CRISPR-Sirius: RNA scaffolds for signal amplification in genome imaging
Clustered regularly interspaced short palindromic repeats (CRISPR) guide RNA scaffolds
have been adapted to carry multiple binding sites for fluorescent proteins to enhance
brightness for live cell imaging of genomic loci. However, many of these modifications result
in guide RNA instability and thus produce lower genome-labeling efficiency than
anticipated. Here we introduce CRISPR-Sirius, based on octet arrays of aptamers conferring
both enhanced guide RNA stability and brightness, and provide initial biological …
have been adapted to carry multiple binding sites for fluorescent proteins to enhance
brightness for live cell imaging of genomic loci. However, many of these modifications result
in guide RNA instability and thus produce lower genome-labeling efficiency than
anticipated. Here we introduce CRISPR-Sirius, based on octet arrays of aptamers conferring
both enhanced guide RNA stability and brightness, and provide initial biological …
Abstract
Clustered regularly interspaced short palindromic repeats (CRISPR) guide RNA scaffolds have been adapted to carry multiple binding sites for fluorescent proteins to enhance brightness for live cell imaging of genomic loci. However, many of these modifications result in guide RNA instability and thus produce lower genome-labeling efficiency than anticipated. Here we introduce CRISPR-Sirius, based on octet arrays of aptamers conferring both enhanced guide RNA stability and brightness, and provide initial biological applications of this platform.
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