Notch-dependent DNA cis-regulatory elements and their dose-dependent control of C. elegans stem cell self-renewal

A long-standing biological question is how DNA cis-regulatory elements shape transcriptional patterns during metazoan development. The use of reporter constructs, cell culture and computational modeling has made enormous contributions to understanding this fundamental question, but analysis of regulatory elements in their natural developmental context is an essential but rarely used complement. Here, we edited Notch-dependent cis-regulatory elements in the endogenous C. elegans sygl-1 gene, which encodes a key stem cell regulator. We then analyzed the in vivo consequences of those mutations – on both gene expression (nascent transcripts, mRNA, protein) and stem cell maintenance. Mutation of a single element in a three-element homotypic cluster reduced expression as well as stem cell pool size by about half, while mutation of two elements essentially abolished them. We find that LBS number and LBS neighborhood are both important to activity: elements on separate chromosomes function additively, while elements in the same cluster act synergistically. Our approach of precise CRISPR/Cas9 gene editing coupled with quantitation of both molecular and biological readouts establishes a powerful model for in vivo functional analyses of DNA cis-regulatory elements. Summary statement Notch-dependent DNA cis-regulatory elements work together in their developmental context to shape a transcriptional gradient, control stem cell pool size, and govern differentiation onset.