing.
The recruiting portion may be linked at the 5' or 3' end to a targeting portion, optionally via a
linker “L”, that comprises one or more nucleotides, an oligopeptide or another chemical
linker, such as polyethylene glycol (PEG).
Chemical modification of the oligonucleotides constructs
Various chemistries and modification are known in the field of oligonucleotides that can be
readily used in accordance with the invention. The regular internucleosidic linkages
between the nucleotides may be altered by mono- or di-thioation of the phosphodiester
bonds to yield phosphorothioate esters or phosphorodithioate esters, respectively. Other
modifications of the internucleosidic linkages are possible, including amidation and peptide
linkers. The ribose sugar may be modified by substitution of the 2'-O moiety with a lower
alkyl (C1-4, such as 2’-O-Me), alkenyl (C2-4), alkynyl (C2-4), methoxyethyl (2’-MOE), or
other substituent. Preferred substituents of the 2’ OH group are a methyl, methoxyethyl or
3,3’-dimethylallyl group. The latter is known for its property to inhibit nuclease sensitivity
due to its bulkiness, while improving efficiency of hybridization (Angus & Sproat FEBS 1993
Vol. 325, no. 1, 2, 123-7). Alternatively, locked nucleic acid sequences (LNAs), comprising
a 2'-4' intramolecular bridge (usually a methylene bridge between the 2' oxygen and 4'
carbon) linkage inside the ribose ring, may be applied. Purine nucleobases and/or
pyrimidine nucleobases may be modified to alter their properties, for example by amination
or deamination of the heterocyclic rings. The exact chemistries and formats may depend
from oligonucleotide construct to oligonucleotide construct and from application to
application, and may be worked out in accordance with the wishes and preferences of those
of skill in the art.
Length
The oligonucleotide constructs according to the invention may comprise between 20 and
several hundred nucleotides. For practical reasons such as manufacturability and cost, the
oligonucleotide constructs should preferably be shorter than 200 nucleotides. Preferably,
the oligonucleotide constructs are between 20 and 100 nucleotides long, more preferably
between 24 and 60 nucleotides, still more preferably between 30 and 50 nucleotides. The
targeting portion of the oligonucleotide construct preferably comprises more than 10
nucleotides, preferably more than 11, 12, 13, 14, 15, 16 still more preferably more than 17
nucleotides. Longer targeting portions provide more specificity for the target site of the RNA
sequence to be edited, less off-target effects due to unintentional (off-target) binding as well
as more room to create secondary structures, such as stem-loop structures within the
targeting portion itself, mismatches or wobble-bases (due to mismatches with one or more
of the complementary base(s) in the targeted RNA sequence at or near the site to be
edited), and so forth. Preferred targeting portions are complementary to the target RNA
sequence over the entire length of the targeting portion except for the mismatch opposite
the nucleotide to be edited, and optionally one or two wobble bases.
Conformation
It is known in the art, that RNA editing entities, such as hADARs, edit dsRNA structures with
varying specificity, depending on a number of factors. One important factor is the degree of
complementarity of the two strands making up the dsRNA sequence. Perfect
complementarity of the two strands usually causes the catalytic domain of hADAR to
deaminate adenosines in a non-discriminative manner, reacting more or less with any
adenosine it encounters. The specificity of hADAR1 can be increased to only convert
particular adenosines by ensuring a mismatch in the dsRNA, by providing a targeting
portion that comprises a mismatch opposite the adenosine to be edited. The mismatch is
preferably created by providing a targeting portion having a cytidine or uridine, most
preferably a cytidine, opposite the adenosine to be edited. Upon deamination of the
adenosine in the target strand, the target strand will obtain an inosine which, for most
biochemical processes, is “read” by the cell’s biochemical machinery as a G. Hence, after A
to I conversion, the mismatch has been resolved, because I is perfectly capable of base
pairing with the opposite C in the targeting portion of the oligonucleotide construct
according to the invention. After the mismatch has been resolved due to editing, the
substrate is released and the oligonucleotide construct-editing entity complex is released
from the target RNA sequence, which then becomes available for downstream biochemical
processes, such as splicing and translation.
The desired level of specificity of editing the target RNA sequence may depend from
application to application. Following the instructions in the present patent application, those
of skill in the art will be capable of designing the targeting portion of the oligonucleotide
construct according to their needs, and, with some trial and error, obtain the desired result.
The targeting portion of the oligonucleotide constructs of the invention will usually comprise
the normal nucleotides A, G, U and C, but may also include inosine (I), for example instead
of one or more G nucleotides. In a recruiting portion of an oligonucleotide construct
according to the invention G may also be replaced by an I, although care must be taken that
an I in the stem or the loop does not interfere with the formation of Z-DNA or Z-RNA
conformations in those embodiments where this is desirable.
Editing specificity
To prevent undesired editing of adenosines in the target RNA sequence in the region of
overlap with the oligonucleotide construct, the targeting portion of the oligonucleotide
construct may be chemically modified. It has been shown in the art, that 2'-O-methylation of
the ribosyl-moiety of a nucleoside opposite an adenosine in the target RNA sequence
dramatically reduces deamination of that adenosine by ADAR (Vogel et al. 2014
Angewandte Chemie Int. Ed. 53, 6267-71). Hence, by including 2'-methoxy (2’-OMe)
nucleotides in desired position of the oligonucleotide construct, the specificity of editing may
be dramatically improved. It is envisaged that other 2’-O substitutions of the ribosyl moiety,
such as 2’-methoxyethyl (2’-MOE) and 2’-O-dimethylallyl groups may also reduce unwanted
editing of the corresponding (opposite) adenosine in the target RNA sequence. Other
chemical modifications are readily available to the person having ordinary skill in the art of
oligonucleotide synthesis and design. The synthesis of such chemically modified
oligonucleotide constructs and testing them in methods according to the invention does not
pose an undue burden and other modifications are encompassed by the present invention.
Editing entities
Editing entities will usually be proteinaceous in nature, such as the ADAR enzymes found in
metazoans, including mammals. Editing entities may also comprise complexes of nucleic
acid(s) and proteins or peptides, such as ribonucleoproteins. Editing enzymes may
comprise or consist of nucleic acid(s) only, such as ribozymes. All such editing entities are
encompassed by the present invention, as long as they are recruited by the oligonucleotide
constructs according to the invention. Preferably, the editing entity is an enzyme, more
preferably an adenosine deaminase or a cytidine deaminase, still more preferably an
adenosine deaminase. When the editing entity is an adenosine deaminase, Y is preferably
a cytidine or a uridine, most preferably a cytidine. The ones of most interest are the human
ADARs, hADAR1 and hADAR2, including any isoforms thereof such as hADAR1 p110 and
p150.
RNA editing enzymes known in the art, for which oligonucleotide constructs according to
the invention may conveniently be designed, include the adenosine deaminases acting on
RNA (ADARs), such as hADAR1 and hADAR2 in humans or human cells and cytidine
deaminases. Human ADAR3 (hADAR3) has been described in the prior art, but reportedly
has no deaminase activity.
It is known that hADAR1 exists in two isoforms; a long 150 kDa interferon inducible version
and a shorter, 100 kDa version, that is produced through alternative splicing from a
common pre-mRNA. Interestingly, only the longer isoform is capable of binding to the
Z-DNA structure that can be comprised in the recruiting portion of the oligonucleotide
construct according to the invention. Consequently, the level of the 150 kDa isoform present
in the cell may be influenced by interferon, particularly interferon-gamma (IFN-gamma).
hADAR1 is also inducible by TNF-alpha. This provides an opportunity to develop
combination therapy, whereby interferon-gamma or TNF-alpha and oligonucleotide
constructs comprising Z-DNA as recruiting portion according to the invention are
administered to a patient either as a combination product, or as separate products, either
simultaneously or subsequently, in any order. Certain disease conditions may already
coincide with increased IFN-gamma or TNF-alpha levels in certain tissues of a patient,
creating further opportunities to make editing more specific for diseased tissues.
Both the targeting portion and the recruiting portion may comprise or consist of nucleotides
having chemical modifications that alter nuclease resistance, alter affinity of binding
(expressed as melting temperature) or other properties. Examples of chemical modifications
are modifications of the sugar moiety, including by cross-linking substituents within the
sugar (ribose) moiety (e.g. as in LNA or locked nucleic acids), by substitution of the 2’-O
atom with alkyl (e.g. 2’-O-methyl), alkynyl (2’-O-alkynyl), alkenyl (2’-O-alkenyl), alkoxyalkyl
(e.g. methoxyethyl, 2’-MOE) groups, having a length as specified above, and the like. In
addition, the phosphodiester group of the backbone may be modified by thioation,
dithioation, amidation and the like to yield phosphorothioate, phosphorodithioate,
phosphoramidate, etc., internucleosidic linkages. The internucleotidic linkages may be
replaced in full or in part by peptidic linkages to yield in peptidonucleic acid sequences and
the like. Alternatively, or in addition, the nucleobases may be modified by (de)amination, to
yield inosine or 2’6’-diaminopurines and the like.
A further modification may be methylation of the C5 in the cytidine moiety of the nucleotide,
to reduce potential immunogenic properties known to be associated with CpG sequences.
The architecture of the oligonucleotide constructs according to the invention may vary from
“one legged” hairpins (Fig. 1 and 2), to “two legged” hairpins (Fig. 3), whereby the legs
comprise the targeting portion or portions, and the body or core of the hairpin provides the
recruiting portion (Figs. 1 – 3). The leg or legs of the oligonucleotide construct will provide
mismatching or wobbling nucleobases representing the opposite site of the editing site,
e.g. an adenosine or cytidine to be edited, in the target RNA. For example, in case the
oligonucleotide construct recruits ADAR activity, to edit an A to I conversion in the target
RNA, the mismatch or wobble may comprise an adenosine, a guanine, an uridine or a
cytidine residue, preferably a cytidine residue. Except for the mismatch or wobble opposite
the editing site, the targeting portion will usually be perfectly complementary to the target
RNA, although a limited number of imperfect matches, such as wobble or mismatching
bases, may be allowable without unacceptably impairing the specificity and/or the strength
of binding between the oligonucleotide construct and the target RNA sequence. The stem of
the hairpin may consist of a perfectly complementary stretch of nucleotides, forming a
double strand RNA structure over the entirety of its length. Alternatively, the stem of the
hairpin may comprise one or more wobbling or non-matching opposing nucleotides, as long
as the recognition of the oligonucleotide construct by the editing activity is not unacceptably
impaired. It should be understood that the functioning of the editing activity in the cell at its
natural editing sites may be reduced as a consequence of the recruitment of the entities
responsible for the editing activity by the oligonucleotide constructs according to the
invention. It will be understood by a person having ordinary skill in the art that the extent to
which the editing entities inside the cell are redirected to other target sites may be regulated
by varying the affinity of the recruiting portion of the oligonucleotide constructs according to
the invention for the recognition domain of the editing entity. This may be done by reducing
the affinity of the recruiting portion of the oligonucleotide construct for the editing entity
through any one or combination of ways, including by changing the sequence of the stem,
the size or structure (sequence, chemistry of the backbone, ribosyl, or nucleobase) of the
loop or a combination of both. The exact modification may be determined through some trial
and error and/or through computational methods based on structural interactions between
the recruiting portion of the oligonucleotide construct and the recognition domain of the
editing entity.
In addition, or alternatively, the degree of recruiting and redirecting the editing entity
resident in the cell may be regulated by the dosing and the dosing regimen of the
oligonucleotide construct. This is something to be determined by the experimenter (in vitro)
or the clinician, usually in phase I and/or II clinical trials.
Preferably, the invention provides for the use of an oligonucleotide construct that consists of
a single oligonucleotide (Fig. 1. Fig. 2A, Fig. 3) comprising both the targeting portion and
the recruiting portion for editing nucleic acid sequences. However, an oligonucleotide
construct comprising the use of two oligonucleotides (Fig. 2B), for example one comprising
the targeting portion and one comprising the recruiting portion, is certainly within the ambit
of the present invention. Hence, according to another embodiment the invention provides
for two separate oligonucleotides, one comprising the targeting portion and the other
comprising the recruiting portion, whereby the two oligonucleotides are designed in such a
way that they have affinity towards each other, for example by antisense Watson-Crick
base pairing between the two functional portions or of a sequence without a specific
targeting or recruiting function, e.g. a linker sequence. Such a two component system may
have advantages in terms of flexibility, adaptability (e.g. within the context of personalised
medicine), manufacturability, cost of goods or otherwise. The two (or more) oligonucleotides
in accordance with the multicomponent system, do not necessarily have to separate the
different functions (targeting and recruiting) strictly. For example, the oligonucleotides may
give rise to the targeting and a recruiting function only after assembling into a complex. In
case the two oligonucleotides anneal, forming a dsRNA portion, they may actually create
the recruiting function upon annealing. Annealing is one way of forming a complex, but it will
be clear that there are other ways by which two (or more) oligonucleotide components may
come together, thereby amalgamating the targeting and the recruiting function.
Oligonucleotide constructs comprising more than two oligonucleotides are not excluded
from the scope of the present invention, although larger the number of oligonucleotides per
construct, the more complex the system in terms of manufacturing, analytics, formulation,
administration or other aspects of handling, including logistics and costs.
The mammalian cell
The invention concerns the modification of target RNA sequences in eukaryotic, preferably
metazoan, more preferably mammalian cells. In principle the invention can be used with
cells from any mammalian species, but it is preferably used with a human cell.
The invention can be used with cells from any organ e.g. skin, lung, heart, kidney, liver,
pancreas, gut, muscle, gland, eye, brain, blood and the like. The invention is particularly
suitable for modifying sequences in cells, tissues or organs implicated in a diseased state of
a (human) subject. Such cells include but are not limited to epithelial cells of the lung or the
gastrointestinal tract, cells of the reproductive organs, muscle cells, cells of the eye, cells of
the skin, cells from tissues and organs such as liver, kidney, pancreas, immune cells,
cancerous cells, gland cells, brain cells, and the like.
The invention can also be used with mammalian cells which are not naturally present in an
organism e.g. with a cell line or with an embryonic stem (ES) cell.
The invention can be used with various types of stem cell, including pluripotent stem cells,
totipotent stem cells, embryonic stem cells, induced pluripotent stem cells, etc.
The cell can be located in vitro or in vivo. One advantage of the invention is that it can be
used with cells in situ in a living organism, but it can also be used with cells in culture. In
some embodiments cells are treated ex vivo and are then introduced into a living organism
(e.g. re-introduced into an organism from whom they were originally derived).
The invention can also be used to edit target RNA sequences in cells within a so-called
organoid. Organoids can be thought of as three-dimensional in vitro–derived tissues but are
driven using specific conditions to generate individual, isolated tissues (e.g. see Lancaster
& Knoblich, Science 2014, vol. 345 no. 6194 1247125). In a therapeutic setting they are
useful because they can be derived in vitro from a patient’s cells, and the organoids can
then be re-introduced to the patient as autologous material which is less likely to be rejected
than a normal transplant. Thus, according to another preferred embodiment, the invention
may be practised on organoids grown from tissue samples taken from a patient (e.g. from
their gastrointestinal tract; see Sala et al. J Surg Res. 2009; 156(2):205-12, and also Sato
et al. Gastroenterology 2011;141:1762-72); upon RNA editing in accordance with the
invention, the organoids, or stem cells residing within the organoids, may be used to
transplant back into the patient to ameliorate organ function.
The cell to be treated will generally have a genetic mutation. The mutation may be
heterozygous or homozygous. The invention will typically be used to modify point
mutations, such as N to A mutations, wherein N may be G, C, U (on the DNA level T),
preferably G to A mutations, or N to C mutations, wherein N may be A, G, U (on the DNA
level T), preferably U to C mutations. Genes containing mutations of particular interest are
discussed below. In some embodiments, however, the invention is used in the opposite way
by introducing a disease-associated mutation into a cell line or an animal, in order to
provide a useful research tool for the disease in question. As an example of creating a
disease model, we have provided an oligonucleotide sequence that provides for the
recruitment of editing activity in a human cell to create a mutation in the CEP290 gene,
creating a cryptic splice site that forms the basis for a form of Leber’s Congenital
Amaurosis, the most common form of congenital child blindness.
A mutation to be reverted through RNA editing may have arisen on the level of the
chromosome or some other form of DNA, such as mitochondrial DNA, or RNA, including
pre-mRNA, ribosomal RNA or mitochondrial RNA. A change to be made may be in a target
RNA of a pathogen, including fungi, yeasts, parasites, kinetoplastids, bacteria, phages,
viruses etc, with which the cell or subject has been infected. Subsequently, the editing may
take place on the RNA level on a target sequence inside such cell, subject or pathogen.
Certain pathogens, such as viruses, release their nucleic acid, DNA or RNA into the cell of
the infected host (cell). Other pathogens reside or circulate in the infected host. The
oligonucleotide constructs of the invention may be used to edit target RNA sequences
residing in a cell of the infected eukaryotic host, or to edit a RNA sequence inside the cell of
a pathogen residing or circulating in the eukaryotic host, as long as the cells where the
editing is to take place contain an editing entity compatible with the oligonucleotide
construct administered thereto.
Without wishing to be bound be theory, the RNA editing through hADAR1 and hADAR2 is
thought to take place on pre-mRNAs in the nucleus, during transcription or splicing. The
RNA editing by cytidine deaminases is thought to take place on the mRNA level. Editing of
mitochondrial RNA codons or non-coding sequences in mature mRNAs is not excluded.
The target sequence and the change
The invention is used to make a change in a target RNA sequence in a eukaryotic cell
through the use of an oligonucleotide construct that is capable of targeting a site to be
edited and recruiting RNA editing entities resident in the cell to bring about the editing
reaction(s). Preferred editing reactions are adenosine deaminations and cytidine
deaminations, converting adenosines into inosines and cytidines into uridines, respectively.
The changes may be in 5’ or 3’ untranslated regions of a target RNA, in (cryptic) splice
sites, in exons (changing amino acids in protein translated from the target RNA, codon
usage or splicing behaviour by changing exonic splicing silencers or enhancers, by
introducing or removing start or stop codons), in introns (changing splicing by altering
intronic splicing silencers or intronic splicing enhancers, branch points) and in general in
any region affecting RNA stability, structure or functioning. The target RNA sequence may
comprise a mutation that one may wish to correct or alter, such as a (a transition or a
transversion). Alternatively, the target RNA sequence is deliberately mutated to create an
altered phenotype (or genotype, in case of RNA based organisms, such as RNA viruses),
where there was no mutation before. For example cell lines or animals may be made which
carry changes (mutations) in a target RNA sequence, which may be used in assays or as
(animal, organoid, etcetera) model systems to study disease, test experimental compounds
against disease, and the like. The oligonucleotide constructs and methods according to the
invention may be used in high throughput screening systems (in arrayed format) for making
cell banks with a large variety of target RNAs, for example coding for a large variety of
protein isoforms, for further experimentation, including compound screening, protein
engineering and the like.
The target RNA may be any cellular or viral RNA sequence, but is more usually a pre-
mRNA or a mRNA with a protein coding function.
Purely for ease of reference, and without the intention to limit the invention, the following
table is provided to illustrate the potential codon changes that can be brought about by
adenosine deaminase editing directed by oligonucleotides of the invention. The table
particularly should not be interpreted as a limitation of the applicability of the invention to
coding sequences in any RNA; as pointed out already, the invention can be practised on
any RNA target comprising an adenosine, whether in a coding region, an intron, a non-
coding exon (such as a 5'- or 3' untranslated region), in miRNAs, tRNAs, rRNAs and so on.
To avoid any misunderstanding about the width of the applicability, changes that are
inconsequential (‘silent’) from a coding perspective may still alter gene expression of a
certain protein as some codons for the same amino acid may be more preferred than others
and may lead, for instance, to different transcription stability or translation efficiency,
causing the encoded protein to become more or less abundant than without the change.
Target codon Amino acid Corrected codon Amino acid
GAA Glu
AGA Arg
AAG Lys
AAA Lys GGA Gly
AGG Arg
GAG Glu
GGG Gly
GAC Asp
AAC Asn AGC Ser
GGC Gly
GAG Glu
AAG Lys AGG Arg
GGG Gly
GAU Asp
AAU Arg AGU Ser
GGU Gly
GCA Ala
ACA Thr ACG Thr
GCG Ala
ACC Thr GCC Ala
ACG Thr GCG Ala
ACU Thr GCU Ala
GGA Gly
AGA Arg AGG Arg
GGG Gly
AGC Ser GGC Gly
AGG Arg GGG Gly
AGU Ser GGU Gly
AUA Ile GAU Asp
AUG Met
GUG Val
AUC Ile GUC Val
AUG Met GUG Val
AUU Ile GUU Val
CGA Arg
CAA Gln CAG Gln
CGG Arg
CAC His CGC Arg
CAG Gln CGG Arg
CAU His CGU Arg
CCA Pro CCG Pro
CGA Arg CGG Arg
CUA Leu CUG Leu
GGA Gly
GAA Glu GAG Glu
GGG Gly
GCA Ala GCG Ala
GUA Val GUG Val
GGA Gly GGG Gly
GAC Asp GGC Gly
GAG Glu GGG Gly
GAU Asp GGU Gly
UGA Stop
UAA Stop UAG Stop
UGG Trp
UCA Ser UCG Ser
UGA Stop UGG Trp
UUA Leu UUG Leu
UAC Tyr UGC Cys
UAG Stop UGG Trp
UAU Tyr UGU Cys
Particularly interesting target adenosines for editing using oligonucleotides according to the
invention are those that are part of codons for amino acid residues that define key
functions, or characteristics, such as catalytic sites, binding sites for other proteins, binding
by substrates, localization domains, for co- or post-translational modification, such as
glycosylation, hydroxylation, myristoylation, protein cleavage by proteases (to mature the
protein and/or as part of the intracellular routing), and so forth.
A host of genetic diseases are caused by G to A mutations, and these are preferred target
diseases because adenosine deamination at the mutated target adenosine will reverse the
mutation to wild-type. However, reversal to wild-type may not always be necessary to obtain
a beneficial effect. Modification of an A to G in a target may also be beneficial if the wild-
type nucleotide is other than a G. In certain circumstances this may be predicted to be the
case, in others this may require some testing. In certain circumstances, the modification
from an A in a target RNA to G where the wild-type is not a G may be silent (not translated
into a different amino acid), or otherwise non-consequential (for example an amino acid is
substituted but it constitutes a conservative substitution that does not disrupt protein
structure and function), or the amino acid is part of a functional domain that has a certain
robustness for change. If the A to G transition brought about by editing in accordance with
the invention is in a non-coding RNA, or a non-coding part of an RNA, the consequence
may also be inconsequential or less severe than the original mutation. Those of ordinary
skill in the art will understand that the applicability of the current invention is very wide and
is not even limited to preventing or treating disease. The invention may also be used to
modify transcripts to study the effect thereof, even if, or particularly when, such modification
induces a diseased state, for example in a cell or a non-human animal model.
Preferred examples of genetic diseases that can be prevented and/or treated with
oligonucleotides according to the invention are any disease where the modification of one
or more adenosines in a target RNA will bring about a (potentially) beneficial change.
Transcribed RNA sequences that are potential target RNA sequences according to the
invention, containing mutations of particular interest include, but are not limited to those
transcribed from the CFTR gene (the cystic fibrosis transmembrane conductance regulator),
dystrophin, huntingtin, neurofibromin 1, neurofibromin 2, the β-globin chain of haemoglobin,
CEP290 (centrosomal protein 290kDa), the HEXA gene of the β-hexosaminidase A, and
any one of the Usher genes (e.g. USH2B encoding Usherin) responsible for a form of
genetic blindness called Usher syndrome. A more extensive list is presented further below.
The target sequence will be selected accordingly, and the oligonucleotide construct will
include the desired modification in order to correct the mutation.
Those skilled in the art of CF mutations recognise that between 1000 and 2000 mutations
are known in the CFTR gene, including R117H, G542X, G551D, R553X, W1282X, and
N1303K.
In general, mutations in any target RNA that can be reversed using oligonucleotide
constructs according to the invention are G to A mutations, in the case of adenosine
deaminase recruitment, and U to C mutations in the case of cytidine deaminase
recruitment, and oligonucleotide constructs can be designed accordingly. Mutations that
may be targeted using oligonucleotide constructs according to the invention also include C
to A, U to A (T to A on the DNA level) in the case of recruiting adenosine deaminases, and
A to C and G to C mutations in the case of recruiting cytidine deaminases. Although RNA
editing in the latter circumstances may not necessarily revert the mutation to wild-type, the
edited nucleotide may give rise to an improvement over the original mutation. For example,
a mutation that causes an in frame stop codon – giving rise to a truncated protein, upon
translation - may be changed into a codon coding for an amino acid that may not be the
original amino acid in that position, but that gives rise to a (full length) protein with at least
some functionality, at least more functionality than the truncated protein.
The target sequence is endogenous to the eukaryotic, preferably mammalian, more
preferably human cell. Thus the target sequence is not, for instance, a transgene or a
marker gene which has been artificially introduced at some point in the cell’s history, but
rather is a gene that is naturally present in the cell (whether in mutant or non-mutant form).
The invention is not limited to correcting mutations, as it may instead be useful to change a
wild-type sequence into a mutated sequence by applying oligonucleotides according to the
invention. One example where it may be advantageous to modify a wild-type adenosine is
to bring about skipping of an exon, for example by modifying an adenosine that happens to
be a branch site required for splicing of said exon. Another example is where the adenosine
defines or is part of a recognition sequence for protein binding, or is involved in secondary
structure defining the stability of the mRNA. As noted above, therefore, the invention can
be used to provide research tools for diseases, to introduce new mutations which are less
deleterious than an existing mutation, etc.
Applications of the oligonucleotide constructs
The amount of oligonucleotide constructs to be administered, the dosage and the dosing
regime can vary from cell type to cell type, the disease to be treated, the target population,
the mode of administration (e.g. systemic versus local), the severity of disease and the
acceptable level of side activity, but these can and should be assessed by trial and error
during in vitro research, in pre-clinical and clinical trials. The trials are particularly
straightforward when the modified sequence leads to an easily-detected phenotypic
change. It is possible that higher doses of oligonucleotide could compete for binding to a
nucleic acid editing entity (e.g. ADAR) within a cell, thereby depleting the amount of the
entity which is free to take part in RNA editing, but routine dosing trials will reveal any such
effects for a given oligonucleotide and a given target.
One suitable trial technique involves delivering the oligonucleotide construct to cell lines, or
a test organism and then taking biopsy samples at various time points thereafter. The
sequence of the target RNA can be assessed in the biopsy sample and the proportion of
cells having the modification can easily be followed. After this trial has been performed once
then the knowledge can be retained and future delivery can be performed without needing
to take biopsy samples.
A method of the invention can thus include a step of identifying the presence of the desired
change in the cell’s target RNA sequence, thereby verifying that the target RNA sequence
has been modified. This step will typically involve sequencing of the relevant part of the
target RNA, or a cDNA copy thereof (or a cDNA copy of a splicing product thereof, in case
the target RNA is a pre-mRNA), as discussed above, and the sequence change can thus be
easily verified. Alternatively the change may be assessed on the level of the protein (length,
glycosylation, function or the like), or by some functional read-out, such as a(n) (inducible)
current, when the protein encoded by the target RNA sequence is an ion channel, for
example. In the case of CFTR function, an Ussing chamber assay or an NPD test in a
mammal, including humans, are well known to a person skilled in the art to assess
restoration or gain of function.
After RNA editing has occurred in a cell, the modified RNA can become diluted over time,
for example due to cell division, limited half-life of the edited RNAs, etc. Thus, in practical
therapeutic terms a method of the invention may involve repeated delivery of an
oligonucleotide construct until enough target RNAs have been modified to provide a
tangible benefit to the patient and/or to maintain the benefits over time.
Delivery of the oligonucleotide construct
Oligonucleotide constructs of the invention are particularly suitable for therapeutic use, and
so the invention provides a pharmaceutical composition comprising an oligonucleotide
construct of the invention and a pharmaceutically acceptable carrier. In some embodiments
of the invention the pharmaceutically acceptable carrier can simply be a saline solution.
This can usefully be isotonic or hypotonic, particularly for pulmonary delivery.
The invention also provides a delivery device (e.g. syringe, inhaler, nebuliser) which
includes a pharmaceutical composition of the invention.
The invention also provides an oligonucleotide construct of the invention for use in a
method for making a change in a target RNA sequence in a mammalian, preferably human
cell, as described herein. Similarly, the invention provides the use of an oligonucleotide
construct of the invention in the manufacture of a medicament for making a change in a
target RNA sequence in a mammalian, preferably human cell, as described herein.
Formulation, dosing and mode of administration for use in therapy
The oligonucleotide constructs according to the invention are suitably administrated in
aqueous solution, e.g. saline, or in suspension, optionally comprising additives, excipients
and other ingredients, compatible with pharmaceutical use, at concentrations ranging from
1 ng/ml to 1 g/ml, preferably from 10 ng/ml to 500 mg/ml, more preferably from 100 ng/ml to
100 mg/ml. Dosage may suitably range from between about 1 µg/kg to about 100 mg/kg,
preferably from about 10 µg/kg to about 10 mg/kg, more preferably from about 100 µg/kg to
about 1 mg/kg. Administration may be by inhalation (e.g. through nebulization), intranasally,
orally, by injection or infusion, intravenously, subcutaneously, intra-dermally, intra-cranially,
intramuscularly, intra-tracheally, intra-peritoneally, intra-rectally, by direct injection into a
tumor, and the like. Administration may be in solid form, in the form of a powder, a pill, or in
any other form compatible with pharmaceutical use in humans.
The invention is particularly suitable for treating genetic diseases, such as cystic fibrosis,
albinism, alphaantitrypsin deficiency, Alzheimer disease, Amyotrophic lateral sclerosis,
Asthma, ß-thalassemia, Cadasil syndrome, Charcot-Marie-Tooth disease, Chronic
Obstructive Pulmonary Disease (COPD), Distal Spinal Muscular Atrophy (DSMA),
Duchenne/Becker muscular dystrophy, Dystrophic Epidermolysis bullosa, Epidermylosis
bullosa, Fabry disease, Factor V Leiden associated disorders, Familial Adenomatous,
Polyposis, Galactosemia, Gaucher’s Disease, Glucosephosphate dehydrogenase,
Haemophilia, Hereditary Hematochromatosis, Hunter Syndrome, Huntington’s disease,
Hurler Syndrome, Inflammatory Bowel Disease (IBD), Inherited polyagglutination syndrome,
Leber congenital amaurosis, Lesch-Nyhan syndrome, Lynch syndrome, Marfan syndrome,
Mucopolysaccharidosis, Muscular Dystrophy, Myotonic dystrophy types I and II,
neurofibromatosis, Niemann-Pick disease type A, B and C, NY-eso1 related cancer,
Parkinson’s disease, Peutz-Jeghers Syndrome, Phenylketonuria, Pompe’s disease, Primary
Ciliary Disease, Prothrombin mutation related disorders, such as the Prothrombin G20210A
mutation, Pulmonary Hypertension, Retinitis Pigmentosa, Sandhoff Disease, Severe
Combined Immune Deficiency Syndrome (SCID), Sickle Cell Anemia, Spinal Muscular
Atrophy, Stargardt’s Disease, Tay-Sachs Disease, Usher syndrome, X-linked
immunodeficiency, various forms of cancer (e.g. BRCA1 and 2 linked breast cancer and
ovarian cancer), and the like.
In some embodiments the oligonucleotide construct can be delivered systemically, but it is
more typical to deliver an oligonucleotide construct to cells in which the target sequence’s
phenotype is seen. For instance, mutations in CFTR cause cystic fibrosis which is primarily
seen in lung epithelial tissue, so with a CFTR target sequence it is preferred to deliver the
oligonucleotide construct specifically and directly to the lungs. This can be conveniently
achieved by inhalation e.g. of a powder or aerosol, typically via the use of a nebuliser.
Especially preferred are nebulizers that use a so-called vibrating mesh, including the PARI
eFlow (Rapid) or the i-neb from Respironics. The inventors have found that inhaled use of
oligonucleotide constructs can lead to systemic distribution of the oligonucleotide construct
and uptake by cells in the gut, liver, pancreas, kidney and salivary gland tissues, among
others. It is therefore to be expected that inhaled delivery of oligonucleotide constructs
according to the invention can also target these cells efficiently, which in the case of CFTR
gene targeting could lead to amelioration of gastrointestinal symptoms also associated with
cystic fibrosis. For other target sequences, depending on the disease and/or the target
organ, administration may be topical (e.g. on the skin), intradermal, subcutaneous,
intramuscular, intravenous, oral, ocular injection, etc.
In some diseases the mucus layer shows an increased thickness, leading to a decreased
absorption of medicines via the lung. One such a disease is chronical bronchitis, another
example is cystic fibrosis. Various forms of mucus normalizers are available, such as
DNAses, hypertonic saline or mannitol, which is commercially available under the name of
Bronchitol. When mucus normalizers are used in combination with RNA editing
oligonucleotide constructs, such as the oligonucleotide constructs according to the
invention, they might increase the effectiveness of those medicines. Accordingly,
administration of an oligonucleotide construct according to the invention to a subject,
preferably a human subject is preferably combined with mucus normalizers, preferably
those mucus normalizers described herein. In addition, administration of the oligonucleotide
constructs according to the invention can be combined with administration of small
molecule for treatment of CF, such as potentiator compounds for example Kalydeco
(ivacaftor; VX-770), or corrector compounds, for example VX-809 (lumacaftor) and/or
VX-661. Other combination therapies in CF may comprise the use of an oligonucleotide
construct according to the invention in combination with an inducer of adenosine
deaminase, using IFN-gamma or TNF-alpha.
Alternatively, or in combination with the mucus normalizers, delivery in mucus penetrating
particles or nanoparticles can be applied for efficient delivery of RNA editing molecules to
epithelial cells of for example lung and intestine. Accordingly, administration of an
oligonucleotide construct according to the invention to a subject, preferably a human
subject, preferably uses delivery in mucus penetrating particles or nanoparticles.
Chronic and acute lung infections are often present in patients with diseases such as cystic
fibrosis. Antibiotic treatments reduce bacterial infections and the symptoms of those such
as mucus thickening and/or biofilm formation. The use of antibiotics in combination with
oligonucleotide constructs according to the invention could increase effectiveness of the
RNA editing due to easier access of the target cells for the oligonucleotide construct.
Accordingly, administration of an oligonucleotide construct according to the invention to a
subject, preferably a human subject, is preferably combined with antibiotic treatment to
reduce bacterial infections and the symptoms of those such as mucus thickening and/or
biofilm formation. The antibiotics can be administered systemically or locally or both.
For application in for example cystic fibrosis patients the oligonucleotide constructs
according to the invention, or packaged or complexed oligonucleotide constructs according
to the invention may be combined with any mucus normalizer such as a DNase, mannitol,
hypertonic saline and/or antibiotics and/or a small molecule for treatment of CF, such as
potentiator compounds for example ivacaftor, or corrector compounds, for example
lumacaftor and/or VX-661.
To increase access to the target cells, Broncheo-Alveolar Lavage (BAL) could be applied to
clean the lungs before administration of the oligonucleotide constructs according to the
invention.
The invention also provides an oligonucleotide construct comprising the nucleotide
sequence of any one of SEQ ID NOs: 1 to 3:
GFP SEQ ID NO: 1 5'-cgcgcgttttcgcgcgGCUGAAC*CACUGCAC-3'
CEP290 SEQ ID NO: 2 5'-cgcgcgttttcgcgcgGAGAUAC*UCACAAUU-3'
CFTR SEQ ID NO: 3 5'-cgcgcgttttcgcgcgCGUUGAC*CUCCACUC-3'
Corresponding sequence SEQ ID NO: 9 G551D mRNA 3'-GCAACUA*GAGGUGAG-5'
small letters = DNA with propensity to form Z-DNA structure
Bold underlined = 2’-O-methyl
Italics = Phosphorothioate internucleosidic linkages and 2’-O-methyl
C*= base opposite the target adenosine to be edited
Similarly, the invention also provides an oligonucleotide construct comprising the nucleotide
sequence of any one of SEQ ID NOs: 16 to 22 (and optionally the nucleic modifications
described in Example 1 for such nucleotide sequences) or any one of SEQ ID NOs: 2, 3,
28, 38, 39, 40 and 41 (and optionally the nucleic modifications described in Examples 2-5
for such nucleotide sequences).
General
The terms “adenine”, “guanine”, “cytosine”, “thymine”, “uracil” and hypoxanthine (the
nucleobase in inosine) refer to the nucleobases as such.
The terms adenosine, guanosine, cytidine, thymidine, uridine and inosine, refer to the
nucleobases linked to the (desoxy)ribosyl sugar.
The term “nucleoside” refers to the nucleobase linked to the (deoxy)ribosyl sugar.
The term nucleotide refers to the respective nucleobase-(deoxy)ribosyl-phospholinker, as
well as any chemical modifications of the ribose moiety or the phospho group. Thus the
term would include a nucleotide including a locked ribosyl moiety (comprising a 2’-4’ bridge,
comprising a methylene group or any other group, well known in the art), a nucleotide
including a linker comprising a phosphodiester, phosphotriester, phosphoro(di)thioate,
methylphosphonates, phosphoramidate linkers, and the like.
Sometimes the terms adenosine and adenine, guanosine and guanine, cytosine and
cytidine, uracil and uridine, thymine and thymidine, inosine and hypo-xanthine, are used
interchangeably to refer to the corresponding nucleobase, nucleoside or nucleotide.
Sometimes the terms nucleobase, nucleoside and nucleotide are used interchangeably,
unless the context clearly requires differently.
Whenever reference is made to an “oligonucleotide”, both oligoribonucleotides and
desoxyoligoribonucleotides are meant unless the context dictates otherwise. Whenever
reference is made to an oligoribonucleotide it may comprise the bases A, G, C, U or I.
Whenever reference is made to a desoxyoligoribonucleotide it may comprise the bases A,
G, C, T or I.
Whenever reference is made to nucleotides in the oligonucleotide construct, such as
cytosine, 5-methylcytosine, 5-hydroxymethylcytosine and β-D-Glucosylhydroxy-
methylcytosine are included; when reference is made to adenine, N6-Methyladenine and
7-methyladenine are included; when reference is made to uracil, dihydrouracil, 4-thiouracil
and 5-hydroxymethyluracil are included; when reference is made to guanine,
1-methylguanine is included.
Whenever reference is made to nucleosides or nucleotides, ribofuranose derivatives, such
as 2’-desoxy, 2’-hydroxy, and 2’-O –substituted variants, such as 2’-O-methyl, are included,
as well as other modifications, including 2’-4’ bridged variants.
Whenever reference is made to oligonucleotides, linkages between two mono-nucleotides
may be phosphodiester linkages as well as modifications thereof, including,
phosphodiester, phosphotriester, phosphoro(di)thioate, methylphosphonate, phosphor-
amidate linkers, and the like.
The term “comprising” encompasses “including” as well as “consisting” e.g. a composition
“comprising” X may consist exclusively of X or may include something additional e.g. X + Y.
The term “about” in relation to a numerical value x is optional and means e.g. x+10%.
The word “substantially” does not exclude “completely” e.g. a composition which is
“substantially free” from Y may be completely free from Y. Where relevant, the word
“substantially” may be omitted from the definition of the invention.
The term “downstream” in relation to a nucleic acid sequence means further along the
sequence in the 3' direction; the term “upstream” means the converse. Thus in any
sequence encoding a polypeptide, the start codon is upstream of the stop codon in the
sense strand, but is downstream of the stop codon in the antisense strand.
References to “hybridisation” typically refer to specific hybridisation, and exclude
non-specific hybridisation. Specific hybridisation can occur under experimental conditions
chosen, using techniques well known in the art, to ensure that the majority of stable
interactions between probe and target are where the probe and target have at least 70%,
preferably at least 80%, more preferably at least 90% sequence identity.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1: Cartoon of a target RNA sequence and an oligonucleotide construct according to
the invention; A: the oligonucleotide construct is designed as a single oligonucleotide “one-
legged” construct, with the targeting portion at its 3’ end and the recruiting portion at its 5’
end. B: the oligonucleotide construct is designed as a single oligonucleotide “one-legged”
construct, with the targeting portion at its 5’ end and the recruiting portion at its 3’end; the
editing entity is depicted as a grey structure, depicting the recognition domain on the left-
hand side and the catalytic domain on the right-hand side, indicating the deamination
reaction (flash) at the target site.
Figure 2: Cartoon of the target RNA structure with oligonucleotide construct: A shows the
oligonucleotide construct with a Linker between the targeting portion and the recruiting
portion; B shows the embodiment where the oligonucleotide construct comprises two
oligonucleotide sequences – not covalently bound – interacting through Watson-Crick
antisense base pairing by their respective 3’ segments.
Figure 3: Cartoon of the target RNA structure with the oligonucleotide construct in its “two-
legged” format, where the targeting portion is separated (or “split”) by the recruiting portion;
A shows the editing site upstream in the target RNA sequence, relative to the recruiting
portion of the oligonucleotide construct; B shows the editing site downstream in the
targeting RNA sequence, relative to the recruiting portion of the oligonucleotide construct.
Figure 4: Fluorescence microscopy of wells showing green fluorescence in HeLa cells after
lipofectamine transfection with pGFPstop57 and the indicated oligonucleotides, except: the
top-left panel is untreated cells; the bottom four panels are controls which did not receive at
least one of the indicated components. Figures 4a & 4b differ only by contrast.
Figure 5: Fluorescence microscopy of wells showing green fluorescence in HeLa cells after
lipofectamine transfection with pGFPstop57, pADAR2, and oligonucleotide #11 at various
ratios of the two plasmids. The top-left panel is untreated cells; the bottom panels shows
cells with a plasmid encoding non-mutant GFP rather than pGFPstop57.
Figure 6: Fluorescence microscopy of wells showing green fluorescence in HeLa cells 24 or
48 hours after no treatment, or transfection with 50 nM or 200 nM oligonucleotide #11 (or
with 500 nM of a control oligonucleotide) together with pGFPstop57.
Figure 7: FACS spectra of non-treated (left peak) or transfected (right peak) HeLa cells. In
7A-7F cells were transfected with pGFPstop57 and oligonucleotide #11. In 7B-7F (but not
7A) cells were also transfected with pADAR2. In 7G & 7H non-mutant GFP was expressed.
All embodiments illustrated in the drawings may be combined, as explained in the detailed
description of the invention herein.
MODES FOR CARRYING OUT THE INVENTION
Example 1: Reversing a non-sense mutation in a GFP target RNA by site-directed A
to I editing
Oligonucleotide construct to be used: 5’-cgcgcgttttcgcgcgGCUGAAC*CACUGCAC-3’ (SEQ
ID NO: 1). HeLa cells (ATCC, CCL-2) are cultured in Dulbecco’s modified Eagle’s medium
(Life Technologies) supplemented with 10% heat-inactivated fetal bovine serum. Cells are
kept in an atmosphere of humidified air with 5% CO . The cells are seeded in 24-well plate
one day before the transfection and when they reach be 70-80% confluency. The GFP
reporter construct with an abolished GFP activity because of a stop codon TGA was used.
100-200 ng of plasmid DNA and 500 ng oligonucleotide (10-100 pmol) construct are mixed
in the appropriate amount of Opti-MEM I Medium (Life Technologies) and Lipofectamine
2000 reagent and the cells are transfected according to the manufacturer’s procedure. The
cells are incubated at 37°C in a CO incubator and the medium is replaced after 4-6 hours.
After 48 hours the cells are analyzed under the fluorescent microscope to assess the
efficiency of the oligo to restore GFP expression.
Further experiments again used a mutant GFP having an internal TAG stop codon due to a
G→A point mutation, expressed from a plasmid (‘pGFPstop57’). The cells were additionally
transfected with a plasmid encoding ADAR2 to ensure that the cells were able to perform
RNA editing. Various oligonucleotides were prepared for restoring GFP expression via
deamination of the mutant A residue, based on the principle of a targeting portion specific
for the GFP mutation and a recruiting portion based on GluR-B.
Seven RNA oligonucleotides were tested, and these targeted short, medium or long forms
of GluR-B (S/M/L; different lengths of the recruiting portion). In addition, these had the
targeting and recruiting portions in either order (upstream/downstream), and in some cases
the oligos included chemically modified regions (the recruiting portion was chemically
modified to include 2'-OMe sugars and phosphorothioate linkages; the targeting portion was
modified in the same way, except for the mutant A position (double underlined) and its two
flanking nucleotides). All oligos include SEQ ID NO: 7 (underlined), and GFP targeting
portions are in bold text:
GluR-B (length
Oligo Modification Sequences (SEQ ID NO:)
& position)
GUGUUGGCCAUGGAACAUAUAACAAUAUgcuaaAUGUUGUUAUA (16)
#2 S 3' unmodified
#3 S 5' 2'OMe-PS UAUAACAAUAUgcuaaAUGUUGUUAUAGUGUUGGCCAUGGAACA (17)
#4 S 3' 2'OMe-PS GUGUUGGCCAUGGAACAUAUAACAAUAUgcuaaAUGUUGUUAUA (18)
#6 M 3' unmodified GUGUUGGCCAUGGAACAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAU (19)
#9 L 5' unmodified GGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCGUGUUGGCCAUGGAACA (20)
GUGUUGGCCAUGGAACAGGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCC (21)
#10 L 3' unmodified
#11 L 5' 2'OMe-PS GGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCGUGUUGGCCAUGGAACA (22)
HeLa cells are cultured in Dulbecco’s modified Eagle’s medium supplemented with 10%
heat-inactivated fetal bovine serum. Cells are kept in an atmosphere of humidified air with
% CO . 8x10 cells are seeded in one well of a 24-well plate one day before transfection
and when they reach 70-80% confluency are transiently transfected with (i) oligonucleotide
+ GFPstop57 plasmid or (ii) oligonucleotide + GFPstop57 + ADAR2 plasmids by using
Lipocetamine 2000 according to the manufacturer’s procedure. The medium is refreshed 24
hours after the transfection, and GFP expression is checked under the fluorescent
microscope 24 hours later.
FACS analysis is also performed. The cells are trypsinized and collected in an Eppendorf
tube and then resuspended in Flow Cytometry Staining Buffer. Intact cells are selected
based on morphological properties using forward scatter and side scatter, excluding debris.
Of the intact cells, median and mean values of GFP mean fluorescent intensity (MFI) are
calculated. Overlay histograms are created using the layout editor.
Results for cells transfected without the ADAR plasmid are shown in Figure 4, and green
fluorescence above the levels seen in controls (which is due to autofluorescence of cells
and/or medium components) is clearly visible for all seven oligos. Oligos #10 & #11 gave
the best results (both having a long GluR-B recruiting portion), and the oligo with an
upstream recruiting portion (#11) was slightly better.
Oligo #11 was therefore chosen for further studies in combination with the ADAR2-encoding
plasmid. Figure 5 again shows that cells treated with oligo #11 fluoresce above levels seen
in negative controls. For comparison, cells were transfected with a plasmid encoding a
non-mutant GFP and the expected fluorescence was seen (Figure 5, bottom panel).
Different concentrations of oligo #11 were tested, ranging from 50-1500 nM. Figure 6 shows
example results after 24 or 48 hours using 50 and 200 nM, along with untreated cells (left)
and control cells which were tested with 500 nM of a control oligo having the same length
and chemical modifications as oligo #11. Oligo #11 showed a time-dependent increase in
fluorescence, which was not seen with the control oligo.
The oligonucleotide’s effect on GFP expression was also visible by FACS (Figure 7). Cells
treated with oligo #11, with (7B-7F) or without (7A) the ADAR2 plasmid, displayed an
increase in GFP fluorescence relative to untreated cells (left-hand peak). Non-mutant GFP
was used as a positive control (7G-7H).
Example 2: Introducing a cryptic splice site in a CEP290 target RNA by site-directed
A to I editing
Oligonucleotide construct to be used: 5’-cgcgcgttttcgcgcgGAGAUAC*UCACAAUU-3' (SEQ
ID NO: 2).
All cell lines are human fibroblasts, generated from skin biopsies. FBL1 (CL10-00008) and
FBL2 (CL12-00027) are wild type and represent control cell lines, FBL3 (CL12-00035) and
FBL4 (CL12-00036) are both homozygous mutant for a mutation in CEP290
(c.2991+1655A>G). All cell lines are grown in DMEM medium (Life Technologies)
supplemented with 20% FBS, 1% Pen/strep and 1% sodium pyruvate.
A day before transfection, cells are seeded in a density of 2x10 /well on a 6-well plate in a
total volume of 2.5 ml of medium. The day of the transfection, the AON to be tested is
added to each well in a final concentration of 100nM using maxPEI (Poliscience) as a
transfection agent, with a mass ratio oligo:PEI of 1:4. After 24h, cells are washed with PBS
and cell lysate is collected and frozen at -80°C.
RNA is isolated from the cell lysates that have been kept at -80°C using the Promega kit
ReliaPrep RNA Cell Miniprep System. Total RNA is quantified using a Nanodrop 2000
spectrophotometer.
400ng of RNA is used as template for the cDNA synthesis using the Verso cDNA synthesis
kit (Thermoscientific) according to the manufacturer’s instructions.
cDNA is diluted 2.5x for this reaction and 2µl of these diluted cDNA is used as template.
Amplification of the target sequence uses AmpliTaq Gold® 360 DNA Polymerase from Life
Technologies. Primers used are ex26_Fw (SEQ ID NO: 10) and ex27_Rv (SEQ ID NO: 11)
with PCR conditions as follows: hold 5 min at 95°C, denature 30 sec at 95°C, anneal 30 sec
at 58°C and extend 35 sec at 72°C, 35 cycles, final extension is 7 min at 72°C.
PCR fragments are analyzed in the Agilent 2100 Bioanalyzer using the Agilent DNA 1000
Kit from Agilent technologies. This kit contains a chip composed of interconnected
microchannels, through which the fragments are separated based on their size as they are
driven through it electrophoretically. To measure the level of expression of CEP290 mRNA,
wild type and mutant transcripts are amplified as 93bp and 117bp fragments, respectively.
The human P0 large ribosomal protein mRNA (RPLP0) is used as normalization. The
primers used are wt_Fw (SEQ ID NO: 12), wt-Rv (SEQ ID NO: 13), mt_Fw (SEQ ID NO:
14), and mt_Rv (SEQ ID NO: 15). For this reaction, SYBR select master mix from Life
Technologies along with cDNA diluted 10x used as template. PCR program is 50°C for 2
min, 95°C for 2 min, 50 cycles of 95°C for 15 sec, 62.5°C for 1 min.
Example 3: Reversing an amino acid substitution in a mutant CFTR G551D target
RNA by site-directed A to I editing
Oligonucleotide construct to be used: 5’-cgcgcgttttcgcgcgCGUUGAC*CUCCACUC-3’ (SEQ
ID NO: 3).
The cell lines are human fibroblasts, generated from skin and heart pericardium biopsies,
GM00142 and GM03465, respectively, Coriell Institute Cell Repository). They are both
heterozygote: one allele carries the deltaF508 deletion mutation (Phe508Del) and a second
allele carries a G-to-A transition at nucleotide 1784 (1784G>A) which converts the gly-551
codon (GGT) to an asp (GAT), resulting in a missense mutation in exon 11 in the CFTR
gene [Gly551Asp (G551D)]. All cell lines are grown in Eagle's Minimum Essential Medium
(Life Technologies) with Earle's salts and non-essential amino acids supplemented with
% FBS non-activated and 1% Pen/strep.
A day before transfection, cells are seeded in a density of 2x10 /well on a 6-well plate in a
total volume of 2.5 ml of medium. The day of the transfection, the oligo to be tested is
added to each well in a final concentration of 100nM using maxPEI (Poliscience) as a
transfection agent, with a mass ratio oligo:PEI of 1:4. After 24h, cells are washed with PBS
and cell lysate is collected and frozen at -80°C.
RNA is isolated from the cell lysates that have been kept at -80°C using the Promega kit
ReliaPrep RNA Cell Miniprep System. Total RNA is quantified using a Nanodrop 2000
spectrophotometer. 400ng of RNA is used as template for the cDNA synthesis using the
Verso cDNA synthesis kit (Thermoscientific) according to the manufacturer’s instructions. 1
μl of cDNA was first subjected to PCR with 0.4 μM of forward and reverse primers, 25 μM
of each dNTP, 1× AmpliTaq Gold® 360 Buffer, 3.125 30 mM MgCl2 and 1.0 units of
AmpliTaq Gold® 360 polymerase (all Life Technologies) were assembled. The primers
used are SEQ ID NOs: 26 (fwd) and 27 (rev). The PCR cycles were performed using the
following cycling conditions. An initial denaturing step at 95°C for 7 min was followed by 30
cycles of 30 s at 95°C, 30 s at 55°C and 45 s at 72°C. The PCR amplifications were
terminated by a final elongation period of 7 min at 72°C. 1 µl of the previous PCR was used
in a nested-PCR program containing 35 0.4 µM of forward primers and a unique MiSeq
index primer per sample, 25 µM of each dNTP, 1× AmpliTaq Gold® 360 Buffer, 3.125 mM
MgCl and 1.0 units AmpliTaq Gold® 360 polymerase. PCR cycles were performed using
the following cycling conditions: an initial denaturing step at 95°C for 7 min was followed by
cycles of 30s at 95°C, 30 s at 60°C and 45s at 72°C. Reactions were terminated using a
final elongation period of 7 minutes at 72°C. Before loading the PCR products containing
the MiSeq sequence primer sequences in the sequencer, the concentration of the purified
PCR products was measured using a Qubit® 2.0 Fluorometer (Life Technologies) according
the manufacturer’s protocol. In summary, two Assay Tubes for the standards were made by
making 20-fold dilutions of the 2 stock standards in working solution. For each sample,
200 µl of working solution was prepared in 10 separate tubes, 1 µl of the PCR product was
brought into this solution and mixed by vortexing for a couple of seconds. Samples were
measured against the two standards and the concentration in ng/µl was calculated
accordingly. Sequencing of the PCR products was performed on the MiSeq™ system from
Illumina, which uses sequencing-by-synthesis to provide rapid high quality sequence data.
Example 4: Reversing an amino acid substitution mutation in the αantitrypsin
(A1AT) transcript by targeted A to I editing for the treatment of A1AT deficiency
Oligonucleotides (SEQ ID NO: 28):
ADAR45: rGrGrArArUrArGrUrArUrArArCrArArUrArUrgrcrurararArUrGrUrUrGrUrUrArUrArGr
UrArUrCrCrCmC*mA*mG*mU*mCmCmCmUmUmUmCrUrCrGmUmCmGmAmUmGmG*m
U*mC*mA*mG
ADAR47: mG*mG*mA*mA*mU*mA*mG*mU*mA*mU*mA*mA*mC*mA*mA*mU*mA*mU*m
G*mC*mU*mA*mA*mA*mU*mG*mU*mU*mG*mU*mU*mA*mU*mA*mG*mU*mA*mU*mC*
mC*mCmC*mA*mG*mU*mCmCmCmUmUmUmCrUrCrGmUmCmGmAmUmGmG*mU*mC*
mA*mG
r = no modification
m = 2'O-Me
* = phosphorothioate linkage
Transfection of liver fibroblasts
Liver fibroblasts are provided from Coriell Cell Repository (GM11423), isolated from a donor
subject homozygous for the Z allele (ZZ), which results from a G>A transition at nucleotide
9989 in exon 5 of the SERPINA1 gene [9989G>A] resulting in a substitution of lysine for
glutamic acid at codon 342 [Glu342Lys (E342K)]. The cells are maintained in EMEM
medium (Life Technologies) and supplemented with 15% FBS. One day before the
transfections the cells are seeded in a 6-well plate in a total volume of 2 ml of medium. On
the day of the transfection oligonucleotide is added to 1x PBS (Thermo Fisher Scientific) in
1.5 ml microfuge tube and mixed with MaxPei (Polysciences) and incubated together and
incubated for 20 min. In the meantime, cell culture medium is removed from the cells and
suitable amount of fresh EMEM with 15% FBS is added. Then DNA/Oligo-MaxPei diluted
mixture is added on to the cell with gentle drop by drop pipetting. The cells are incubated at
37°C and the medium is refreshed after 6-24h.
RNA isolation
RNA Isolation is performed using the Reliaprep RNA Cell Miniprep System (Promega)
according to the manufacturer’s procedure. Briefly, culture medium is removed and the cells
are washed with cold PBS. 250µl lysis buffer is added on each well of 6-well plate. The
plate is gently rocked and the cells are lysed completely by repeated pipetting over the well
surface. 85µl isopropanol is added on to the lysate as recommended and the lysate is
transferred to Minicolumn and centrifuged for 30 sec at 12,000-14,000g (RT), the liquid is
discarded. 500µl of RNA Wash Solution is added and centrifuged again 30 sec at 12,000-
14,000g. In a sterile tube, DNase I incubation master mix is prepared by combining sample
24µl of Yellow Core Buffer, 3µl 0.09M MnCl , 3µl DNAse I and 30µl freshly prepared DNase
I mix is added to the membrane in the column of each sample, incubated for 15 min at RT.
Then 200µl of Column Wash Solution is added and centrifuged for 15 sec at 12,000-
14,000g. After that 500µl of RNA Wash Solution is added and centrifuged for 30 sec at
12,000-14,000g and liquid is discarded. The minicolumn is placed into a new collection tube
and 300µl of RNA Wash Solution is added and centrifuged at 14,000g for 2 min. Each
Minicolumn is placed to an Elution Tube and Nuclease-Free Water is added to the
membrane and centrifuged 1 min. Lastly, RNA concentration is measured on the Nanodrop.
cDNA synthesis
cDNA synthesis is performed using the Verso cDNA synthesis kit (Thermo Fisher) with
500ng or 1000ng RNA input. RNA mix is prepared by taking the desired amount of RNA
and completing it to a total volume of 11µl by adding water. The mix is heated for 5 min. at
70°C, then cooled. cDNA mix is prepared according to the pipetting scheme provided by the
supplier. 9µl of cDNA mix is put in a reaction tube and 11µl RNA mix is added and is kept at
the thermal cycler for 30 min. at 42°C and 2 min. at 95°C.
PCR
PCR is performed using the AmpliTaq Gold 360 DNA Polymerase 1000U Kit (Applied
Biosystems). A PCR mastermix is prepared by adding 1µl of cDNA, 2.5µl of 10x buffer, 3µl
of MgCl , 0.5µl of dNTPs, 1µl of each primer, 0.5µl Taq polymerase and by adding water to
complete 25µl. The PCR program is as follows; 95°C for 5 min, 95°C for 30 s, 55°C for
30 s, 72°C for 1 min for 35 cycles and 72°C for 7 min. After PCR, the samples are run on
the Bioanalyzer using the DNA 1000 kit (Agilent) and program.
PCR sample purification
Samples are purified using a Nucleospin PCR cleanup kit (Macherey-Nagel) to ensure
removal of contamination of PCR products. 1 volume of PCR sample is mixed with 2
volumes NT1 and samples are loaded into the NucleoSpin® Gel and PCR Clean-up
Column is placed in a Collection Tube and centrifuged for 30 s at 11000 x g. The liquid is
discarded and column is placed back into collection tube. 700µl Buffer NT3 to the
NucleoSpin® Gel is added and centrifuged for 30 s at 11000 x g. The washing step is
repeated and tubes are centrifuged for 1 min at 11000 x g to remove Buffer NT3.
NucleoSpin® Gel and PCR Clean-up Column is placed into a new 1.5ml Eppendorf tube,
-30µl Buffer NE is added and incubated for 1 min. at room temperature then centrifuged
for 1 min. at 11000 x g. DNA concentration is measured by using the Nanodrop method.
Restriction digestion
After PCR clean up, SERPINA1 amplicon is subjected to Hyp99I restriction digestion. The
enzyme recognizes the last G in CGACG sequence in WT and cuts the amplicon in two
pieces but it cannot cut CGACA sequence in the mutant version because of absence of the
second G. Thus if editing is successful there will be some WT DNA as a substrate for
Hyp99I restriction digestion. 1 unit of Hyp99I (NEB) is used to digest 0.1µg of DNA. A DNA
input of 0.5µg is used. Samples are diluted in nuclease-free water and incubated for 1-1.5
hour at 37°C, the enzyme is inactivated by subsequent incubation of the samples at 65°C
for 20min. After incubation, samples are loaded on the Bioanalyzer using the DNA1000 kit
(Agilent) and program to visualize the results.
Taqman PCR
SNP genotyping assay is performed using the custom SERPINA1 SNP genotyping assay
(ThermoFisher Scientific). This assay is performed in parallel to restriction enzyme
digestion assay to explore which assay is more sensitive for the detection of editing. The
probes specific to WT and mutant SERPINA1 have different fluorescent groups attached,
VIC and FAM, respectively. So we can quantify the increase or decrease in the amounts of
WT/mutant transcripts. The reaction mix is prepared by adding 5µl of master mix and 0.5µl
of probe-primer mixture. Sequences of oligos used are: WT probe (SEQ ID NO: 29), mutant
probe (SEQ ID NO: 30), forward primer (SEQ ID NO: 31), and reverse primer (SEQ ID NO:
32). 5.5µl reaction mix is added to the designated wells of a 96-well plate. 4.5µl of cDNA is
added to each well. The PCR program is run as follows: 95°C for 10 min, 92°C for 15 sec
and 60°C for 90 sec for 50 cycles. The results were analyzed by using the CFX Manager.
Example 5: Reversing an amino acid substitution mutation G2019S in the LRRK2
transcript by targeted A to I editing for the treatment of Parkinson’s disease
Mutations in the catalytic Roc-COR and kinase domains of leucine-rich repeat kinase 2
gene (LRRK2 Gene ID: 120892) are a common cause of familial Parkinson’s disease (PD).
We set out to target the G2019S mutation in the LRRK2 pre-mRNA transcript (Transcript
RefSeq NM_198578.3) using AONs capable of recruiting ADAR1 and 2 by virtue of the full
length or shortened GluRB portion as recruiting portion linked to a targeting portion with
complementarity to the sequence surrounding the G to A mutation in exon 41 at position
G6055 (see sequence below with the mutated G underlined). This mutation is also identified
as Genbank dbSNP variation rs34637584, commonly referred to as G2019S.
LRRK2 Exon 41 sequence with the wt G residue highlighted in position 6055:
ATACCTCCACTCAGCCATGATTATATACCGAGACCTGAAACCCCACAATGTGCTGCTT
TTCACACTGTATCCCAATGCTGCCATCATTGCAAAGATTGCTGACTACGGCATTGCTC
AGTACTGCTGTAGAATGGGGATAAAAACATCAGAGGGCACACCAG (SEQ ID NO: 33)
Mutant allele and translation:
GCT GAC TAC AGC ATT GCT CAG SEQ ID NO: 34
Ala Asp Tyr Ser Ile Ala Gln SEQ ID NO: 35
Normal allele and translation (after A to I editing):
GCT GAC TAC GGC ATT GCT CAG SEQ ID NO: 36
Ala Asp Tyr Gly Ile Ala Gln SEQ ID NO: 37
The following sequences have been designed to target the LRRK2 G2019S mutation.
Nucleotides in bold form the targeting portion; all nucleotides are 2'-OMe except those
underlined; * designates a PS-linkage. The AONs vary in the length of the targeting portion
either 25 (LRRK2-ADAR1 and LRRK2-ADAR3) or 30 nucleotides (LRRK-ADAR2 and 4).
The AONs vary in the length of the recruiting portion: shortened GluRB recruiting portion
(LRRK2-ADAR3 and 4) and full length GluRB recruiting portion (LRRK2-ADAR1 and 2).
LRRK2- Sequence (SEQ ID NO:)
ADAR1 GUGGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCACACUGA
GCAAUGCcGUAGUCAG*C*A*A*U (SEQ ID NO: 38)
ADAR2 GUGGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCACGUACU
GAGCAAUGCcGUAGUCAGCAA*U*C*U*U (SEQ ID NO: 39)
ADAR3 GGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCACUGAGCAA
UGCcGUAGUCAG*C*A*A*U (SEQ ID NO: 40)
ADAR4 GGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCGUACUGAGC
AAUGCcGUAGUCAGCAA*U*C*U*U (SEQ ID NO: 41)
Correction of LRRK2 is assessed in LRRK2G6055A mutant fibroblasts through means of
RNA sequencing, western blot analysis of LRRK2 (auto)-phosphorylation status, and
functional readouts of established LRRK2 -associated mitochondrial phenotypes (oxygen
consumption rate and mitochondrial membrane potential). See: Tatiana et al. (2012) Hum.
Mol. Genet. 21 (19): 4201-4213; Smith et al. (2015) Molecular Neurobiology, 1-17; and
Grünewald et al. (2014) Antioxidants & Redox Signaling, 20(13), 1955–1960.
LRRK2G6055A homozygous fibroblast line fff-028 (Telethon Network of Genetic Biobanks),
heterozygous G6055A lines ND29492, ND29542, ND29802, and healthy controls lines
GM023074, GM08402 (Coriell Institute), are transfected with LRRK2-ADAR AON using
Lipofectamine 2000. After 48-96 hours incubation, the following analyses are performed:
1) To detect A-to-I edited LRRK2 transcript, cells are lysed, RNA isolated by standard
methods, and subjected to semi-quantitative RNA sequencing analysis using the following
sequencing primers of SEQ ID NOs: 42 & 43. A-to-I edited mRNA sequences appear after
transfection of LRRK2-ADAR-AON.
2) LRRK2G6055A protein has previously been demonstrated (Smith et al., 2015) to show
increased auto-phosphorylation at serine 955 after stress-treatment with the mitochondrial
membrane depolarizing agent valinomycin (10 μM for 24h), due to increased catalytic
activity of the kinase domain, as compared to LRRK2wt. Treatment with LRRK2-ADAR-
AON reduces serine-955 phosphorylation of valinomycin-treated LRRK2G6055A cells at
least partially, potentially even completely to wild-type levels. This can be assessed by
western blot analysis (Smith et al.) using LRRK2 phospho-S955 (Abcam clone MJF-R11-
(75-1)), and total LRRK2 (Abcam clone MJFF2 (c41-2)) antibodies.
3) LRRK2G6055A fibroblasts display alterations in mitochondrial respiration (OXPHOS),
including increased proton leak (Smith et al., 2015; Grünewald et al., 2014) which can be
reversed after LRRK2-ADAR-AON transfection. Oxygen consumption rate under basal and
forced respiratory conditions is assessed using a Seahorse XF24 extracellular flux analyzer
(Seahorse Bioscience), a device that measures concentration of dissolved oxygen in the
culture medium in 2 s time intervals by solid-state sensor probes. This analysis can be
performed together with XF Xell Mito Stress Test kit (Seahorse Bioscience), which by
sequential treatment with oligomycin, carbonyl cyanide(trifluoromethoxy)phenyl
hydrazone (FCCP), rotenone and antimycin-A, can determine metabolic parameters such
as basal respiration, ATP production, proton leak, and maximal respiration. The assay is
performed according to manufacturer’s instructions, and proton leak is defined as remaining
oxygen consumption after oligomycin treatment.
4) LRRK2G6055A fibroblasts display decreased mitochondrial membrane potential as
compared to control cells (Smith et al., 2015; Grünewald et al., 2014). Mitochondrial
membrane potential is assessed with the lipophilic cationic dye tetramethylrhodamine
methylester (TMRM), used in non-quenching mode (0.5-30 nM, determined empirically),
loaded in phenol red-free culture medium for 20 minutes. After dye-loading, steady-state
mitochondrial TMRM fluorescence is measured by live-cell confocal microscopy and image
analysis. LRRK2-ADAR-AON transfection can increase mitochondrial membrane potential
at least partially, potentially even completely to control levels.
Conclusions
The examples described above show how to make desired changes in a target RNA
sequence by site-directed editing of nucleotides in a target RNA molecule using
oligonucleotide constructs according to the invention. The examples teach how to remove a
stop codon to reopen the reading frame of a GFP expression construct, create a splice site
to change the splicing pattern of the target RNA coding for CEP290, and how to establish a
desired amino acid substitution by making a change in a codon in the target RNA sequence
coding for a mutant G551D CFTR protein. Successful RNA editing can conveniently be
confirmed, for example by observing fluorescent cells in the case of the GFP non-sense
mutation reversal, by observing a shift in the RT-PR bands in a gel from wild-type to mutant
in the case of introducing the cryptic splice site in the CEP290 coding RNA, and by
sequencing, or by using a functional assay (e.g. an Ussing chamber assay), in the case of
the reversal of the G551D mutation in the CFTR coding RNA, and the like. Similar work on
αantitrypsin (A1AT) and LRRK2 can also be performed.
It will be understood that the invention is described above by way of example only and
modifications may be made whilst remaining within the scope and spirit of the invention.
SEQUENCE LISTING
SEQ ID NO: 1 DNA-RNA oligonucleotide construct editing a non-sense mutation in eGFP:
cgcgcgttttcgcgcgGCUGAACCACUGCAC
SEQ ID NO: 2 DNA-RNA oligonucleotide construct creating a cryptic splice site in hCEP290:
cgcgcgttttcgcgcgGAGAUACUCACAAUU
SEQ ID NO: 3 DNA-RNA Oligonucleotide construct editing a G551D mutation in hCFTR:
cgcgcgttttcgcgcgCGUUGACCUCCACUC
SEQ ID NO: 4 hCFTR DNA showing G551D hCFTR mutation in lower case (n is T or C):
ATGCAGAGGTCGCCTCTGGAAAAGGCCAGCGTTGTCTCCAAACTTTTTTTCAGCTGGACCAGACCAATTTTGAGGAAAGGATACAG
ACAGCGCCTGGAATTGTCAGACATATACCAAATCCCTTCTGTTGATTCTGCTGACAATCTATCTGAAAAATTGGAAAGAGAATGGG
ATAGAGAGCTGGCTTCAAAGAAAAATCCTAAACTCATTAATGCCCTTCGGCGATGTTTTTTCTGGAGATTTATGTTCTATGGAATC
TTTTTATATTTAGGGGAAGTCACCAAAGCAGTACAGCCTCTCTTACTGGGAAGAATCATAGCTTCCTATGACCCGGATAACAAGGA
GGAACGCTCTATCGCGATTTATCTAGGCATAGGCTTATGCCTTCTCTTTATTGTGAGGACACTGCTCCTACACCCAGCCATTTTTG
GCCTTCATCACATTGGAATGCAGATGAGAATAGCTATGTTTAGTTTGATTTATAAGAAGACTTTAAAGCTGTCAAGCCGTGTTCTA
GATAAAATAAGTATTGGACAACTTGTTAGTCTCCTTTCCAACAACCTGAACAAATTTGATGAAGGACTTGCATTGGCACATTTCGT
GTGGATCGCTCCTTTGCAAGTGGCACTCCTCATGGGGCTAATCTGGGAGTTGTTACAGGCGTCTGCCTTCTGTGGACTTGGTTTCC
TGATAGTCCTTGCCCTTTTTCAGGCTGGGCTAGGGAGAATGATGATGAAGTACAGAGATCAGAGAGCTGGGAAGATCAGTGAAAGA
CTTGTGATTACCTCAGAAATGATTGAAAATATCCAATCTGTTAAGGCATACTGCTGGGAAGAAGCAATGGAAAAAATGATTGAAAA
CTTAAGACAAACAGAACTGAAACTGACTCGGAAGGCAGCCTATGTGAGATACTTCAATAGCTCAGCCTTCTTCTTCTCAGGGTTCT
TTGTGGTGTTTTTATCTGTGCTTCCCTATGCACTAATCAAAGGAATCATCCTCCGGAAAATATTCACCACCATCTCATTCTGCATT
GTTCTGCGCATGGCGGTCACTCGGCAATTTCCCTGGGCTGTACAAACATGGTATGACTCTCTTGGAGCAATAAACAAAATACAGGA
TTTCTTACAAAAGCAAGAATATAAGACATTGGAATATAACTTAACGACTACAGAAGTAGTGATGGAGAATGTAACAGCCTTCTGGG
AGGAGGGATTTGGGGAATTATTTGAGAAAGCAAAACAAAACAATAACAATAGAAAAACTTCTAATGGTGATGACAGCCTCTTCTTC
AGTAATTTCTCACTTCTTGGTACTCCTGTCCTGAAAGATATTAATTTCAAGATAGAAAGAGGACAGTTGTTGGCGGTTGCTGGATC
CACTGGAGCAGGCAAGACTTCACTTCTAATGATGATTATGGGAGAACTGGAGCCTTCAGAGGGTAAAATTAAGCACAGTGGAAGAA
TTTCATTCTGTTCTCAGTTTTCCTGGATTATGCCTGGCACCATTAAAGAAAATATCATCTTTGGTGTTTCCTATGATGAATATAGA
TACAGAAGCGTCATCAAAGCATGCCAACTAGAAGAGGACATCTCCAAGTTTGCAGAGAAAGACAATATAGTTCTTGGAGAAGGTGG
AATCACACTGAGTGGAganCAACGAGCAAGAATTTCTTTAGCAAGAGCAGTATACAAAGATGCTGATTTGTATTTATTAGACTCTC
CTTTTGGATACCTAGATGTTTTAACAGAAAAAGAAATATTTGAAAGCTGTGTCTGTAAACTGATGGCTAACAAAACTAGGATTTTG
GTCACTTCTAAAATGGAACATTTAAAGAAAGCTGACAAAATATTAATTTTGCATGAAGGTAGCAGCTATTTTTATGGGACATTTTC
AGAACTCCAAAATCTACAGCCAGACTTTAGCTCAAAACTCATGGGATGTGATTCTTTCGACCAATTTAGTGCAGAAAGAAGAAATT
CAATCCTAACTGAGACCTTACACCGTTTCTCATTAGAAGGAGATGCTCCTGTCTCCTGGACAGAAACAAAAAAACAATCTTTTAAA
CAGACTGGAGAGTTTGGGGAAAAAAGGAAGAATTCTATTCTCAATCCAATCAACTCTATACGAAAATTTTCCATTGTGCAAAAGAC
TCCCTTACAAATGAATGGCATCGAAGAGGATTCTGATGAGCCTTTAGAGAGAAGGCTGTCCTTAGTACCAGATTCTGAGCAGGGAG
AGGCGATACTGCCTCGCATCAGCGTGATCAGCACTGGCCCCACGCTTCAGGCACGAAGGAGGCAGTCTGTCCTGAACCTGATGACA
CACTCAGTTAACCAAGGTCAGAACATTCACCGAAAGACAACAGCATCCACACGAAAAGTGTCACTGGCCCCTCAGGCAAACTTGAC
TGAACTGGATATATATTCAAGAAGGTTATCTCAAGAAACTGGCTTGGAAATAAGTGAAGAAATTAACGAAGAAGACTTAAAGGAGT
GCTTTTTTGATGATATGGAGAGCATACCAGCAGTGACTACATGGAACACATACCTTCGATATATTACTGTCCACAAGAGCTTAATT
TTTGTGCTAATTTGGTGCTTAGTAATTTTTCTGGCAGAGGTGGCTGCTTCTTTGGTTGTGCTGTGGCTCCTTGGAAACACTCCTCT
TCAAGACAAAGGGAATAGTACTCATAGTAGAAATAACAGCTATGCAGTGATTATCACCAGCACCAGTTCGTATTATGTGTTTTACA
TTTACGTGGGAGTAGCCGACACTTTGCTTGCTATGGGATTCTTCAGAGGTCTACCACTGGTGCATACTCTAATCACAGTGTCGAAA
ATTTTACACCACAAAATGTTACATTCTGTTCTTCAAGCACCTATGTCAACCCTCAACACGTTGAAAGCAGGTGGGATTCTTAATAG
ATTCTCCAAAGATATAGCAATTTTGGATGACCTTCTGCCTCTTACCATATTTGACTTCATCCAGTTGTTATTAATTGTGATTGGAG
CTATAGCAGTTGTCGCAGTTTTACAACCCTACATCTTTGTTGCAACAGTGCCAGTGATAGTGGCTTTTATTATGTTGAGAGCATAT
TTCCTCCAAACCTCACAGCAACTCAAACAACTGGAATCTGAAGGCAGGAGTCCAATTTTCACTCATCTTGTTACAAGCTTAAAAGG
ACTATGGACACTTCGTGCCTTCGGACGGCAGCCTTACTTTGAAACTCTGTTCCACAAAGCTCTGAATTTACATACTGCCAACTGGT
TCTTGTACCTGTCAACACTGCGCTGGTTCCAAATGAGAATAGAAATGATTTTTGTCATCTTCTTCATTGCTGTTACCTTCATTTCC
ATTTTAACAACAGGAGAAGGAGAAGGAAGAGTTGGTATTATCCTGACTTTAGCCATGAATATCATGAGTACATTGCAGTGGGCTGT
AAACTCCAGCATAGATGTGGATAGCTTGATGCGATCTGTGAGCCGAGTCTTTAAGTTCATTGACATGCCAACAGAAGGTAAACCTA
CCAAGTCAACCAAACCATACAAGAATGGCCAACTCTCGAAAGTTATGATTATTGAGAATTCACACGTGAAGAAAGATGACATCTGG
CCCTCAGGGGGCCAAATGACTGTCAAAGATCTCACAGCAAAATACACAGAAGGTGGAAATGCCATATTAGAGAACATTTCCTTCTC
AATAAGTCCTGGCCAGAGGGTGGGCCTCTTGGGAAGAACTGGATCAGGGAAGAGTACTTTGTTATCAGCTTTTTTGAGACTACTGA
ACACTGAAGGAGAAATCCAGATCGATGGTGTGTCTTGGGATTCAATAACTTTGCAACAGTGGAGGAAAGCCTTTGGAGTGATACCA
CAGAAAGTATTTATTTTTTCTGGAACATTTAGAAAAAACTTGGATCCCTATGAACAGTGGAGTGATCAAGAAATATGGAAAGTTGC
AGATGAGGTTGGGCTCAGATCTGTGATAGAACAGTTTCCTGGGAAGCTTGACTTTGTCCTTGTGGATGGGGGCTGTGTCCTAAGCC
ATGGCCACAAGCAGTTGATGTGCTTGGCTAGATCTGTTCTCAGTAAGGCGAAGATCTTGCTGCTTGATGAACCCAGTGCTCATTTG
GATCCAGTAACATACCAAATAATTAGAAGAACTCTAAAACAAGCATTTGCTGATTGCACAGTAATTCTCTGTGAACACAGGATAGA
AGCAATGCTGGAATGCCAACAATTTTTGGTCATAGAAGAGAACAAAGTGCGGCAGTACGATTCCATCCAGAAACTGCTGAACGAGA
GGAGCCTCTTCCGGCAAGCCATCAGCCCCTCCGACAGGGTGAAGCTCTTTCCCCACCGGAACTCAAGCAAGTGCAAGTCTAAGCCC
CAGATTGCTGCTCTGAAAGAGGAGACAGAAGAAGAGGTGCAAGATACAAGGCTT
SEQ ID NO: 5 – example recruiting portion
CGCGCGTTTTCGCGCG
SEQ ID NO: 6 – example recruiting portion
AUANUAUAACAAUAUgcuaaAUGUUGUUAUANUAU
SEQ ID NO: 7 – example recruiting portion
UAUAACAAUAUgcuaaAUGUUGUUAUA
SEQ ID NO: 8 – generic targeting portion
NNNNNNNNNNNNNNNNNCNNN
SEQ ID NO: 9
GCAACUAGAGGUGAG
SEQ ID NO: 10
TGCTAAGTACAGGGACATCTTGC
SEQ ID NO: 11
AGACTCCACTTGTTCTTTTAAGGAG
SEQ ID NO: 12
TGACTGCTAAGTACAGGGACATCTTG
SEQ ID NO: 13
AGGAGATGTTTTCACACTCCAGGT
SEQ ID NO: 14
CTGGCCCCAGTTGTAATTTGTGA
SEQ ID NO: 15
CTGTTCCCAGGCTTGTTCAATAGT
SEQ ID NO: 16
GUGUUGGCCAUGGAACAUAUAACAAUAUgcuaaAUGUUGUUAUA
SEQ ID NO: 17
UAUAACAAUAUgcuaaAUGUUGUUAUAGUGUUGGCCAUGGAACA
SEQ ID NO: 18
GUGUUGGCCAUGGAACAUAUAACAAUAUgcuaaAUGUUGUUAUA
SEQ ID NO: 19
GUGUUGGCCAUGGAACAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAU
SEQ ID NO: 20
GGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCGUGUUGGCCAUGGAACA
SEQ ID NO: 21
GUGUUGGCCAUGGAACAGGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCC
SEQ ID NO: 22
GGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCGUGUUGGCCAUGGAACA
SEQ ID NO: 23
GGAAUANUAUAACAAUAUgcuaaAUGUUGUUAUANUAUCCC
SEQ ID NO: 24
GUGGAAUANUAUAACAAUAUgcuaaAUGUUGUUAUANUAUCCCAC
SEQ ID NO: 25
GUGGNAUANUAUAACAAUAUgcuaaAUGUUGUUAUANUAUNCCAC
SEQ ID NO: 26
GCCTGGCACCATTAAAGAAA
SEQ ID NO: 27
GCATCTTTGTATACTGCTCTTGCT
SEQ ID NO: 28
GGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCCAGUCCCUUUCUCGUCGAUGGUCAG
SEQ ID NO: 29
CCATCGACGAGAAAG
SEQ ID NO: 30
CATCGACAAGAAAG
SEQ ID NO: 31
TCCAGGCCGTGCATAAGG
SEQ ID NO: 32
GCCCCAGCAGCTTCAG
SEQ ID NO: 33
ATACCTCCACTCAGCCATGATTATATACCGAGACCTGAAACCCCACAATGTGCTGCTTTTCACACTGTATCCCAATGCTGCCATCA
TTGCAAAGATTGCTGACTACGGCATTGCTCAGTACTGCTGTAGAATGGGGATAAAAACATCAGAGGGCACACCAG
SEQ ID NO: 34
GCTGACTACAGCATTGCTCAG
SEQ ID NO: 35
ADYSIAQ
SEQ ID NO: 36
GCTGACTACGGCATTGCTCAG
SEQ ID NO: 37
ADYGIAQ
SEQ ID NO: 38
GUGGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCACACUGAGCAAUGCcGUAGUCAGCAAU
SEQ ID NO: 39
GUGGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCACGUACUGAGCAAUGCcGUAGUCAGCAAUCUU
SEQ ID NO: 40
GGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCACUGAGCAAUGCcGUAGUCAGCAAU
SEQ ID NO: 41
GGAAUAGUAUAACAAUAUgcuaaAUGUUGUUAUAGUAUCCCGUACUGAGCAAUGCcGUAGUCAGCAAUCUU
SEQ ID NO: 42
GTTTGAGATACCTCCACTCAGC
SEQ ID NO: 43
AGGTGCACGAAACCCTGGTG
Claims (22)
1. An oligonucleotide construct for the site-directed editing of a nucleotide in a target RNA sequence in a eukaryotic cell, said oligonucleotide construct comprising: (a) a targeting portion, comprising an antisense sequence complementary to part 5 of the target RNA; and (b) a recruiting portion capable of forming an intramolecular stem-loop structure, capable of binding and recruiting an RNA editing entity naturally present in said cell and capable of performing the editing of said nucleotide.
2. An oligonucleotide construct according to claim 1, wherein the recruiting portion is not 10 complementary to the target sequence.
3. An oligonucleotide construct according to claim 1 or 2, wherein the targeting portion comprises an oligoribonucleotide sequence that forms a dsRNA structure upon base pairing with the target RNA sequence.
4. An oligonucleotide construct according to any one of claims 1 to 3, wherein the targeting 15 portion comprises a non-complementary nucleotide in a position opposite to the nucleotide to be edited in the target RNA sequence.
5. An oligonucleotide construct according to any one of claims 1 to 4, wherein the nucleotide that is the target for editing is an adenosine or a cytidine, and the RNA editing entity comprises a deaminase activity. 20
6. An oligonucleotide construct according to any one of claims 1 to 5, wherein the nucleotide that is a target for editing is an adenosine and the editing entity is an adenosine deaminase.
7. An oligonucleotide construct according to any one of claims 1 to 6, wherein the cell is a human cell. 25
8. An oligonucleotide construct according to any one of claims 1 to 7, wherein the editing entity comprises hADAR1 or hADAR2.
9. An oligonucleotide construct according to claim 4, wherein the non-complementary nucleotide is a cytidine or a uridine.
10. An oligonucleotide construct according to claim 9, wherein the non-complementary 30 nucleotide is a cytidine.
11. An oligonucleotide construct according to claim any one of claims 1 to 10, wherein the nucleic acid sequence capable of forming an intramolecular stem-loop structure is an oligoribonucleotide (RNA) sequence.
12. An oligonucleotide construct according to claim 11, wherein the recruiting portion N (RY or YR) , comprises a stem-loop structure comprising a sequence (RY or YR) n m n wherein R is adenosine or guanosine, Y is uridine or cytidine, N is adenosine, guanosine, cytidine, uridine, or inosine, n is 3 or more, m is 4 or more and wherein N 5 forms a loop and the two (RY) or (YR) sequences form a double-stranded stem structure through complementary base pairing.
13. An oligonucleotide construct according to claim 11 or 12, wherein the loop is a tetranucleotide or a pentanucleotide having the sequence: GCUMA, wherein G is guanosine, C is cytidine, U is uridine, M is adenosine or cytidine and A is adenosine. 10
14. An oligonucleotide construct according to claim 13, wherein the loop is a tetranucleotide or a pentanucleotide having the sequence GCUAA.
15. An oligonucleotide construct according to claim 1 or 2, wherein the recruiting portion comprises nucleotide sequence: 5'-(AUAN ) UAUAACAAUAUgcuaaAUGUUGUUAUA(N UAU) -3' 15 wherein N and N are each single nucleotides which may be A, G, C or U, with the proviso that N and N form a mismatch base pair upon the formation of a stem-loop structure, and n is 1 or 0.
16. An oligonucleotide construct according to claim 11, wherein the recruiting portion comprises a sequence selected from SEQ ID NOs: 6, 7, 20, 21, 22, 23 and 24. 20
17. An oligonucleotide construct according to claim 11, wherein the loop structure is derived from or mimics the RNA sequence coding for a B-domain of a human GluR protein.
18. An oligonucleotide construct according to claim 1 or 2, wherein the recruiting portion comprises a deoxyoligonucleotide sequence comprising the sequence (CG) T (CG) 3 4 3 (SEQ ID NO: 5), wherein C is cytidine, G is guanosine and T is thymidine. 25
19. An oligonucleotide construct according to any one of claims 1 to 18, wherein one or more of the nucleotides of the oligonucleotide construct comprise a chemical modification.
20. An oligonucleotide construct according to claim 19, wherein the targeting portion of the oligonucleotide construct comprises one or more 2’-O ribosyl substituted uridines. 30
21. An oligonucleotide construct according to claim 19 or 20, wherein the targeting portion of the oligonucleotide construct comprises one or more 2'-OMe substituted uridines.
22. An oligonucleotide construct according to claim 16, wherein all uridines opposite adenosines in the target RNA sequence that are not a target for editing are 2’-methoxy- (2’-OMe) uridine.
Applications Claiming Priority (9)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| GB201422511 | 2014-12-17 | ||
| GB1422511.4 | 2014-12-17 | ||
| GBGB1512467.0A GB201512467D0 (en) | 2015-07-16 | 2015-07-16 | Editing |
| GB1512467.0 | 2015-07-16 | ||
| GB1512595.8 | 2015-07-17 | ||
| GBGB1512595.8A GB201512595D0 (en) | 2015-07-17 | 2015-07-17 | Editing |
| GBGB1521987.6A GB201521987D0 (en) | 2015-12-14 | 2015-12-14 | Editing |
| GB1521987.6 | 2015-12-14 | ||
| PCT/EP2015/080347 WO2016097212A1 (en) | 2014-12-17 | 2015-12-17 | Targeted rna editing |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| NZ732182A NZ732182A (en) | 2021-05-28 |
| NZ732182B2 true NZ732182B2 (en) | 2021-08-31 |
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