CRISPR-dCas13-tracing reveals transcriptional memory and limited mRNA export in developing zebrafish embryos

Author:

Huang Youkui,Gao Bao-Qing,Meng Quan,Yang Liang-Zhong,Ma Xu-Kai,Wu Hao,Pan Yu-Hang,Yang Li,Li Dong,Chen Ling-LingORCID

Abstract

Abstract Background Understanding gene transcription and mRNA-protein (mRNP) dynamics in single cells in a multicellular organism has been challenging. The catalytically dead CRISPR-Cas13 (dCas13) system has been used to visualize RNAs in live cells without genetic manipulation. We optimize this system to track developmentally expressed mRNAs in zebrafish embryos and to understand features of endogenous transcription kinetics and mRNP export. Results We report that zygotic microinjection of purified CRISPR-dCas13-fluorescent proteins and modified guide RNAs allows single- and dual-color tracking of developmentally expressed mRNAs in zebrafish embryos from zygotic genome activation (ZGA) until early segmentation period without genetic manipulation. Using this approach, we uncover non-synchronized de novo transcription between inter-alleles, synchronized post-mitotic re-activation in pairs of alleles, and transcriptional memory as an extrinsic noise that potentially contributes to synchronized post-mitotic re-activation. We also reveal rapid dCas13-engaged mRNP movement in the nucleus with a corralled and diffusive motion, but a wide varying range of rate-limiting mRNP export, which can be shortened by Alyref and Nxf1 overexpression. Conclusions This optimized dCas13-based toolkit enables robust spatial-temporal tracking of endogenous mRNAs and uncovers features of transcription and mRNP motion, providing a powerful toolkit for endogenous RNA visualization in a multicellular developmental organism.

Funder

CAS Project for Young Scientists in Basic Research

Health and Family Planning Commission of Sichuan Province

National Natural Science Foundation of China

Howard Hughes Medical Institute

Postdoctoral Research Foundation of China

Shanghai Municipal Fund for Daily Expenses

National Key R&D Program of China

Ministry of Science and Technology of China

Publisher

Springer Science and Business Media LLC

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