Single-cell Transcriptome Reveals Dominant Subgenome Expression and Transcriptional Response to Heat Stress in Chinese Cabbage

Overview

Journal Genome Biol

Specialties Biology
Genetics

Date 2022 Dec 19

PMID 36536447

Authors

Xiaoxue Sun

Daling Feng

Mengyang Liu

Ruixin Qin

Yan Li

Yin Lu

Xiaomeng Zhang

Yanhua Wang

Shuxing Shen

Wei Ma

Jianjun Zhao

Affiliations

Soon will be listed here.

Abstract

Background: Chinese cabbage (Brassica rapa ssp. pekinensis) experienced a whole-genome triplication event and thus has three subgenomes: least fractioned, medium fractioned, and most fractioned subgenome. Environmental changes affect leaf development, which in turn influence the yield. To improve the yield and resistance to different climate scenarios, a comprehensive understanding of leaf development is required including insights into the full diversity of cell types and transcriptional networks underlying their specificity.

Results: Here, we generate the transcriptional landscape of Chinese cabbage leaf at single-cell resolution by performing single-cell RNA sequencing of 30,000 individual cells. We characterize seven major cell types with 19 transcriptionally distinct cell clusters based on the expression of the reported marker genes. We find that genes in the least fractioned subgenome are predominantly expressed compared with those in the medium and most fractioned subgenomes in different cell types. Moreover, we generate a single-cell transcriptional map of leaves in response to high temperature. We find that heat stress not only affects gene expression in a cell type-specific manner but also impacts subgenome dominance.

Conclusions: Our study highlights the transcriptional networks in different cell types and provides a better understanding of transcriptional regulation during leaf development and transcriptional response to heat stress in Chinese cabbage.

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