Summary
Programmable nucleases reside at the nexus of advanced gene editing and microbial defense. These nucleases degrade phage DNA but avoid genomic DNA to provide the microbe with adaptive immunity. The standard-bearer, CRISPR-Cas9, relies on a guide RNA (gRNA) – its program – to precisely cut a complimentary genetic sequence – its target – for precision gene editing. These programmable nucleases deliver cure for genetic diseases like anemia, blindness, and cancer; quick disease model development; and diagnostics for viruses like SARS-CoV-2.
Hunts across microbial genomes have exposed thousands of programmable nucleases. Each could be another valuable tool for genome engineers, but we know just too little about them to use them safely. Even Cas9 does not have guide-target parity: It cuts partially matched ‘off-target’ genome sites, which can lead to dangerous side effects. Though we work hard to avoid off-targets, partial matching may have a bright side. What if we leverage it, using it to make gene editing more predictable?
Using high-throughput biochemistry, we will Profile nucleases and Repurpose Off-Targets to Expand Gene Editing. The PROTÉGÉ research program will profile guide-target parity – specificity – across promising, newly discovered programmable nucleases. It will deliver a toolset for assessing this critical safety feature rapidly and broadly. Finally, we will test the hypothesis that purposefully misprogramming nucleases can direct specific repair outcomes. We intended to benefit Europe and the world community with safer and more diverse gene editing tools for achieving its Horizon Europe health, technology and environmental goals.
Hunts across microbial genomes have exposed thousands of programmable nucleases. Each could be another valuable tool for genome engineers, but we know just too little about them to use them safely. Even Cas9 does not have guide-target parity: It cuts partially matched ‘off-target’ genome sites, which can lead to dangerous side effects. Though we work hard to avoid off-targets, partial matching may have a bright side. What if we leverage it, using it to make gene editing more predictable?
Using high-throughput biochemistry, we will Profile nucleases and Repurpose Off-Targets to Expand Gene Editing. The PROTÉGÉ research program will profile guide-target parity – specificity – across promising, newly discovered programmable nucleases. It will deliver a toolset for assessing this critical safety feature rapidly and broadly. Finally, we will test the hypothesis that purposefully misprogramming nucleases can direct specific repair outcomes. We intended to benefit Europe and the world community with safer and more diverse gene editing tools for achieving its Horizon Europe health, technology and environmental goals.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101078247 |
| Start date: | 01-06-2023 |
| End date: | 31-05-2028 |
| Total budget - Public funding: | 1 141 779,00 Euro - 1 141 779,00 Euro |
Cordis data
Original description
Programmable nucleases reside at the nexus of advanced gene editing and microbial defense. These nucleases degrade phage DNA but avoid genomic DNA to provide the microbe with adaptive immunity. The standard-bearer, CRISPR-Cas9, relies on a guide RNA (gRNA) – its program – to precisely cut a complimentary genetic sequence – its target – for precision gene editing. These programmable nucleases deliver cure for genetic diseases like anemia, blindness, and cancer; quick disease model development; and diagnostics for viruses like SARS-CoV-2.Hunts across microbial genomes have exposed thousands of programmable nucleases. Each could be another valuable tool for genome engineers, but we know just too little about them to use them safely. Even Cas9 does not have guide-target parity: It cuts partially matched ‘off-target’ genome sites, which can lead to dangerous side effects. Though we work hard to avoid off-targets, partial matching may have a bright side. What if we leverage it, using it to make gene editing more predictable?
Using high-throughput biochemistry, we will Profile nucleases and Repurpose Off-Targets to Expand Gene Editing. The PROTÉGÉ research program will profile guide-target parity – specificity – across promising, newly discovered programmable nucleases. It will deliver a toolset for assessing this critical safety feature rapidly and broadly. Finally, we will test the hypothesis that purposefully misprogramming nucleases can direct specific repair outcomes. We intended to benefit Europe and the world community with safer and more diverse gene editing tools for achieving its Horizon Europe health, technology and environmental goals.
Status
SIGNEDCall topic
ERC-2022-STGUpdate Date
12-03-2024
Geographical location(s)
