Epigenetic control of plant regeneration: Unraveling the role of histone methylation

IF 5.4 Q1 PLANT SCIENCES

Current Plant Biology Pub Date : 2024-10-31 DOI:10.1016/j.cpb.2024.100408

Saikat Sena , Ajit Prakash , Johannes Van Staden , Vijay Kumar

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引用次数: 0

Abstract

It is incredible that plants can actively promote cellular dedifferentiation and regeneration. The change in cell fate is accompanied by modifications to the epigenetic landscape. Plants may regulate developmental processes and environmental adaptation via the establishment, maintenance, and removal of epigenetic changes in addition to genetically encoded variables. Studies on plant regeneration are very important since the underlying processes are connected to basic research in many different domains as well as the development of widely used plant biotechnology. De novo organogenesis, somatic embryogenesis, and tissue regeneration are the three primary kinds of regeneration observed in higher plants. In-vitro culturing may cause histone methylation to reassemble the nuclear architecture. The process of somatic embryogenesis and regeneration relates to different methylation states that regulate gene expression in-vitro. In order to generate huge amounts of top-notch planting materials or to enhance agronomic features that promote crop development, it may be necessary to change the methylation profile. Enhancing the embryogenic potential and totipotency in resistant plant species and specific genotypes could be achievable by developing techniques with the aid of an understanding of the molecular processes behind methylation changes and the acquisition of embryonic cell destiny during in-vitro cultures. Additionally, the methylation profile may help crops adapt to extreme conditions when they experience diverse challenges throughout in-vitro growth. In this article, we examine the studies on how histone methylation affects plant variety and explore the possibilities of targeted epigenetic modification for crop development.

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植物再生的表观遗传控制：揭示组蛋白甲基化的作用

令人难以置信的是，植物能够积极促进细胞的去分化和再生。细胞命运的改变伴随着表观遗传景观的改变。除了基因编码变量外，植物还可以通过表观遗传变化的建立、维持和消除来调节发育过程和环境适应。植物再生研究非常重要，因为其基本过程与许多不同领域的基础研究以及广泛应用的植物生物技术的发展息息相关。全新器官发生、体细胞胚胎发生和组织再生是在高等植物中观察到的三种主要再生方式。体外培养可导致组蛋白甲基化，从而重新组装核结构。体细胞胚胎发生和再生过程与调节体外基因表达的不同甲基化状态有关。为了产生大量顶级种植材料或增强农艺特征以促进作物生长，可能有必要改变甲基化状况。通过了解甲基化变化背后的分子过程以及体外培养过程中胚胎细胞命运的获得，开发技术可以提高抗性植物物种和特定基因型的胚胎发生潜力和全能性。此外，当作物在体外生长过程中经历各种挑战时，甲基化特征可能有助于作物适应极端条件。在本文中，我们将探讨组蛋白甲基化如何影响植物品种的研究，并探讨有针对性地进行表观遗传修饰以促进作物生长的可能性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Current Plant Biology Agricultural and Biological Sciences-Plant Science

CiteScore

10.90

自引率

1.90%

发文量

审稿时长

50 days

期刊介绍： Current Plant Biology aims to acknowledge and encourage interdisciplinary research in fundamental plant sciences with scope to address crop improvement, biodiversity, nutrition and human health. It publishes review articles, original research papers, method papers and short articles in plant research fields, such as systems biology, cell biology, genetics, epigenetics, mathematical modeling, signal transduction, plant-microbe interactions, synthetic biology, developmental biology, biochemistry, molecular biology, physiology, biotechnologies, bioinformatics and plant genomic resources.