Barcoding Notch Signaling in the Developing Brain

Overview

Journal Development

Specialty Biology

Date 2024 Nov 22

PMID 39575683

Authors

Abigail M Siniscalco

Roshan Priyarangana Perera

Jessie E Greenslade

Hemagowri Veeravenkatasubramanian

Aiden Masters

Hannah M Doll

Bushra Raj

Affiliations

Soon will be listed here.

Abstract

Developmental signaling inputs are fundamental for shaping cell fates and behavior. However, traditional fluorescent-based signaling reporters have limitations in scalability and molecular resolution of cell types. We present SABER-seq, a CRISPR-Cas molecular recorder that stores transient developmental signaling cues as permanent mutations in cellular genomes for deconstruction at later stages via single-cell transcriptomics. We applied SABER-seq to record Notch signaling in developing zebrafish brains. SABER-seq has two components: a signaling sensor and a barcode recorder. The sensor activates Cas9 in a Notch-dependent manner with inducible control, while the recorder obtains mutations in ancestral cells where Notch is active. We combine SABER-seq with an expanded juvenile brain atlas to identify cell types derived from Notch-active founders. Our data reveal rare examples where differential Notch activities in ancestral progenitors are detected in terminally differentiated neuronal subtypes. SABER-seq is a novel platform for rapid, scalable and high-resolution mapping of signaling activity during development.

Citing Articles

Reconstructing signaling history of single cells with imaging-based molecular recording.

Hao K, Barrett M, Samadi Z, Zarezadeh A, McGrath Y, Askary A bioRxiv. 2024; .

PMID: 39416000 PMC: 11482953. DOI: 10.1101/2024.10.11.617908.

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