Single-cell Transcriptome and Translatome Dual-omics Reveals Potential Mechanisms of Human Oocyte Maturation

Overview

Journal Nat Commun

Specialty Biology

Date 2022 Aug 30

PMID 36042231

Authors

Wenqi Hu

Haitao Zeng

Yanan Shi

Chuanchuan Zhou

Jiana Huang

Lei Jia

Siqi Xu

Xiaoyu Feng

Yanyan Zeng

Tuanlin Xiong

Wenze Huang

Peng Sun

Yajie Chang

Tingting Li

Cong Fang

Keliang Wu

Lingbo Cai

Wuhua Ni

Yan Li

Zhiyong Yang

Qiangfeng Cliff Zhang

RiCheng Chian

Zijiang Chen

Xiaoyan Liang

Kehkooi Kee

Affiliations

Soon will be listed here.

Abstract

The combined use of transcriptome and translatome as indicators of gene expression profiles is usually more accurate than the use of transcriptomes alone, especially in cell types governed by translational regulation, such as mammalian oocytes. Here, we developed a dual-omics methodology that includes both transcriptome and translatome sequencing (T&T-seq) of single-cell oocyte samples, and we used it to characterize the transcriptomes and translatomes during mouse and human oocyte maturation. T&T-seq analysis revealed distinct translational expression patterns between mouse and human oocytes and delineated a sequential gene expression regulation from the cytoplasm to the nucleus during human oocyte maturation. By these means, we also identified a functional role of OOSP2 inducing factor in human oocyte maturation, as human recombinant OOSP2 induced in vitro maturation of human oocytes, which was blocked by anti-OOSP2. Single-oocyte T&T-seq analyses further elucidated that OOSP2 induces specific signaling pathways, including small GTPases, through translational regulation.

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