Epigenetics in the Modern Era of Crop Improvements

Overview

Journal Sci China Life Sci

Date 2025 Jan 14

PMID 39808224

Authors

Yan Xue

Xiaofeng Cao

Xiangsong Chen

Xian Deng

Xing Wang Deng

Yong Ding

Aiwu Dong

Cheng-Guo Duan

Xiaofeng Fang

Lei Gong

Zhizhong Gong

Xiaofeng Gu

Chongsheng He

Hang He

Shengbo He

Xin-Jian He

Yan He

Yuehui He

Guifang Jia

Danhua Jiang

Jianjun Jiang

Jinsheng Lai

Zhaobo Lang

Chenlong Li

Qing Li

Xingwang Li

Bao Liu

Bing Liu

Xiao Luo

Yijun Qi

Weiqiang Qian

Guodong Ren

Qingxin Song

Xianwei Song

Zhixi Tian

Jia-Wei Wang

Yuan Wang

Liang Wu

Zhe Wu

Rui Xia

Jun Xiao

Lin Xu

Zheng-Yi Xu

Wenhao Yan

Hongchun Yang

Jixian Zhai

Yijing Zhang

Yusheng Zhao

Xuehua Zhong

Dao-Xiu Zhou

Ming Zhou

Yue Zhou

Bo Zhu

Jian-Kang Zhu

Qikun Liu

Affiliations

Soon will be listed here.

Abstract

Epigenetic mechanisms are integral to plant growth, development, and adaptation to environmental stimuli. Over the past two decades, our comprehension of these complex regulatory processes has expanded remarkably, producing a substantial body of knowledge on both locus-specific mechanisms and genome-wide regulatory patterns. Studies initially grounded in the model plant Arabidopsis have been broadened to encompass a diverse array of crop species, revealing the multifaceted roles of epigenetics in physiological and agronomic traits. With recent technological advancements, epigenetic regulations at the single-cell level and at the large-scale population level are emerging as new focuses. This review offers an in-depth synthesis of the diverse epigenetic regulations, detailing the catalytic machinery and regulatory functions. It delves into the intricate interplay among various epigenetic elements and their collective influence on the modulation of crop traits. Furthermore, it examines recent breakthroughs in technologies for epigenetic modifications and their integration into strategies for crop improvement. The review underscores the transformative potential of epigenetic strategies in bolstering crop performance, advocating for the development of efficient tools to fully exploit the agricultural benefits of epigenetic insights.

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