ANTISENSE OLIGONUCLEOTIDES FOR RNA EDITING

Abstract

The invention relates to editing oligonucleotides (EONs) that carry 2′-0-methoxyethyl (2′-MOE) ribose modifications at specified positions and that do not carry such modifications on positions that would lower RNA editing efficiency. The selection of positions that should or should not carry a 2′-MOE modification is based on computational modelling that revealed steric clashes between the 2′-MOE modification and mammalian ADAR enzymes.

Description

FIELD OF THE INVENTION

The invention relates to the field of medicine. More in particular, it relates to the field of RNA editing, whereby an RNA molecule in a cell is targeted by an antisense oligonucleotide to specifically correct a mutation in the RNA sequence using endogenous deaminases. More specifically, the invention relates to antisense oligonucleotides that are chemically modified at preferred positions in such a particular specific manner that it increases their RNA editing efficiency.

BACKGROUND OF THE INVENTION

RNA editing is a natural process through which eukaryotic cells alter the sequence of their 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 (A) to inosine (I) conversions and cytidine (C) to uridine (U) conversions, which occur 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 multi-domain protein, comprising a catalytic domain, and 2 to 3 double-stranded RNA recognition domains, depending on the enzyme in question. The recognition domain recognizes a specific double stranded RNA (dsRNA) sequence and/or conformation, whereas the catalytic domain converts an adenosine (A) into inosine (I) 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 an mRNA or pre-mRNA, it can recode the protein sequence. A to I conversions may also occur in 5′ non-coding sequences of a target mRNA, creating new translational start sites upstream of the original start site, which gives rise to N-terminally extended proteins, or in the 3′ UTR or other non-coding parts of the transcript, which may affect the processing and/or stability of the RNA. 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. As a result thereof, exons may be included or skipped. The adenosine deaminases are part of a family of enzymes known as Adenosine Deaminases acting on RNA (ADAR), including human deaminases hADAR1, hADAR2 and hADAR3.

The use of oligonucleotides to edit a target RNA applying adenosine deaminase has been described (e.g. Montiel-Gonzalez et al. PNAS 2013, 110(45):18285-18290; Vogel et al. 2014. Angewandte Chemie Int Ed 53:267-271; Woolf et al. 1995. PNAS 92:8298-8302). Montiel-Gonzalez et al. (2013) described the editing of a target RNA using a genetically engineered fusion protein, comprising an adenosine deaminase domain of the hADAR2 protein fused to a bacteriophage lambda N protein, which recognises the boxB RNA hairpin sequence. The natural dsRNA binding domains of hADAR2 had been removed to eliminate the substrate recognition properties of the natural ADAR and replace it by the boxB recognition domain of lambda N-protein. The authors created an antisense oligonucleotide comprising a ‘guide RNA’ (gRNA) part that is complementary to the target sequence for editing, fused to a boxB portion for sequence specific recognition by the N-domain-deaminase fusion protein. By doing so, it was elegantly shown that the guide RNA oligonucleotide faithfully directed the adenosine deaminase fusion protein to the target site, resulting in guide RNA-directed site-specific A to I editing of the target RNA. These guide RNAs are longer than 50 nucleotides, which is generally too long for therapeutic applications, because of difficulties in manufacturing and limited cell entry. A disadvantage of this method in a therapeutic setting is also the need for a fusion protein consisting of the boxB recognition domain of bacteriophage lambda N-protein, genetically fused to the adenosine deaminase domain of a truncated natural ADAR protein. It requires target cells to be either transduced with the fusion protein, which is a major hurdle, or that target cells are transfected with a nucleic acid construct encoding the engineered adenosine deaminase fusion protein for expression. The latter requirement constitutes no minor obstacle when editing is to be achieved in a multicellular organism, such as in therapy against human disease to correct a genetic disorder.

Vogel et al. (2014) disclosed editing of RNA coding for eCFP and Factor V Leiden, using a benzylguanine substituted guide RNA and a genetically engineered fusion protein, comprising the adenosine deaminase domains of ADAR1 or ADAR2 (lacking the dsRNA binding domains) 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, through its SNAP-tag domain which is covalently linked to a guide RNA through a 5′-terminal O6-benzylguanine modification, this system suffers from similar drawbacks as the genetically engineered ADARs described by Montiel-Gonzalez et al. (2013), 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.

Woolf et al. (1995) disclosed a simpler approach, using relatively long single stranded antisense RNA oligonucleotides (25-52 nucleotides in length) wherein the longer oligonucleotides (34-mer and 52-mer) could promote editing of the target RNA by endogenous ADAR because of the double stranded nature of the target RNA and the oligonucleotide hybridizing thereto. The oligonucleotides of Woolf et al. (1995) that were 100% complementary to the target RNA sequences only appeared to function in cell extracts or in amphibian (Xenopus) oocytes by microinjection, and suffered from severe lack of specificity: nearly all adenosines in the target RNA strand that was complementary to the antisense oligonucleotide were edited. An oligonucleotide, 34 nucleotides in length, wherein each nucleotide carried a 2′-O-methyl modification, was tested and shown to be inactive in Woolf et al. (1995). In order to provide stability against nucleases, a 34-mer RNA, modified with 2′-O-methyl-modified phosphorothioate nucleotides at the 5′- and 3′-terminal 5 nucleotides, was also tested. It was shown that the central unmodified region of this oligonucleotide could promote editing of the target RNA by endogenous ADAR, with the terminal modifications providing protection against exonuclease degradation. Woolf et al. (1995) did not achieve deamination of a specific target adenosine in the target RNA sequence. As mentioned, nearly all adenosines opposite an unmodified nucleotide in the antisense oligonucleotide were edited (therefore nearly all adenosines opposite nucleotides in the central unmodified region, if the 5′- and 3′-terminal 5 nucleotides of the antisense oligonucleotide were modified, or nearly all adenosines in the target RNA strand if no nucleotides were modified).

It is known that ADAR may act on any dsRNA. Through a process sometimes referred to as ‘promiscuous editing’, the enzyme will edit multiple A's in the dsRNA. Hence, there is a need for methods and means that circumvent such promiscuous editing and that only target specified adenosines in a target RNA sequence for therapeutic applicability. Vogel et al. (2014) showed that such off-target editing can be suppressed by using 2′-O-methyl-modified nucleotides in the oligonucleotide at positions opposite to the adenosines that should not be edited, and use a non-modified nucleotide directly opposite to the specifically targeted adenosine on the target RNA. However, the specific editing effect at the target nucleotide has not been shown to take place in that article without the use of recombinant ADAR enzymes that had covalent bonds with the antisense oligonucleotide.

WO 2016/097212 discloses antisense oligonucleotides (AONs) for the targeted editing of RNA, wherein the AONs are characterized by a sequence that is complementary to a target RNA sequence (therein referred to as the ‘targeting portion’) and by the presence of a stem-loop structure (therein referred to as the ‘recruitment portion’), which is preferably non-complementary to the target RNA. Such oligonucleotides are referred to as ‘self-looping AONs’. The recruitment portion acts in recruiting a natural ADAR enzyme present in the cell to the dsRNA formed by hybridization of the target sequence with the targeting portion. Due to the recruitment portion there is no need for conjugated entities or presence of modified recombinant ADAR enzymes. WO 2016/097212 describes the recruitment portion as being a stem-loop structure mimicking either a natural substrate (e.g. the GluB receptor) or a Z-DNA structure known to be recognized by the dsRNA binding regions of ADAR enzymes. A stem-loop structure can be an intermolecular stem-loop structure, formed by two separate nucleic acid strands, or an intramolecular stem loop structure, formed within a single nucleic acid strand. The stem-loop structure of the recruitment portion as described in WO 2016/097212 is an intramolecular stem-loop structure, formed within the AON itself, and able to attract ADAR.

WO 2017/220751 and WO 2018/041973 describe AONs that do not comprise a recruitment portion but that are (almost fully) complementary to the targeted area, except for one or more mismatches, or so-called ‘wobbles’ or bulges. The sole mismatch may be the nucleotide opposite the target adenosine, but in other embodiments AONs are described that have multiple bulges and/or wobbles when attached to the target sequence area. It appeared that it was possible to achieve in vitro, ex vivo and notably, also in vivo RNA editing with AONs lacking a recruitment portion and with endogenous ADAR enzymes when the sequence of the AON was carefully selected such that it could attract ADAR. The nucleotide in the AON directly opposite the target adenosines was described as not carrying a 2′-O-methyl modification. It could also be a DNA nucleotide, wherein the remainder of the AON was carrying 2′-O-alkyl modifications at the sugar entity (such as 2′-O-methyl), or the nucleotides within the so-called ‘Central Triplet’ or directly surrounding the Central Triplet contained particular chemical modifications (or were DNA) that further improved the RNA editing efficiency and/or increased the resistance against nucleases. Such effects could even be further improved when using sense oligonucleotides (SONs) that ‘protect’ the AONs against breakdown (described in WO 2018/134301).

It is further noted that yet another editing technique exists which uses oligonucleotides, known as the CRISPR/Cas9 system. However, this editing complex acts on DNA. It also suffers from the same drawback as the engineered ADAR systems described above, because 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.

Despite the achievements outlined above, there remains a need for new compounds that can utilise endogenous cellular pathways and naturally available ADAR enzymes to more specifically and more efficiently edit endogenous nucleic acids in mammalian cells, even in whole organisms, to alleviate disease.

SUMMARY OF THE INVENTION

The present invention relates to an editing oligonucleotide (EON) capable of forming a double stranded complex with a target RNA molecule in a cell, and capable of recruiting an endogenous enzyme with ADAR activity, wherein the target RNA molecule comprises a target adenosine for deamination by the enzyme with ADAR activity, wherein the EON comprises a Central Triplet of three sequential nucleotides in which the nucleotide directly opposite the target adenosine is the middle nucleotide (position 0) of the Central Triplet and wherein the positions are positively (+) and negatively (−) incremented towards the 5′ and 3′ ends of the EON, respectively, wherein the EON comprises a nucleotide at position 0 that mismatches with the target adenosine, wherein the EON comprises one or more nucleotides comprising a 2′-O-methoxyethyl (2′-MOE) ribose modification, and wherein the EON comprises one or more nucleotides not comprising a 2′-MOE ribose modification, characterized in that the nucleotides comprising a 2′-MOE ribose modification are at positions that do not prevent the enzyme with ADAR activity from deaminating the target adenosine. Preferably, the EON comprises 2′-O-methyl (2′-OMe) ribose modifications at the positions that do not comprise a 2′-MOE ribose modification. In another preferred aspect, the EON comprises deoxynucleotides at positions that do not comprise a 2′-MOE ribose modification. In yet another preferred aspect, the EON comprises one or two deoxynucleotides at positions −1 and/or 0 in the Central Triplet. Also preferred is an EON according to the invention that does not comprise a 2′-MOE modification at position −1 and or 0 in the Central Triplet. In a highly preferred embodiment, the EON does not comprise a 2′-MOE modification at position +6, +1, 0, −1, −2, −3, −4, and/or −5. Preferably, the nucleotide in the EON that is opposite the target adenosine (A) is a cytidine (C).

The inventors of the present invention have, by applying computational modelling, surprisingly found that 2′-MOE modifications at certain positions in the EON cause steric clashes with the ADAR enzyme, which in turn resulted in a lower RNA editing efficiency. EONs that were almost completely modified with 2′-MOE were inactive. However, the inventors found that when certain positions were excluded from 2′-MOE modifications, while other positions did contain the 2′-MOE modification, RNA editing efficiency was increased or at least at the same level in comparison to a positive control that only comprised 2′-OMe modifications. Hence, the inventors were able to pinpoint preferred (and non-preferred) positions for 2′-MOE modifications using computational modelling. This enables now the skilled person to improve the efficacy of the EON in RNA editing, in vivo, using endogenous ADAR enzymes.

The invention also relates to a pharmaceutical composition comprising the EON according to the invention, and a pharmaceutically acceptable carrier. In yet another aspect, the invention relates to an EON according to the invention for use in the treatment or prevention of a genetic disorder. The invention also relates to a method for the deamination of at least one target adenosine present in a target RNA molecule in a cell, the method comprising the steps of providing the cell with an EON according to the invention, allowing uptake by the cell of the EON, allowing annealing of the EON to the target RNA molecule, allowing a mammalian enzyme with ADAR activity to deaminate the target adenosine in the target RNA molecule to an inosine; and optionally identifying the presence of the inosine in the target RNA. In a final aspect, the invention relates to a method of computational modelling of EONs and ADAR enzymes in the context of a target RNA sequence, to trace steric hindrance and clashes to exclude particular chemical modifications in the EON and thereby increase the RNA editing efficiency of the EON in vivo.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows the primary sequence of an EON encompassing the binding region of the ADAR2 deaminase domain. The sequence in this particular instance (5′ to 3′; SEQ ID NO: 1) is complementary to the mouse Idua RNA target. The middle C of the central triplet is arbitrarily referenced as 0, positively (+) and negatively (−) incremented towards the 5′ and 3′ ends of the EON, respectively. Black boxes indicate the positions where 2′-MOE modifications are not tolerated to ensure a correct binding of the ADAR2 deaminase domain. White boxes represent the locations where the insertion of 2′-MOE modifications do not interfere with the EON-ADAR2 deaminase domain interaction.

FIG. 2 shows the target mouse Idua RNA sequence (upper strands; 5′ to 3′; SEQ ID NO: 2) with the complementary oligonucleotide from 3′ to 5′ and again (lower sequences) from 5′ to 3′ with modifications. Asterisks represent phosphorothioate linkages. The target adenosine in the Idua target sequence is in bold. (A) The negative control oligonucleotide CTRL ADAR 65-11 (SEQ ID NO: 3) does not have a ‘mismatch’ between the target adenosine in the target RNA and the opposing nucleotide U in the oligonucleotide, which makes that no editing should occur. This control oligonucleotide is fully complementary to the target sequence. There is a short stretch of three nucleotides that are not 2′-OMe modified (upper case). All lower case nucleotides carry a 2′-OMe modification. (B) The positive control 2′-OMe oligonucleotide ADAR 65-28 (SEQ ID NO: 4) comprises 2′-OMe (here: 2′ 0-Met) modifications in all nucleotides, except for the two upper case DNA nucleotides, and it has one wobble base pair. (C) The Full-MOE oligonucleotide (also SEQ ID NO: 4) comprises 2′-MOE modifications (here: 2′ OMOE) in all nucleotides, except for the DNA nucleotides that are in upper case, and the positions +24, +12, +11, −2, and −3 that all have 2′-OMe modifications (here: 2′ OMet). It also has one wobble base pair. (D) The Part-MOE oligonucleotide (also SEQ ID NO: 4) has 2′-MOE modifications (here: 2′OMOE) at positions −13, −10, −7, −4, +1, +4, +7, +10, +13, +16, +19, +22, +25, +28, +31, +34 and +36. All other positions, except the DNA nucleotides (in upper case), have 2′-OMe modifications (here: 2′OMet). This oligonucleotide also has one wobble base pair.

FIG. 3 shows the target mouse Idua RNA sequence (upper strands; 5′ to 3′; SEQ ID NO: 2) with the complementary oligonucleotide from 3′ to 5′ and again the lower sequences as 5′ to 3′ with modifications. Asterisks represent phosphorothioate linkages. The target adenosine in the Idua target sequence is in bold. (A) ADAR 65-11 is the same control oligonucleotide as in FIG. 2A. (B) The 39 nt positive control 2′-OMe oligonucleotide ADAR 102-1 (SEQ ID NO: 5) comprises 2′-OMe modifications (here: 2′ 0-Met) in all nucleotides, except for the two upper case DNA nucleotides, and has one wobble base pair. (C) The 39 nt Opt-MOE oligonucleotide ADAR 102-2 (also SEQ ID NO: 5) comprises 2′-OMe modifications (here: 2′ OMet) in all nucleotides, except for the DNA nucleotides in upper case, and the positions −6 to −10, and positions +2 to +5, positions +7 to +12 that comprise a 2′-MOE modification (here: 2′ OMOE). This oligonucleotide also has one wobble base pair.

FIG. 4 shows the results of two separate experiments in which RNA editing was determined on a mouse Idua target RNA (encoding the α-L-iduronidase protein, but carrying an early stop codon mutation) using different types of EONs (oligonucleotides of FIG. 2 in the first experiment A, and the oligonucleotides of FIG. 3 in the second experiment B), with and without 2′-OMe and 2′-MOE modifications as outlined in the examples. The bars noted as CTRL, 2′-OMe, Full-MOE and Part-MOE in (A) in the first experiment correspond to an EON that is not compatible with RNA editing, a fully methylated EON (except for the two deoxynucleotides as indicated in FIG. 2), a fully 2′-MOE-modified EON (except for the two deoxynucleotides) and a partially 2′-MOE-modified EON, respectively. The bars noted as CTRL, 2′-OMe and Opt-MOE in (B) in the second experiment correspond to an EON that is not compatible with RNA editing (see (A)), another fully methylated EON (except for the two deoxynucleotides as indicated in FIG. 3) and to the EON for which 2′-MOE modifications have been optimally inserted based on atomic scale modelling as discussed in detail in the examples. The restored α-L-iduronidase enzymatic activity (after EON treatment) has been normalized to the effect of the 2′-OMe oligonucleotide. The restored Idua enzymatic activity after Opt-MOE transfection is increased 2-fold compared to the normalized 2′-OMe EON.

FIG. 5 shows the target mouse Idua RNA sequence (upper strands; 5′ to 3′; SEQ ID NO: 2) with the complementary oligonucleotide twice: from 3′ to 5′ and from 5′ to 3′ with modifications. Asterisks represent phosphorothioate linkages. The target adenosine in the Idua target sequence is in bold. (A) Oligonucleotide ADAR 102-4 (SEQ ID NO: 5) has the same modifications as ADAR 102-1 (FIG. 3B), except that it contains 11 additional phosphorothioate linkages, as indicated. (B) Oligonucleotide ADAR 102-6 (also SEQ ID NO: 5) has the same modifications as ADAR 102-2 (FIG. 3C), except that it contains 11 additional phosphorothioate linkages, as indicated.

FIG. 6 shows the results of experiments in which RNA editing was determined on a mouse Idua target RNA (encoding the α-L-iduronidase protein, but carrying an early stop codon mutation) using the oligonucleotides shown in FIG. 5. In both experiments, the bars refer to samples not treated (NT), or treated with ADAR 102-4 or ADAR 102-6, respectively. (A) The editing efficacy was analysed by digital droplet PCR with specific probes to detect the presence of adenosine in the target position (indicating editing had not taken place) or the presence of guanosine in the same position (indicating editing had taken place). Three independent experiments were performed. The fraction of edited target was calculated in each sample, and the results in each individual experiment normalized to the fraction of edited target with ADAR 102-4. Presented here is the mean of the normalized values from the three experiments, with error bars indicating the standard deviation. (B) The editing efficacy was analysed by measuring the restored α-L-iduronidase enzymatic activity. Similarly to the analysis in (A), the enzymatic activity was normalized in each individual experiment to that achieved with ADAR 102-4. Presented here is the mean of the normalized values from the two experiments, with error bars indicating the standard deviation.

FIG. 7 shows again (see FIGS. 3 and 5) the target mouse Idua RNA sequence (upper strands; 5′ to 3′; SEQ ID NO: 2) with the complementary oligonucleotide twice: from 3′ to 5′ and from 5′ to 3′ with modifications. Asterisks represent phosphorothioate linkages. The target adenosine in the Idua target sequence is in bold. The upper case nucleotides in the EON are deoxynucleotides. The positive control 2′-OMe 35 nt oligonucleotide ADAR 103-1 (SEQ ID NO: 6) is comparable to ADAR 102-1 (see FIG. 3B) but is shorter on the 5′ end. ADAR 103-2 (also 35 nt; also SEQ ID NO: 6) is comparable to ADAR 102-2 (see FIG. 3C) but also shorter on the 5′ end. ADAR 103-8 (also 35 nt; also SEQ ID NO: 6) is comparable to ADAR 103-2, but has additional 2′-MOE modifications towards the 5′ end as indicated. ADAR 102-7 (also 35 nt; SEQ ID NO: 6) is a control EON in the sense that it comprises 2′-MOE and 2′-OMe modifications distributed over the oligonucleotide, without computational optimization.

FIG. 8 shows the percentage of edited target RNA, by ddPCR, over time, using four different editing oligonucleotides carrying a variety of 2′-OMe and 2′-MOE modifications (see FIG. 7). The presence of 2′-MOE modifications at specified positions as determined by the computational modelling as described by the present invention results in similar RNA editing levels in comparison to the full 2′-OMe modified EONs, whereas an EON carrying a 2′-MOE modification every two or three nucleotides (without computational modelling) clearly performs significantly less efficient. This shows that by using computational modelling of the EON at the interface with the ADAR2 deaminase domain is useful for generating more optimal EONs for more efficient RNA editing.

DETAILED DESCRIPTION OF THE INVENTION

There is a constant need for improving the pharmacokinetic properties of editing oligonucleotides (EONs) without negatively affecting editing efficiency of the target adenosine in the target RNA. Many chemical modifications exist in the generation of antisense oligonucleotides, whose properties are incompatible with the desire of designing effective editing oligonucleotides. In the search for better pharmacokinetic properties, the inventors of the present invention found that a 2′-O-methoxyethyl (2′-MOE) modification of the ribose of some, but not all, nucleotides—surprisingly—is compatible with efficient ADAR engagement and editing. Examples of enhanced pharmacokinetic properties are cellular uptake and intracellular trafficking, stability and so on. Whereas the properties of 2′-MOE modifications are known as such, the compatibility thereof with ADAR engagement and deamination was not known. The inventors of the present invention have unravelled the positions inside the oligonucleotide where 2′-MOE is compatible with ADAR and where it is not. This is the subject of the present invention. These findings can, in principle, be used with any form of base editing employing synthetic oligonucleotides involving ADAR or ADAR deaminase domains, be they natural or recombinant, truncated or full length, fused to other proteins or not (e.g. Stafforst and Schneider, 2012, Angew Chem Int 51:11166-11169; Schneider et al. 2014, Nucleic Acids Res 42:e87; Montiel-Gonzalez et al. 2016, Nucleic Acids Res 44:e157).

The present invention relates to an editing oligonucleotide (EON) capable of forming a double stranded complex with a target RNA molecule in a cell, and capable of recruiting an endogenous enzyme with ADAR activity, wherein the target RNA molecule comprises a target adenosine for deamination by the enzyme with ADAR activity, wherein the EON comprises at least one nucleotide carrying a 2′-O-methoxyethyl (2′-MOE) ribose modification at a position that does not prevent the enzyme with ADAR activity from deaminating the target adenosine. Preferably, the EON comprises nucleotides carrying a 2′-O-methyl (2′-OMe) ribose modification at the positions that do not have a 2′-MOE ribose modification. In one preferred aspect, the EON comprises a Central Triplet of three sequential nucleotides, wherein the nucleotide directly opposite the target adenosine is the middle nucleotide and position 0 of the Central Triplet, and wherein the EON comprises one or two deoxynucleotides (DNA) at positions −1 and/or 0 in the Central Triplet, wherein the positions are positively (+) and negatively (−) incremented towards the 5′ and 3′ ends of the EON, respectively. In another preferred aspect, the EON does not comprise a 2′-MOE modification at position −1 and or 0 in the Central Triplet. More preferably, the EON of the invention does not comprise a 2′-MOE modification at position +6, +1, 0, −1, −2, −3, −4, and/or −5. The enzyme with ADAR activity is an enzyme that is capable of deaminating a target adenosine in a double stranded RNA complex into an inosine. Preferably the enzyme with ADAR activity is (human) ADAR1 or ADAR2. Also preferably, the cell is a human cell. In one preferred embodiment, the EON according to the invention is longer than 10, 11, 12, 13, 14, 15, 16 or 17 nucleotides, and preferably the EON is shorter than 100 nucleotides, more preferably shorter than 60 nucleotides.

The invention also relates to a pharmaceutical composition comprising the EON according to the invention, and a pharmaceutically acceptable carrier. Suitable pharmaceutically acceptable carriers are well known to the person skilled in the art. The invention also relates to an EON according to the invention for use in the treatment or prevention of a genetic disorder, preferably selected from the group consisting of: Cystic fibrosis, Hurler Syndrome, alpha-1-antitrypsin (A1AT) deficiency, Parkinson's disease, Alzheimer's disease, albinism, Amyotrophic lateral sclerosis, Asthma, β-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, Glucose-6-phosphate dehydrogenase, Haemophilia, Hereditary Hematochromatosis, Hunter Syndrome, Huntington's disease, 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, 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, Sturge-Weber Syndrome, and cancer. The invention also relates to a use of the EON according to the invention in the manufacture of a medicament for the treatment or prevention of a genetic disorder, preferably selected from the group consisting of: Cystic fibrosis, Hurler Syndrome, alpha-1-antitrypsin (A1AT) deficiency, Parkinson's disease, Alzheimer's disease, albinism, Amyotrophic lateral sclerosis, Asthma, β-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, Glucose-6-phosphate dehydrogenase, Haemophilia, Hereditary Hematochromatosis, Hunter Syndrome, Huntington's disease, 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, 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, Sturge-Weber Syndrome, and cancer.

In yet another embodiment, the invention relates to a method for the deamination of at least one target adenosine present in a target RNA molecule in a cell, the method comprising the steps of providing the cell with an EON according to the invention, allowing uptake by the cell of the EON, allowing annealing of the EON to the target RNA molecule, allowing a mammalian enzyme with ADAR activity to deaminate the target adenosine in the target RNA molecule to an inosine, and optionally identifying the presence of the inosine in the target RNA. Preferably, the presence of the inosine is detected by either (i) sequencing the target RNA sequence, (ii) assessing the presence of a functional, elongated, full length and/or wild type protein when the target adenosine is located in a UGA or UAG stop codon, which is edited to a UGG codon through the deamination, (iii) assessing the presence of a functional, elongated, full length and/or wild type protein when two target adenosines are located in a UAA stop codon, which is edited to a UGG codon through the deamination of both target adenosines, (iv) assessing whether splicing of the pre-mRNA was altered by the deamination; or (v) using a functional read-out, wherein the target RNA after the deamination encodes a functional, full length, elongated and/or wild type protein.

The antisense oligonucleotides (AONs; herein often referred to as editing oligonucleotides, or EONs) of the present invention do preferably not comprise a recruitment portion as described in WO 2016/097212. The EONs of the present invention preferably do not comprise a portion that is capable of forming an intramolecular stem-loop structure. In one embodiment, the present invention relates to EONs that target premature termination stop codons (PTCs) present in the (pre)mRNA to alter the adenosine present in the stop codon to an inosine (read as a G), which in turn then results in read-through during translation and a full length functional protein. In one particular embodiment, the present invention relates to EONs for use in the treatment of cystic fibrosis (CF), and in an even further preferred embodiment, the present invention relates to EONs for use in the treatment of CF wherein PTCs such as the G542X (UGAG), W1282X (UGAA), R553X (UGAG), R1162X (UGAG), Y122X (UAA, both adenosines), W1089X, W846X, and W401X mutations are modified through RNA editing to amino acid encoding codons, and thereby allowing the translation to full length proteins. The teaching of the present invention, the computational modelling of allowable and not-allowable positions regarding mutation, especially 2′-MOE modifications, as outlined below, is applicable for all genetic diseases that may be targeted with EONs and may be treated through RNA editing. It depends on the target sequence, the applicable EON and the context of the ADAR protein to pinpoint preferred and non-preferred positions for modifications, preferably 2′-MOE modifications in the sugar moieties of the EON. This is the first time that it is shown that computational modelling can be applied to find preferred positions within therapeutic EONs that may be or should not be modified with 2′-MOE ribose modifications to increase the RNA editing efficiencies of such EONs.

The present invention relates to an EON for the deamination of a target adenosine in a target RNA, wherein the EON is complementary to a target RNA region comprising the target adenosine, and the EON optionally comprises one or more mismatches, wobbles and/or bulges with the complementary target RNA region; the EON comprises one or more nucleotides with one or more sugar modifications, provided that the nucleotide opposite the target adenosine comprises a ribose with a 2′-OH group, or a deoxyribose with a 2′-H group, and further wherein the EON does not have 2′-MOE modifications at certain positions relative to the nucleotide opposite the target adenosine, and further does have 2′-MOE modifications at other positions within the EON, as further defined herein. The EON does preferably not comprise a portion that is capable of forming an intramolecular stem-loop structure that is capable of binding an ADAR enzyme. The EON does preferably not include a 5′-terminal O6-benzylguanine modification. The EON preferably does not include a 5′-terminal amino modification. The EON preferably is not covalently linked to a SNAP-tag domain. In another preferred embodiment the target RNA is human CFTR. In a more preferred embodiment, the stop codon is a premature termination stop codon in the human CFTR (pre)mRNA and even more preferably selected from the group of stop codon mutations in CFTR consisting of: G542X, W1282X, R553X, R1162X, Y122X, W1089X, W846X, and W401X. More preferably, the splice mutation in human CFTR is selected from the group of consisting of: 621+1G>T and 1717-1G>A. In one aspect, the present invention relates to an EON for use in the treatment of Cystic Fibrosis, wherein the EON enables the deamination of an adenosine present in a PTC present in the CFTR (pre)mRNA and wherein the PTC results in early translation termination that eventually causes the disease.

In yet another aspect, the invention relates to an EON capable of forming a double stranded complex with a target RNA in a cell, for use in the deamination of a target adenosine in a disease-related splice mutation present in the target RNA, wherein the nucleotide in the EON that is opposite the target adenosine does not carry a 2′-O-methyl (2′-OMe) modification; the nucleotide directly 5′ and/or 3′ from the nucleotide opposite the target adenosine carry a sugar modification and/or a base modification to render the EON more stable and/or more effective in RNA editing. In another preferred aspect the nucleotide in the EON opposite the target adenosine is not RNA but DNA, and in an even more preferred aspect, the nucleotide opposite the target adenosine as well as the nucleotide 5′ and/or 3′ of the nucleotide opposite the target adenosine are DNA nucleotides, while the remainder (not DNA) of the nucleotides in the EON are preferably 2′-O-alkyl modified ribonucleotides. When two nucleotides are DNA all others may be RNA and may be 2′-OMe or 2′-MOE modified, whereas in particular aspects the third nucleotide in the triplet opposite the target adenosine may be RNA and non-modified, as long as the nucleotide opposite the target adenosine is not 2′-OMe modified. In one particular aspect the invention relates to an EON for the deamination of a target adenosine present in the target RNA by an enzyme present in the cell (likely an ADAR enzyme), wherein the EON is (partly) complementary to a target RNA region comprising the target adenosine, wherein the nucleotide opposite the target adenosine comprises a deoxyribose with a 2′-H group, wherein the nucleotide 5′ and/or 3′ of the nucleotide opposite the target adenosine also comprises a deoxyribose with a 2′-H group, and the remainder of the EON comprises ribonucleosides, preferably all with 2′-OMe or 2′-MOE modifications. In the case of two sequential adenosines (e.g. in the Y122X mutation: UAA) that need to be edited, it is preferred that the nucleotides in the EON that are opposite the two adenosines do both not carry a 2′-O-methyl modification. In another preferred aspect, the EON according to the invention is not a 17-mer or a 20-mer. In yet another aspect the EON according to the invention is longer than 17 nucleotides, or shorter than 14 nucleotides. In a preferred embodiment, the EON according to the invention comprises 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10 mismatches, wobbles and/or bulges with the complementary target RNA region. Preferably, the nucleotide opposite the target adenosine is a cytidine, a deoxycytidine, a uridine, or a deoxyuridine. When the nucleotide opposite the target adenosine is a cytidine or a deoxycytidine, the EON comprises at least one mismatch with the target RNA molecule. When the nucleotide opposite the target adenosine is a uridine or a deoxyuridine, the EON may be 100% complementary and not have any mismatches, wobbles or bulges in relation to the target RNA. However, in a preferred aspect one or more additional mismatches, wobbles and/or bulges are present between EON and target RNA whether the nucleotide opposite the target adenosine is a cytidine, a deoxycytidine, a uridine, or a deoxyuridine. In another preferred embodiment, the nucleotide directly 5′ and/or 3′ from the nucleotide opposite the target adenosine comprises a ribose with a 2′-OH group, or a deoxyribose with a 2′-H group, or a mixture of these two (triplet consists then of DNA-DNA-DNA; DNA-DNA-RNA; DNA-RNA-DNA; DNA-RNA-RNA; RNA-DNA-DNA; RNA-DNA-RNA; RNA-RNA-DNA; or RNA-RNA-RNA; wherein the middle nucleoside does not have a 2′-O-methyl modification (when RNA) and either or both surrounding nucleosides also do not have a 2′-O-methyl modification). It is then preferred that all other nucleotides in the EON then do have a 2′-O-alkyl group, preferably a 2′-O-methyl group, or a 2′-O-methoxyethyl (2′-MOE) group, or any modification as disclosed herein. The EONs of the present invention preferably comprise at least one phosphorothioate linkage. In a further preferred aspect, the 2, 3, 4, 5, or 6 terminal nucleotides of the 5′ and 3′ terminus of the EON are linked with phosphorothioate linkages. More preferably, the terminal 5 nucleotides at the 5′ and 3′ terminus are linked with phosphorothioate linkages. In one particular embodiment of the present invention, the EON is longer than 10, 11, 12, 13, 14, 15, 16 or 17 nucleotides. Preferably, the EON is shorter than 100 nucleotides, more preferably shorter than 60 nucleotides, and even more preferably, the EON comprises 18 to 70 nucleotides, 18 to 60 nucleotides, or 18 to 50 nucleotides. The invention also relates to a pharmaceutical composition comprising the EON according to the invention, and a pharmaceutically acceptable carrier. The invention also relates to an EON according to the invention for use in the treatment or prevention of a genetic disorder, preferably selected from the group consisting of Cystic fibrosis, Hurler Syndrome, alpha-1-antitrypsin (A1AT) deficiency, Parkinson's disease, Alzheimer's disease, albinism, Amyotrophic lateral sclerosis, Asthma, β-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, Glucose-6-phosphate dehydrogenase, Haemophilia, Hereditary Hematochromatosis, Hunter Syndrome, Huntington's disease, 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, 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, and cancer. In a particularly preferred embodiment, the EONs according to the invention are for use in the treatment of Cystic Fibrosis and used for the deamination of a target adenosine present in a PTC present in the human CFTR (pre)mRNA. In another aspect the invention relates to a use of an EON according to the invention in the manufacture of a medicament for the treatment or prevention of a disease, preferably Cystic Fibrosis. In yet another embodiment of the invention, it relates to a method for the deamination of at least one target adenosine present in a PTC in a target RNA in a cell, the method comprising the steps of providing the cell with an EON according to the invention; allowing uptake by the cell of the EON; allowing annealing of the EON to the target RNA; allowing an ADAR enzyme comprising a natural dsRNA binding domain as found in the wild type enzyme to deaminate the target adenosine in the target RNA to an inosine; and optionally identifying the presence of the inosine in the targeted RNA, preferably wherein the last step comprises sequencing the targeted RNA sequence; assessing the presence of a functional, elongated, full length and/or wild type protein when the target adenosine is located in a UGA or UAG stop codon, which is edited to a UGG codon through the deamination; assessing the presence of a functional, elongated, full length and/or wild type protein when two target adenosines are located in a UAA stop codon, which is edited to a UGG codon through the deamination of both target adenosines; assessing whether splicing of the pre-mRNA was altered by the deamination; or using a functional read-out, wherein the target RNA after the deamination encodes a functional, full length, elongated and/or wild type protein. In one particularly preferred embodiment, the invention relates to an EON or a method according to the invention, wherein the target RNA sequence encodes CFTR (e.g. to edit a G542X, W1282X, R553X, R1162X, Y122X, W1089X, W846X, W401X, 621+1G>T or 1717-1G>A mutation.

It is an important aspect of the invention that the EON comprises one or more nucleotides with one or more sugar modifications. Thereby, a single nucleotide of the EON can have one, or more than one sugar modification. Within the EON, one or more nucleotide(s) can have such sugar modification(s).

It is also an important aspect of the invention that the nucleotide within the EON of the present invention that is opposite to the nucleotide that needs to be edited does not contain a 2′-O-methyl modification (herein often referred to as a 2′-OMe group, or as 2′-O-methylation) and preferably comprises a 2′-OH group, or is a deoxyribose with a 2′-H group. It is preferred that the nucleotides that are directly 3′ and/or 5′ of this nucleotide (the ‘neighbouring nucleotides’) also lack such a chemical modification, although it is believed that it is tolerated that one of these neighbouring nucleotides may contain a 2′-O-alkyl group (such as a 2′-O-methyl group), but preferably not both. Either one, or both neighbouring nucleotides may be 2′-OH or a compatible substitution (as defined herein).

Preferably the EON of the present invention does not have a portion that is complementary to the target RNA or the RNA region that comprises the target adenosine that allows the EON in itself to fold into an intramolecular hairpin or other type of (stem) loop structure (herein also referred to as “auto-looping” or “self-looping”), and which may potentially act as a structure that sequesters ADAR. In one aspect, the single stranded EON of the present invention is fully complementary with the target RNA, although it preferably does not perfectly pair on at least one position, which is at the position of the target adenosine, where the opposite nucleoside is then preferably a cytidine. The single-stranded RNA editing oligonucleotides of the present invention may also have one or more mismatches, wobbles or bulges (no opposite nucleoside) with the target sequence, at other positions than at the target adenosine position. These wobbles, mismatches and/or bulges of the EON of the present invention with the target sequence do not prevent hybridization of the oligonucleotide to the target RNA sequence, but add to the RNA editing efficiency by the ADAR present in the cell, at the target adenosine position. The person skilled in the art is able to determine whether hybridization under physiological conditions still does take place. In contrast to the prior art, the EON of the present invention uses a mammalian ADAR enzyme present in the cell, wherein the ADAR enzyme comprises its natural dsRNA binding domain as found in the wild type enzyme. The EONs according to the present invention can utilise endogenous cellular pathways and naturally available ADAR enzyme, or enzymes with ADAR activity (which may be yet unidentified ADAR-like enzymes) to specifically edit a target adenosine in a target RNA sequence. The person skilled in the art is, based on the increasing knowledge and what has been shown on RNA editing in the prior art, very capable to check whether a certain EON with certain specified modifications, which is—according to the present invention—often a mixture of nucleotides either carrying a 2′-OMe or a 2′-MOE ribose modification, is able to more efficiently give RNA editing in comparison to an EON that solely carries 2′-OMe ribose modifications. As disclosed herein, the single-stranded RNA editing-inducing oligonucleotides of the invention are capable of deamination of a specific target adenosine nucleotide in a target RNA sequence. Ideally, only one adenosine is deaminated. Alternatively 1, 2, or 3 adenosine nucleotides are deaminated, but preferably only one. Taking the features of the EONs of the present invention together, there is no need for modified recombinant ADAR expression, there is no need for conjugated entities attached to the EON, or the presence of long recruitment portions that are not complementary to the target RNA sequence. Besides that, the EON of the present invention does allow for the specific deamination of a target adenosine present in the target RNA molecule to an inosine by a natural ADAR enzyme comprising a natural dsRNA binding domain as found in the wild type enzyme, without the risk of promiscuous editing elsewhere in the RNA/EON complex.

Analysis of natural targets of ADAR enzymes indicated that these generally include mismatches between the two strands that form the RNA helix edited by ADAR1 or ADAR2. It has been suggested that these mismatches enhance the specificity of the editing reaction (Stefl et al. 2006. Structure 14(2):345-355; Tian et al. 2011. Nucleic Acids Res 39(13):5669-5681). Characterization of optimal patterns of paired/mismatched nucleotides between the EONs and the target RNA also appears crucial for development of efficient ADAR-based EON therapy. An improved feature of the EONs of the present invention is the use of specific nucleotide modifications at predefined spots to ensure stability as well as proper ADAR binding and activity. These changes may vary and may include modifications in the backbone of the EON, in the sugar moiety of the nucleotides as well as in the nucleobases. They may also be variably distributed throughout the sequence of the EON, depending on the target and on secondary structures. Specific chemical modifications may be needed to support interactions of different amino acid residues within the RNA-binding domains of ADAR enzymes, as well as those in the deaminase domain. For example, phosphorothioate linkages between nucleotides, and/or 2′-O-methyl modifications may be tolerated in some parts of the EON, while in other parts they should be avoided so as not to disrupt crucial interactions of the enzyme with the phosphate and/or 2′-OH groups. Part of these design rules are guided by the published structures of ADAR2, while others have to be defined empirically. Different preferences may exist for ADAR1 and ADAR2. The modifications should also be selected such that they prevent degradation of the EONs. Specific nucleotide modifications may also be necessary to enhance the editing activity on substrate RNAs where the target sequence is not optimal for ADAR editing. Previous work has established that certain sequence contexts are more amenable to editing. For example, the target sequence 5′-UAG-3′ (with the target A in the middle) contains the most preferred nearest-neighbor nucleotides for ADAR2, whereas a 5′-CAA-3′ target sequence is disfavored (Schneider et al. 2014. Nucleic Acids Res 42(10):e87). The recent structural analysis of ADAR2 deaminase domain hints at the possibility of enhancing editing by careful selection of the nucleotides that are opposite to the target trinucleotide. For example, the 5′-CAA-3′ target sequence, paired to a 3′-GCU-5′ sequence on the opposing strand (with the A-C mismatch formed in the middle in this triplet), is disfavored because the guanosine base sterically clashes with an amino acid side chain of ADAR2. However, here it is postulated that a smaller nucleobase, such as inosine, could potentially fit better into this position without causing steric clashes, while still retaining the base-pairing potential to the opposing cytidine. Modifications that could enhance activity of suboptimal sequences include the use of backbone modifications that increase the flexibility of the EON or, conversely, force it into a conformation that favors editing.

Definitions of Terms as Used Herein

The terms ‘adenine’, ‘guanine’, ‘cytosine’, ‘thymine’, ‘uracil’ and ‘hypoxanthine’ (the nucleobase in inosine) as used herein refer to the nucleobases as such.

The terms ‘adenosine’, ‘guanosine’, ‘cytidine’, ‘thymidine’, ‘uridine’ and ‘inosine’, refer to the nucleobases linked to the (deoxy)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. The terms ‘ribonucleoside’ and ‘deoxyribonucleoside’, or ‘ribose’ and ‘deoxyribose’ are as used in the art.

Whenever reference is made to an ‘oligonucleotide’, both oligoribonucleotides and deoxyoligoribonucleotides 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 ‘deoxyoligoribonucleotide’ it may comprise the bases A, G, C, T or I. In a preferred aspect, the EON of the present invention is an oligoribonucleotide that may comprise chemical modifications, and may include deoxynucleotides (DNA) at certain specified positions.

Whenever reference is made to nucleotides in the oligonucleotide construct, such as cytosine, 5-methylcytosine, 5-hydroxymethylcytosine and β-D-Glucosyl-5-hydroxy-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 “complementary” as used herein refers to the fact that the AON (or EON as it is often referred to herein) hybridizes under physiological conditions to the target sequence. The term does not mean that each and every nucleotide in the AON has a perfect pairing with its opposite nucleotide in the target sequence. In other words, while an AON may be complementary to a target sequence, there may be mismatches, wobbles and/or bulges between AON and the target sequence, while under physiological conditions that AON still hybridizes to the target sequence such that the cellular RNA editing enzymes can edit the target adenosine. The term “substantially complementary” therefore also means that in spite of the presence of the mismatches, wobbles, and/or bulges, the AON has enough matching nucleotides between AON and target sequence that under physiological conditions the AON hybridizes to the target RNA. As shown herein, an AON may be complementary, but may also comprise one or more mismatches, wobbles and/or bulges with the target sequence, as long as under physiological conditions the AON is able to hybridize to its target.

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.

The term ‘mismatch’ is used herein to refer to opposing nucleotides in a double stranded RNA complex which do not form perfect base pairs according to the Watson-Crick base pairing rules. Mismatched nucleotides are G-A, C-A, U-C, A-A, G-G, C-C, U-U pairs. In some embodiments EONs of the present invention comprise fewer than four mismatches, for example 0, 1 or 2 mismatches. Wobble base pairs are: G-U, I-U, I-A, and I-C base pairs.

The term ‘splice mutation’ relates to a mutation in a gene that encodes for a pre-mRNA, wherein the splicing machinery is dysfunctional in the sense that splicing of introns from exons is disturbed and due to the aberrant splicing the subsequent translation is out of frame resulting in premature termination of the encoded protein. Often such shortened proteins are degraded rapidly and do not have any functional activity, as discussed herein. In a preferred aspect, the splice mutations that are targeted by the EONs and through the methods of the present invention are present in the human CFTR gene, more preferably the splice mutations 621+1G>T and 1717-1G>A. The exact mutation does not have to be the target for the RNA editing; it may be that (for instance in the case of 621+1G>T) a neighbouring or nearby adenosine in the splice mutation is the target nucleotide, which conversion to I fixes the splice mutation back to a normal state. The skilled person is aware of methods to determine whether or not normal splicing is restored, after RNA editing of the adenosine within the splice mutation site or area.

An EON according to the present invention may be chemically modified almost in its entirety, for example by providing nucleotides with a 2′-O-methylated sugar moiety (2′-OMe) and/or with a 2′-O-methoxyethyl sugar moiety (2′-MOE). However, the nucleotide opposite the target adenosine does not comprise the 2′-OMe modification, and in yet a further preferred aspect, at least one and in a preferred aspect both the two neighbouring nucleotides flanking each nucleotide opposing the target adenosine further do not comprise a 2′-OMe modification. Complete modification, wherein all nucleotides within the EON holds a 2′-OMe modification results in a non-functional oligonucleotide as far as RNA editing goes, presumably because it hinders the ADAR activity at the targeted position. 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 also able to reduce editing of the opposing adenosine.

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. In a preferred aspect the EONs of the present invention have one, two, three, four or more phosphorothioate linkages between the most terminal nucleotides of the EON (hence, preferably at both the 5′ and 3′ end), which means that in the case of four phosphorothioate linkages, the ultimate five nucleotides are linked accordingly. It will be understood by the skilled person that the number of such linkages may vary on each end, depending on the target sequence, or based on other aspects, such as toxicity.

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.

The EON 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. In one embodiment the EON according to the invention is longer than 20 nucleotides. The oligonucleotide according to the invention is preferably shorter than 100 nucleotides, still more preferably shorter than 60 nucleotides. In one embodiment the EON according to the invention is shorter than 50 nucleotides. In a preferred aspect, the oligonucleotide according to the invention comprises 18 to 70 nucleotides, more preferably comprises 18 to 60 nucleotides, and even more preferably comprises 18 to 50 nucleotides. Hence, in a most preferred aspect, the oligonucleotide of the present invention comprises 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49 or 50 nucleotides.

It is known in the art, that RNA editing entities (such as human ADAR enzymes) 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 and 2 can be increased by introducing chemical modifications and/or ensuring a number of mismatches in the dsRNA, which presumably help to position the dsRNA binding domains in a way that has not been clearly defined yet. Additionally, the deamination reaction itself can be enhanced by providing an EON that comprises a mismatch opposite the adenosine to be edited. The mismatch is preferably created by providing a targeting portion having a cytidine opposite the adenosine to be edited. As an alternative, also uridines may be used opposite the adenosine, which, understandably, will not result in a ‘mismatch’ because U and A pair. 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. Also this on/off rate is important because the targeting oligonucleotide should not be too tightly bound to the target RNA.

The desired level of specificity of editing the target RNA sequence may depend from target to target. Following the instructions in the present patent application, those of skill in the art will be capable of designing the complementary portion of the oligonucleotide according to their needs, and, with some trial and error, obtain the desired result.

The oligonucleotide 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.

To prevent undesired editing of adenosines in the target RNA sequence in the region of overlap with the oligonucleotide construct, the oligonucleotide 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). Hence, by including 2′-O-methyl (2′-OMe) nucleotides in desired position of the oligonucleotide construct, the specificity of editing is dramatically improved. Other 2′-0 substitutions of the ribosyl moiety, such as 2′-O-methoxyethyl (2′-MOE) and 2′-O-dimethylallyl groups may also reduce unwanted editing of the corresponding (opposite) adenosine in the target RNA sequence. All these modifications may be applied in the oligonucleotides of the present invention. Other chemical modifications are also readily available to the person having ordinary skill in the art of oligonucleotide synthesis and design. The synthesis of such chemically modified oligonucleotides and testing them in methods according to the invention does not pose an undue burden and other modifications are encompassed by the present invention.

RNA editing molecules present in the cell will usually be proteinaceous in nature, such as the ADAR enzymes found in metazoans, including mammals. Preferably, the cellular editing entity is an enzyme, more preferably an adenosine deaminase or a cytidine deaminase, still more preferably an adenosine deaminase. These are enzymes with ADAR activity. 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. 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 oligonucleotides 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.

Examples of chemical modifications in the EONs of the present invention 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′-0 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 internucleosidic 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.

In case the dsRNA complex recruits ADAR enzymes to deaminate an A to I in the target RNA sequence, the base-pair, mismatch, bulge or wobble between the adenosine to be edited and the opposite nucleotide may comprise an adenosine, a guanine, a uridine or a cytidine residue, but preferably a cytidine residue. Except for the potential mismatch opposite the editing site (when no uridine is applied), the remaining portion of the EON may be perfectly complementary to the target RNA. However, as shown herein, in certain aspects the invention relates to EONs that comprise a limited number of imperfect matches. 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 oligonucleotides according to the invention for the recognition domain of the editing molecule. The exact modification may be determined through some trial and error and/or through computational methods based on structural interactions between the oligonucleotide and the recognition domain of the editing molecule.

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. This is something to be determined by the experimenter (in vitro) or the clinician, usually in phase I and/or II clinical trials.

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, for instance when the human subject suffers from Cystic Fibrosis. Such cells include but are not limited to epithelial cells of the lung. 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. 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.

Without wishing to be bound be theory, the RNA editing through hADAR1 and hADAR2 is thought to take place on primary transcripts in the nucleus, during transcription or splicing, or in the cytoplasm, where e.g. mature mRNA, miRNA or ncRNA can be edited. Different isoforms of the editing enzymes are known to localize differentially, e.g. with hADAR1 p110 found mostly in the nucleus, and hADAR1 p150 in the cytoplasm. The RNA editing by cytidine deaminases is thought to take place on the mRNA level.

The invention is used to make a change in a target RNA sequence in a eukaryotic cell through the use of an oligonucleotide 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, converting adenosines into inosines. The target RNA sequence may comprise a mutation that one may wish to correct or alter, such as a point mutation (a transition or a transversion). The target RNA may be any cellular or viral RNA sequence, but is more usually a pre-mRNA or an mRNA with a protein coding function.

Many 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 a codon giving rise to a functional, full length and/or wild type protein, especially when it concerns PTCs. 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. Especially preferred is Cystic Fibrosis, and more specifically the RNA editing of adenosines in the disease-inducing PTCs in CFTR RNA is preferred. Those skilled in the art of CF mutations recognise that between 1000 and 2000 mutations are known in the CFTR gene, including G542X, W1282X, R553X, R1162X, Y122X, W1089X, W846X, W401X, 621+1G>T or 1717-1G>A.

The target sequence is endogenous to the eukaryotic, preferably mammalian, more preferably human cell.

The amount of oligonucleotide to be administered, the dosage and the dosing regimen 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.

Oligonucleotides of the invention are particularly suitable for therapeutic use, and so the invention provides a pharmaceutical composition comprising an oligonucleotide 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 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.

The invention also relates to a method for the deamination of at least one specific target adenosine present in a target RNA sequence in a cell, the method comprising the steps of: providing the cell with an EON according to the invention; allowing uptake by the cell of the EON; allowing annealing of the EON to the target RNA sequence; allowing a mammalian ADAR enzyme comprising a natural dsRNA binding domain as found in the wild type enzyme to deaminate the target adenosine in the target RNA sequence to an inosine; and optionally identifying the presence of the inosine in the RNA sequence.

Introduction of the EON according to the present invention into the cell is performed by general methods known to the person skilled in the art. After deamination the read-out of the effect (alteration of the target RNA sequence) can be monitored through different ways. Hence, the identification step of whether the desired deamination of the target adenosine has indeed taken place depends generally on the position of the target adenosine in the target RNA sequence, and the effect that is incurred by the presence of the adenosine (point mutation, early stop codon). Hence, in a preferred aspect, depending on the ultimate deamination effect of A to I conversion, the identification step comprises: sequencing the target RNA; assessing the presence of a functional, elongated, full length and/or wild type protein; assessing whether splicing of the pre-mRNA was altered by the deamination; or using a functional read-out, wherein the target RNA after the deamination encodes a functional, full length, elongated and/or wild type protein. In the event that there is a UAA stop codon it means that both adenosines need to be deaminated. Hence, the invention also relates to oligonucleotides and methods wherein two adenosines that are next to each other are co-deaminated by an RNA editing enzyme such as ADAR. In this particular case, the UAA stop codon is converted into a UGG Trp-encoding codon. Because the deamination of the adenosine to an inosine may result in a protein that is no longer suffering from the mutated A at the target position, the identification of the deamination into inosine may also be a functional read-out, for instance an assessment on whether a functional protein is present, or even the assessment that a disease that is caused by the presence of the adenosine is (partly) reversed. The functional assessment for each of the diseases mentioned herein will generally be according to methods known to the skilled person. A very suitable manner to identify the presence of an inosine after deamination of the target adenosine is of course RT-PCR and sequencing, using methods that are well-known to the person skilled in the art.

The oligonucleotide according to the invention is 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, 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.

In some embodiments the oligonucleotide construct can be delivered systemically, but it is more typical to deliver an oligonucleotide 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. It is 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. 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 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 according to the invention.

EXAMPLES

Example 1: Design of Single-Stranded Antisense Editing Oligonucleotides Based on Computational Modeling

The inventors of the present invention envisioned that modeling data could possibly support the identification of structural features that could be incorporated into editing oligonucleotides (EONs) to improve (or to increase the efficiency of) editing of target RNA. The suboptimal sequence context was addressed by chemically modifying the nucleotides of the EONs so as to avoid steric hindrances with ADAR, and even to provide a more efficient recruitment of the protein. To guide this process, the existing RNA-bound ADAR2 structures were used as a starting point (the structural template). The published structure of the ADAR2 deaminase domain in interaction with a double-stranded RNA (Matthews et al., Nature Structural and Molecular Biology, 2016) was analysed and a network of intra and intermolecular distances required for new structure calculations was generated. For the intra and intermolecular distance values, upper limits were defined. For intramolecular distances, upper limits correspond to distances observed in the RNA-bound ADAR2 deaminase X-ray structure. For intermolecular distances, upper limits were set between 1 to 3 Å above the observed distances allowing side-chains adaptation in the binding interface. For secondary structure elements of the ADAR2 deaminase domain, upper and lower distance limits were inserted to characterize the hydrogen-bonds network classically detected in α-helices and β-sheets. Dihedral angle constraints were derived from the published structure. This approach is based on standard methods used to solve protein-RNA structures in solution (Nuclear Magnetic Resonance Spectroscopy) that are known to the person skilled in the art, and integrates torsion angle as well as molecular dynamics steps. Structures of the ADAR2 deaminase domain bound to functionally optimized EONs were calculated with CYANA3.97 (Herrmann et al., J Mol Biol, 2002) and selected atomic models were refined with the SANDER module of AMBER16 (Case D. A. et al., J Comput Chem, 2005) by simulated annealing in implicit water using the ff99SB force field. In silico, a double-stranded RNA complex composed of EONs annealed to the Idua RNA target was used. This protocol enabled the investigation of the atomic details of the interaction between the protein side-chains and the double-stranded RNA-EON helix. The interaction was modulated by chemical modifications of the oxygen-phosphate backbone of the EON.

2′-MOEs are well referenced and highly relevant RNA modifications for therapeutically optimized oligonucleotides, as outlined herein. In this context, a series of structural calculations was performed including punctual 2′-MOE modifications in a 25 nt-long region embedding the deaminase domain binding site. For each nucleotide from the 3′ to the 5′ end of the EON, 200 RNA-bound deaminase domain ADAR2 structures were calculated and the 20 lowest energy ones were selected. In each of the 20 lowest energy structure, it was determined whether the relative position of the 2′-MOE modification could generate steric clashes with the amino acids side-chains of the ADAR2 deaminase domain. In total 5000 structures were calculated and the 500 most energetically favourable ones were screened for potential steric clashes. With this approach, relevant atomic scale pictures were obtained of the conformational space explored by the 2′-MOE groups covalently bound to the sugar. Within the protein-EON binding interface, all positions prone to create steric clashes with the surrounding protein side-chains were detected. Following this novel modelling approach for therapeutic oligonucleotides design, it was concluded that specific positions within EONs bound to their RNA target do not tolerate 2′-MOE modifications because of their propensity to alter the interaction with the ADAR2 deaminase domain (FIG. 1).

Example 2: Use of in Silico Modelled EONs in RNA Editing

As outlined above, a pattern of allowable and non-allowable 2′-MOE modifications was determined and to further substantiate this in an RNA editing experiment, an enzymatic assay was performed to validate the method experimentally. The procedure of these Hurler syndrome model experiments was as described in WO 2017/220751. In a first experiment, a number of EONs carrying modifications at various positions were tested. In a second experiment, 2′-MOE modifications were integrated at specific positions in the EONs in agreement with the atomic scale modelling results as outlined in example 1. After transfection of the oligonucleotides in MEF cells overexpressing an altered Idua gene with a premature termination codon (W392X), the α-L-iduronidase (the protein encoded by the Idua gene) enzymatic activity was quantified relative to multiple controls. Binding of EONs to their RNA target and subsequent editing by ADAR should restore the enzyme function.

The oligonucleotides as shown in FIG. 2 were tested in the first experiment:

• • The first oligonucleotide (CTRL), also referred to as ADAR 65-11 (see FIG. 2A), was an oligonucleotide that is not compatible with RNA editing, and which served as a negative control;
  • The second oligonucleotide (2′-OMe), also referred to as ADAR 65-28, was an EON carrying 2′-O-methyl modifications at all positions except at the two deoxynucleotides (DNA) near the catalytic site as indicated in FIG. 2B, and which served as a positive control;
  • The third oligonucleotide (Full-MOE) was an EON with almost all 2′-OMe groups replaced with 2′-MOE, except for a few intermediate positions (that are 2′-OMe modified) and two deoxynucleotides near the catalytic site as indicated in FIG. 2C; and
  • The fourth oligonucleotide (Part-MOE) was an EON with an alternating pattern of 2′-OMe and 2′-MOE-modified nucleotides, as indicated in FIG. 2D.The oligonucleotides as shown in FIG. 3 were tested in the second experiment:
  • The first oligonucleotide (CTRL), also referred to as ADAR 65-11 (see FIGS. 2A and 3A), was an oligonucleotide that is not compatible with RNA editing, and which served as a negative control;
  • The second oligonucleotide (2′-OMe), also referred to as ADAR 102-1, was an EON carrying 2′-O-methyl modifications at all positions except at the two deoxynucleotides (DNA) near the catalytic site as indicated in FIG. 3B, and which served as a positive control;
  • The third oligonucleotide (Opt-MOE), also referred to as ADAR 102-2, was an EON with 2′-MOE modifications at positions that would not result in steric clashes with the surrounding protein side-chains as calculated upon modelling as outlined in example 1. The remainder of the EON contained 2′-OMe modifications except for the two deoxynucleotides near the catalytic site as indicated in FIG. 3C.

Results of the first experiment are shown in FIG. 4A. The best performing EON was the one with an almost full 2′-OMe modification pattern (2′-OMe; ADAR 65-28), whereas an oligonucleotide with almost full 2′-MOE modifications (Full-MOE) and an oligonucleotide that was modified with alternating 2′-OMe and 2′-MOE modifications (Part-MOE) hardly performed over background levels (as it was detected with the CTRL oligonucleotide).

Results of the second (similar) experiment are shown in FIG. 4B. The same negative CTRL oligonucleotide as tested in the first experiment was tested together with another fully 2′-OMe modified EON (2′-OMe; ADAR 102-1), which again served as a positive control, and compared to an optimized 2′-MOE modified EON (Opt-MOE; ADAR 102-2) in which the 2′-MOE modifications were present only at allowable positions, following the computer-based modelling as outlined above. In this particular EON, certain positions in the sequence were specifically excluded for a 2′-MOE modification, namely nucleotides +6, +1, 0, −1, −2, −3, −4, −5, according to the numbering reported in FIG. 1. Results display a significant improvement of enzymatic activity correlated to editing efficiency using the Opt-MOE EON. It exhibits a 2-fold and a 10-fold enzymatic activity improvement relative to the normalized activities of the oligonucleotides with no 2′-MOE (2′-OMe oligonucleotide) and with almost complete 2′-MOE substitution (Full-MOE oligonucleotide), respectively. Also, 10-fold improvement is detected compared to the partially 2′-MOE modified EON (Part-MOE oligonucleotide). These results demonstrate that the atomic scale computational approach as applied by the inventors of the present invention works for the optimization and the development of chemically optimized EONs.

Example 3: Use of EONs Combining Additional Phosphorothioate Linkages with Patterns of in Silico Modelled Ribose 2′ Modifications

To further establish whether the pattern of allowable 2′-MOE modifications was also compatible with editing when combined with other EON backbone modifications, EONs with increased number of phosphorothioate (PS) linkages were tested by transfections into MEF cells using the same experimental setup as in example 2. Cells not treated (NT) with EONs were used as the negative control. The oligonucleotides as shown in FIG. 5 were tested in the second experiment:

• • The first oligonucleotide (ADAR 102-4), carrying the same pattern of 2′-O-methyl modifications and deoxynucleotides (DNA) as EON 102-1 (Example 2) but with additional PS linkages as indicated in FIG. 5A, and which served as a positive control;
  • The second oligonucleotide (ADAR 102-6), carrying the same pattern of 2′-O-methyl and 2′-MOE modifications and deoxynucleotides (DNA) as EON 102-2 (Example 2) but with additional PS linkages as indicated in FIG. 5A.

The effect of editing was analysed by two methods. Firstly, by digital droplet PCR (ddPCR) with specific probes to detect the presence of adenosine in the target position in the Idua RNA (indicating editing had not taken place) or the presence of guanosine in the same position (indicating editing had taken place). Secondly, the effect of editing was analysed by measuring the restored α-L-iduronidase enzymatic activity as described in example 2.

The fraction of edited RNA was quantified by ddPCR using BioRad's QX-200 Droplet Digital PCR system. 1 μl of cDNA obtained from the reverse transcriptase reaction (1/4000 diluted) was used in a total mixture of 20 μl of reaction mix, including the ddPCR Supermix for Probes no dUTP (BioRad), a Taqman SNP genotype assay with the relevant forward and reverse primers combined with the following gene-specific probes:

Fw Primer:
(SEQ ID NO: 7)
5′-CTCACAGTCATGGGGCTC-3′
Rv Primer:
(SEQ ID NO: 8)
5′-CACTGTATGATTGCTGTCCAAC-3′
FAM probe (wild type):
(SEQ ID NO: 9)
5′-AGAACAACTCTGGGCAGAGGTCTCA-3′
HEX probe (Mutant):
(SEQ ID NO: 10)
5′-AGAACAACTCTAGGCAGAGGTCTCA-3′

A total volume of 20 μl PCR mix including cDNA was filled in the middle row of a ddPCR cartridge using a multichannel pipette. The replicates were divided by two cartridges. The bottom rows were filled with 70 μl of droplet generation oil for probes. After the rubber gasket replacement droplets were generated in the QX200 droplet generator. 40 μl of oil emulsion from the top row of the cartridge was transferred to a 96-wells PCR plate. The PCR plate was sealed with a tin foil for 4 sec at 170° C. using the PX1 plate sealer and directly followed by the following PCR program: 1 cycle of enzyme activation for 10 min at 95° C., 40 cycles denaturation for 30 sec at 95° C. and annealing/extension for 1 min at 63.8° C., 1 cycle of enzyme deactivation for 10 min at 98° C., followed by a storage at 8° C. After the PCR program the plate was read out and analyzed with the QX200 droplet reader with the following settings: Absolute quantification, Supermix for probes no dUTP, Ch1 FAM Wildtype and CH2 HEX mutant. Nonlinear regression was used for data analysis and generation of fitted curve, with an exponential function where the fraction of edited RNA, F, is a function of time, F0 is the maximum edited fraction of RNA and K_obs is the observed rate constant: F(t)=F0*[1−exp(−K_obs*t)]. Reported error bars indicate standard deviations from two independent experiments.

The results shown in FIG. 6 indicate that both EONs increase the Idua editing efficacy observed with the ddPCR (FIG. 6A) and the resulting α-L-iduronidase enzymatic activity (FIG. 6B) above the background level observed with the non-treated (NT) sample in each experiment. Additionally, treatment with the EON containing the computationally defined pattern of 2′-MOE modifications (ADAR 102-6) resulted in, on average, 2.9-fold more edited target sites than treatment with the EON with no 2′-MOE modifications (ADAR 102-4) as analysed by ddPCR, and on average 1.9-fold higher α-L-iduronidase enzymatic activity. While considerable variation was observed in the results, as indicated by the standard deviations, the results are consistent with those presented in example 2, indicating that the computationally modelled pattern of 2′-MOE is at least compatible with ADAR-mediated A-to-I editing as the EON with 2′-OMe in the corresponding positions, even in the presence of additional PS linkages in the positions tested here. Since it is known that 2′-MOE modifications may contribute to cell entry, stability and thereby increased RNA editing efficiency in an in vivo setting, the modelled 2′-MOE positions are a useful improvement over the original 2′-OMe modifications used before.

Example 4: Compatibility of Computationally-Designed 2′-MOE-Modified EONs with RNA Editing In Vitro

The compatibility between RNA editing and the specifically 2′-MOE-modified EONs designed with the structure-based computational approach as described herein was investigated in vitro with purified components. For this, a synthetic Hurler target RNA molecule (61 nucleotides, SEQ ID NO: 2), a set of 35 nt-long editing oligonucleotides (FIG. 7) and the human full-length ADAR2 protein (produced and purified by Genscript; primary sequence UniProtKB-P78563) were used. Four different oligonucleotides with various combinations of 2′-OMe and 2′-MOE modifications were tested for their ability to restore the wild type RNA sequence through A-to-I conversion.

The control EON ADAR 103-1 does not carry 2′-MOE modifications. For ADAR 103-2, the 2′-MOE modifications were inserted according to the pattern defined with the structure-based computational approach as described herein, e.g. screening for the tolerability of 2′-MOEs at the binding interface. The ADAR 103-8 EON also respects the computationally-based pattern but without 2′-MOE modifications at positions +11 and +12. In addition, 2′-MOE modifications were introduced in the 5′ region of this EON (between position +13 and +24). With ADAR 102-7, 2′-MOE modifications were inserted, when possible, every 3 nucleotides without considering that specific positions in the sequence could generate steric hindrances.

Experiments with EONs were performed under single-turnover conditions with saturating full length hADAR2 at 5 nM and 2 nM concentration of duplex RNA (target RNA:EON ratio 1:3). Target RNA/EON mixtures were heated at 95° C. and slowly cooled down (30 min) to room temperature in order to favour intermolecular interactions. Annealing buffer was 5 mM Tris-Cl pH 7.4, 0.5 mM EDTA, 50 mM NaCl. The formed duplex RNA was mixed with 100 ng/μl yeast tRNA, 200 ng/μl polyA RNA, Protease (cOmpete™, EDTA-free Protease Inhibitor Cocktail) and RNAse Inhibitor (RNasin® Ribonuclease Inhibitors) in editing reaction buffer: 15 mM Tris-Cl pH 7.4, 1.5 mM EDTA, 60 mM KCl, 3 mM MgCl₂, 0.5 mM DTT, 3% glycerol and 0.003% NP-40. The editing reaction was initiated by addition of hADAR2 protein into reaction mix (final volume 10 μl). After 6 different incubation times (10, 20, 40, 80, 120 and 160 min) reaction was stop with 190 μl boiled water to denature the protein. The Maxima™ reverse transcription kit was used to convert the modified and unmodified RNA targets to cDNA, and the fraction of edited RNA was indirectly measured with ddPCR assays (as described in example 3) to quantify the number of restored wild type RNA targets, with the mean from 2 replicates shown. Data was collected for the different time points and results are shown in FIG. 8. ADAR 103-1, which does not have 2′-MOE modifications generates a high percentage of RNA target sequence recovery above 80% after 50 min. ADAR 103-2 with insertions of 2′-MOE modifications derived from the structure-based computational screening as outlined herein shows a similar percentage of editing above 70% after 50 min. Notably, ADAR 102-7 with no computational optimization exhibits a percentage of editing below 20% after 50 min. ADAR 103-8 with additional 2′-MOE modifications in the 5′ region shows similar results as ADAR 103-2. It should be noted that the compatibility of 2′-MOE modifications inserted in the 5′ region of the EON cannot be determined further than position +12, as the in silico screening is strictly performed for the RNA sequence spanned by the ADAR2 deaminase domain (positions −12 to +12). However, from the results observed with ADAR 103-8, it can be concluded that additional 2′-MOEs in the 5′ region of the EON (positions +13 to +24) apparently do not interfere with hADAR2 enzymatic activity.

These results confirm the relevance of the structure-based computational approach for the design of 2′-MOE modified oligonucleotides compatible with hADAR2-mediated editing. It is demonstrated that the computational approach of the present invention can support the design of 2′-MOE modified EONs (ADAR 103-2 and ADAR 103-8) with editing level in vitro similar to exclusively 2′-OMe EONs such as ADAR 103-1. This is important, because it is now been shown that while 2′-MOE modifications may cause steric hindrances in the area that relates to the ADAR2 deaminase domain, if such positions are carefully addressed, the beneficial properties of having as many 2′-MOE modifications in this region as possible (which in itself contributes to features such as cell entry, intracellular trafficking, etc.) is now feasible. It is anticipated that the beneficial properties of having 2′-MOE at the selected positions may contribute to an increased RNA editing efficiency when used in in vivo settings, in comparison to EONs that solely carry 2′-OMe modifications.

Claims

1. An editing oligonucleotide (EON) capable of forming a double stranded complex with a target RNA molecule in a cell, and capable of recruiting an endogenous enzyme with ADAR activity, wherein: (i) the target RNA molecule comprises a target adenosine for deamination by the enzyme with ADAR activity;(ii) the EON comprises a Central Triplet of three sequential nucleotides in which the nucleotide directly opposite the target adenosine is the middle nucleotide (position 0) of the Central Triplet and wherein the positions are positively (+) and negatively (−) incremented towards the 5′ and 3′ ends of the EON, respectively;(iii) the EON comprises a nucleotide at position 0 that mismatches with the target adenosine;(iv) the EON comprises one or more nucleotides comprising a 2′-O-methoxyethyl (2′-MOE) ribose modification;(v) the EON comprises one or more nucleotides not comprising a 2′-MOE ribose modification; and(vi) the nucleotides comprising a 2′-MOE ribose modification are at positions that do not prevent the enzyme with ADAR activity from deaminating the target adenosine.

2. The EON of claim 1, wherein the EON comprises 2′-O-methyl (2′-OMe) ribose modifications at the positions that do not comprise a 2′-MOE ribose modification, and/or wherein the EON comprises deoxynucleotides at positions that do not comprise a 2′-MOE ribose modification.

3. The EON of claim 1, wherein the EON comprises one or two deoxynucleotides at positions −1 and/or 0 in the Central Triplet.

4. The EON of claim 1, wherein the EON does not comprise a 2′-MOE modification at position −1 and or 0 in the Central Triplet.

5. The EON of claim 1, wherein the EON does not comprise a 2′-MOE modification at position +6, +1, 0, −1, −2, −3, −4, and/or −5.

6. The EON of claim 1, wherein the enzyme with ADAR activity is ADAR1 or ADAR2.

7. The EON of claim 1, wherein the EON is longer than 10, 11, 12, 13, 14, 15, 16 or 17 nucleotides, and wherein the EON is shorter than 100 nucleotides.

8. A pharmaceutical composition comprising the EON of claim 1, and a pharmaceutically acceptable carrier.

9. A method of treating or preventing a genetic disorder in a subject in need thereof, the method comprising administering to the subject the EON of claim 1.

10. The method of claim 9, wherein the genetic disorder is selected from the group consisting of: Cystic fibrosis, Hurler Syndrome, alpha-1-antitrypsin (A1AT) deficiency, Parkinson's disease, Alzheimer's disease, albinism, Amyotrophic lateral sclerosis, Asthma, β-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, Glucose-6-phosphate dehydrogenase, Haemophilia, Hereditary Hematochromatosis, Hunter Syndrome, Huntington's disease, 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, 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, Sturge-Weber Syndrome, and cancer.

11. A method for the deamination of at least one target adenosine present in a target RNA molecule in a cell, the method comprising the steps of: (i) providing the cell with the EON of claim 1;(ii) allowing uptake by the cell of the EON;(iii) allowing annealing of the EON to the target RNA molecule; and(iv) allowing a mammalian enzyme with ADAR activity to deaminate the target adenosine in the target RNA molecule to an inosine.

12. The method of claim 14, wherein step (v) comprises: (a) sequencing the target RNA sequence;(b) assessing the presence of a functional, elongated, full length and/or wild type protein when the target adenosine is located in a UGA or UAG stop codon, which is edited to a UGG codon through the deamination;(c) assessing the presence of a functional, elongated, full length and/or wild type protein when two target adenosines are located in a UAA stop codon, which is edited to a UGG codon through the deamination of both target adenosines;(d) assessing whether splicing of the pre-mRNA was altered by the deamination; or(e) using a functional read-out, wherein the target RNA after the deamination encodes a functional, full length, elongated and/or wild type protein.

13. The EON of claim 7, wherein the EON is shorter than 60 nucleotides.

14. The method of claim 11, further comprising: (v) identifying the presence of the inosine in the target RNA.