AI Article Synopsis
- Integrating cell type-specific enhancers with recombinant adeno-associated viruses (AAVs) allows targeted genetic access to specific cell types, but AAVs have a limited capacity for the size of genetic material they can deliver.
- The concept of transcriptional crosstalk involves separating large regulatory elements into a second AAV genome, offering a new way to achieve specific gene expression within a certain cell type.
- The study identifies transcriptional crosstalk in AAVs with 11 mouse brain enhancers, using advanced spatial genomics to examine AAV behavior, and successfully demonstrates cell type-specific gene editing in tissues with minimal invasiveness.
Article Abstract
Integrating cell type-specific regulatory elements (e.g. enhancers) with recombinant adeno-associated viruses (AAVs) can provide broad and efficient genetic access to specific cell types. However, the packaging capacity of AAVs restricts the size of both the enhancers and the cargo that can be delivered. Transcriptional crosstalk offers a novel paradigm for cell type-specific expression of large cargo, by separating distally-acting regulatory elements into a second AAV genome. Here, we identify and profile transcriptional crosstalk in AAV genomes carrying 11 different enhancers active in mouse brain. To understand transcriptional crosstalk, we develop spatial genomics methods to identify and localize AAV genomes and their concatemeric forms in cultured cells and in tissue. Using these methods, we construct detailed views of the dynamics of AAV transduction and demonstrate that transcriptional crosstalk is dependent upon concatemer formation. Finally, we leverage transcriptional crosstalk to drive expression of a large Cas9 cargo in a cell type-specific manner with systemically-administered engineered AAVs and demonstrate AAV-delivered, minimally-invasive, cell type-specific gene editing in wildtype animals that recapitulates known disease phenotypes.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10769433 | PMC |
| http://dx.doi.org/10.1101/2023.12.23.573214 | DOI Listing |
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