Single Worm Transcriptomics Identifies a Developmental Core Network of Oscillating Genes with Deep Conservation Across Nematodes

Overview

Journal Genome Res

Specialty Genetics

Date 2021 Jul 24

PMID 34301622

Citations 10

Authors

Shuai Sun

Christian Rodelsperger

Ralf J Sommer

Affiliations

Soon will be listed here.

Abstract

High-resolution spatial and temporal maps of gene expression have facilitated a comprehensive understanding of animal development and evolution. In nematodes, the small body size represented a major challenge for such studies, but recent advancements have helped overcome this limitation. Here, we have implemented single worm transcriptomics (SWT) in the nematode model organism to provide a high-resolution map of the developmental transcriptome. We selected 38 time points from hatching of the J2 larvae to young adults to perform transcriptome analysis over 60 h of postembryonic development. A mean sequencing depth of 4.5 million read pairs allowed the detection of more than 23,135 (80%) of all genes. Nearly 3000 (10%) genes showed oscillatory expression with discrete expression levels, phases, and amplitudes. Gene age analysis revealed an overrepresentation of ancient gene classes among oscillating genes, and around one-third of them have 1:1 orthologs in One important gene family overrepresented among oscillating genes is collagens. Several of these collagen genes are regulated by the developmental switch gene , indicating a potential function in the regulation of mouth-form plasticity, a key developmental process in this facultative predatory nematode. Together, our analysis provides (1) an updated protocol for SWT in nematodes that is applicable to many microscopic species, (2) a 1- to 2-h high-resolution catalog of gene expression throughout postembryonic development, and (3) a comparative analysis of oscillatory gene expression between the two model organisms and and associated evolutionary dynamics.

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