RNA Editing as a Therapeutic Approach for Retinal Gene Therapy Requiring Long Coding Sequences
Abstract
:1. Introduction
2. ADARs: Adenosine Deaminase Acting on RNA
2.1. ADAR Expression, Structure and Function
2.2. Engineering ADARs for RNA Editing
2.2.1. A-I Editors
2.2.2. C-U Editors
3. RNA Editing with ADARs
3.1. BoxB-λN-ADAR
3.2. SNAP-ADAR
3.3. GluR2-ADAR
3.4. MS2-MCP-ADAR
3.5. Endogenous ADAR Approaches
3.6. CRISPR-Cas13 for RNA Editing
3.6.1. A to I Editing
3.6.2. C to U Editing
3.6.3. Synthetic CRISPR-Like RNA Editors
4. RNA Editing for Large Inherited Retinal Genes
4.1. Gene Targets for RNA Editing in Inherited Retinal Degeneration
4.2. Distribution of Targetable Mutations with RNA Editing
4.3. A Case Study of RNA Editing for Inherited Retinal Disease
4.4. Towards Clinical use of RNA Editing
4.4.1. Clinical Considerations of RNA Editing
4.4.2. Endogenous and Exogenous ADAR Strategies
4.4.3. Delivery Challenges
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
AAV | Adeno-associated virus |
ADAR | Adenosine deaminase acting on RNA |
ADARDD | Deaminase domain of ADAR |
BoxB-λN | BoxB RNA hairpin-Lambda N protein |
CRISPR | Clustered Regularly Interspaced Short Palindromic Repeat |
Cas | CRISPR-associated genes |
CIRTS | CRISPR-Cas-inspired RNA targeting system |
dsRBD | Double-stranded RNA-binding domain |
HEK | Human embryonic kidney |
HEPN | Higher eukaryotes and prokaryotes nucleotide-binding domain |
HUVEC | Human umbilical vein endothelial cells |
LEAPER | Leveraging Endogenous ADAR for Programmable Editing of RNA |
MS2-MCP | MS2 bacteriophage coat protein |
NLS | Nuclear localization signal |
NES | Nuclear export signal |
PAM | Protospacer adjacent motif |
PFS | Protospacer flanking sequences |
REPAIR | RNA Editing for Programmable A to I Replacement |
RESCUE | RNA Editing for Specific C to U Exchange |
RESTORE | Recruiting Endogenous ADAR to Specific Transcripts for Oligonucleotide-mediated RNA Editing |
RNA | Ribonucleic acid |
UTR | Untranslated region |
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System | Immortalized Cells | Primary Cells | In Vivo | Ref | |
---|---|---|---|---|---|
Exogenous ADAR | |||||
BoxB-λN-ADAR | Gene | Mecp2 | Mecp2 | Not tested | [47,49,50] |
Model | N2A | Murine neuron | |||
Efficiency | 25–50% | 72% | |||
Delivery | Plasmid | AAV | |||
SNAP-ADAR | Gene | Many targets | Not tested | Not tested | [53] |
Model | HEK293 | ||||
Efficiency | Up to 90% | ||||
Delivery | Guide transfection | ||||
MS2-MCP-ADAR | Gene | Many targets | Not tested | Dmd | [42,55] |
Model | HEK293T | mdx mouse | |||
Efficiency | 10–80% | AAV | |||
Delivery | Plasmid transfection | 2% | |||
GluR2-ADAR | Gene | PINK1 | Dmd, Otc | [42,54] | |
Model | HELA HEK293T | Not tested | mdx mouse model spfash mouse model | ||
Efficiency | 10–40% | 0.8% (mdx) 4.6–8.2% (spfash) | |||
Delivery | Plasmid transfection | AAV | |||
REPAIR: CRISPR-Cas13b-ADAR (A-I) | Gene | KRAS, PPIB | Not tested | Not tested | [43] |
Model | HEK293FT | ||||
Efficiency | 28% | ||||
Delivery | Plasmid | ||||
RESCUE: CRISPR-Cas13b-ADAR (C-T) | Gene | Multiple | CTNNB1 | Not tested | [44] |
Model | HEK293FT | HUVEC cells | |||
Efficiency | 3–42% in 5% when multiplexed | Not reported | |||
Delivery | Plasmid transfection | Plasmid transfection | |||
Endogenous ADAR | |||||
LEAPER (long gRNA) | Gene | Many targets | Many targets | Not tested | [40] |
Model | Multiple lines | Multiple lines | |||
Efficiency | Up to 50% (plasmid) 6% (lentivirus) | 30–80% | |||
Delivery | Plasmid Lentivirus | Plasmid electroporation | |||
RESTORE (ASO, chemical modification) | Gene | Many targets | GAPDH, STAT1, SERPINA1 | Not tested | [57] |
Model | Many cell types | Multiple lines | |||
Efficiency | 3–34% | Up to 27% | |||
Delivery | ASO Transfection | ASO Transfection | |||
GluR2 | Gene | Not tested | Not tested | Otc | [42] |
Model | spfash mouse model | ||||
Efficiency | 0.6% | ||||
Delivery | AAV |
Gene | Frequency (%) # | Coding Sequence Length (kb) |
---|---|---|
ABCA4 | 17.3 | 6.81 |
USH2A | 7.6 | 15.6 |
CEP290 | 1.8 | 7.44 |
MYO7A | 0.8 | 6.65 |
EYS | 0.6 | 9.43 |
CDH23 | 0.4 | 10.1 |
Total | 28.5 |
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Fry, L.E.; Peddle, C.F.; Barnard, A.R.; McClements, M.E.; MacLaren, R.E. RNA Editing as a Therapeutic Approach for Retinal Gene Therapy Requiring Long Coding Sequences. Int. J. Mol. Sci. 2020, 21, 777. https://doi.org/10.3390/ijms21030777
Fry LE, Peddle CF, Barnard AR, McClements ME, MacLaren RE. RNA Editing as a Therapeutic Approach for Retinal Gene Therapy Requiring Long Coding Sequences. International Journal of Molecular Sciences. 2020; 21(3):777. https://doi.org/10.3390/ijms21030777
Chicago/Turabian StyleFry, Lewis E., Caroline F. Peddle, Alun R. Barnard, Michelle E. McClements, and Robert E. MacLaren. 2020. "RNA Editing as a Therapeutic Approach for Retinal Gene Therapy Requiring Long Coding Sequences" International Journal of Molecular Sciences 21, no. 3: 777. https://doi.org/10.3390/ijms21030777
APA StyleFry, L. E., Peddle, C. F., Barnard, A. R., McClements, M. E., & MacLaren, R. E. (2020). RNA Editing as a Therapeutic Approach for Retinal Gene Therapy Requiring Long Coding Sequences. International Journal of Molecular Sciences, 21(3), 777. https://doi.org/10.3390/ijms21030777