Epigenetics governs senescence.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
ACS Applied Bio Materials Pub Date : 2024-03-01 Epub Date: 2023-08-18 DOI:10.1007/s00497-023-00479-2
Ajayraj Kushwaha, Vipul Mishra, Durgesh Kumar Tripathi, Ravi Gupta, Vijay Pratap Singh
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引用次数: 0

Abstract

Petal is one of the most esthetic and essential parts of a flower that fascinates the pollinators to enhance pollination. Petal senescence is a highly controlled and organized natural phenomenon assisted by phytohormones and gene regulation. It is an inelastically programmed event preceding to which petals give rise to color and scent that captivate pollinators, representing a flower's maturity for sexual reproduction. Till today, many genes involved in the petal senescence through genetic as well as epigenetic changes in response to hormones have been identified. In most of the species, petal senescence is controlled by ethylene, whereas others are independent of this hormone. It has also been proved that the increase in the carbohydrate contents like mannitol, inositol and trehalose delayed the senescence in tulips and Gladiolus. An increased sugar content prevents the biosynthesis of EIN3-like mRNA and further upregulates several senescence correlated genes. A wide range of different transcription factors as well as regulators are disparately expressed in ethylene insensitive and ethylene sensitive petal senescence. DcHB30, a downregulating factor, which upon linking physically to DcWRKY75 leads to the upregulation of ethylene promoting petal senescence. Here we describe the role of ethylene in petal senescence through epigenetic changes. Studies show that ethylene causes petal senescence through epigenetic changes. Feng et al. (Plant Physiol 192:546-564, 2023) observed that ARABIDOPSIS HOMOLOG OF TRITHORAX1 (DcATX1) promotes trimethylation of histone 3 (H3) at 4th lysine (H3K4me3) in Carnation. H3K4me3 further stimulates the expression of genes of ethylene biosynthesis and senescence, leading to senescence in Carnation.

Abstract Image

表观遗传学控制着衰老。
花瓣是花朵最美、最重要的部分之一,它吸引着授粉者,促进授粉。在植物激素和基因调控的帮助下,花瓣衰老是一种高度受控和有组织的自然现象。在花瓣衰老之前,花瓣会呈现出吸引传粉昆虫的颜色和香味,这是一种非弹性程序事件,代表着花朵有性生殖的成熟。迄今为止,已发现许多基因通过遗传和表观遗传变化对激素做出反应,从而参与花瓣衰老。在大多数物种中,花瓣的衰老受乙烯控制,而其他物种则不受乙烯控制。研究还证明,甘露糖醇、肌醇和三卤糖等碳水化合物含量的增加会延缓郁金香和剑兰的衰老。糖分含量的增加会阻止类 EIN3 mRNA 的生物合成,并进一步上调多个与衰老相关的基因。在对乙烯不敏感和对乙烯敏感的花瓣衰老过程中,各种不同的转录因子和调控因子都有不同程度的表达。DcHB30是一个下调因子,它与DcWRKY75物理连接后导致乙烯上调,促进花瓣衰老。在这里,我们描述了乙烯通过表观遗传变化在花瓣衰老中的作用。研究表明,乙烯通过表观遗传变化导致花瓣衰老。Feng等人(Plant Physiol 192:546-564, 2023)观察到,在康乃馨中,TRITHORAX1的同源染色体(DcATX1)促进组蛋白3(H3)在第4个赖氨酸处的三甲基化(H3K4me3)。H3K4me3 进一步刺激乙烯生物合成和衰老基因的表达,导致康乃馨衰老。
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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