DNA methylation variation and growth in the clonal Duchesnea indica is regulated by both past and present lead environments.

IF 2.9 3区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Epigenetics Pub Date : 2024-12-01 Epub Date: 2024-01-21 DOI:10.1080/15592294.2024.2305078
Jiaxin Quan, Shanshan Song, Linya Xing, Xiao Liu, Ming Yue
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Abstract

Studies suggest that clonal plants' ability to select habitats and forage in a heterogeneous environment is influenced by their past environment, with stress legacy potentially playing a crucial role. In this study, we examined parental ramets of Duchesnea indica Focke that were subject to either a control or lead-contaminated environment (past environment), and their newborn offspring were then transplanted into control, homogeneous lead or heterogeneous lead environment (present environment). We analysed how past and present environments affect plant growth and DNA methylation in offspring. The result shown that the DNA methylation loci composition of offspring was affected by the interaction of parental environment and offspring environment, and DNA methylation levels were higher in heterogeneous environments. Moreover, our findings indicate that offspring would thrive in the heterogeneous lead environment if they did not experience lead pollution in the past, their progeny will avoid lead toxicity by reducing underground biomass allocation. However, when the parents experienced lead stress environment, their biomass allocation strategies disappeared, and they prefer to grow in favourable patches to avoid lead-contaminated patches. We concluded that the integration of historical parental exposure to lead-contaminated and current information about their offspring's environment are impacting plant phenotypes. It is possible that the stress legacy from the parents has been transmitted to their offspring ramets, and the stress legacy is at least partly based on heritable epigenetic variation. The phenotypic variation regulated by the stress legacy affects the growth performance, biomass allocation strategy, and even the behaviour of D. indica.

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Duchesnea indica克隆植物的DNA甲基化变异和生长受过去和现在铅环境的调节。
研究表明,克隆植物在异质环境中选择栖息地和觅食的能力受其过去环境的影响,而压力遗产可能起着至关重要的作用。在这项研究中,我们研究了受对照环境或铅污染环境(过去环境)影响的 Duchesnea indica Focke 的亲本柱头,然后将它们的新生后代移植到对照环境、同质铅环境或异质铅环境(现在环境)中。我们分析了过去和现在的环境对植物生长和后代 DNA 甲基化的影响。结果表明,子代的DNA甲基化位点组成受亲代环境和子代环境的交互影响,在异质环境中DNA甲基化水平更高。此外,我们的研究结果表明,如果亲本过去没有经历过铅污染,其后代会在异质铅环境中茁壮成长,其后代会通过减少地下生物量分配来避免铅毒性。然而,当亲本经历过铅胁迫环境时,它们的生物量分配策略就会消失,它们更愿意在有利的斑块中生长,以避开铅污染斑块。我们的结论是,亲本历史上暴露于铅污染环境的情况与子代当前所处环境的信息相结合,对植物表型产生了影响。亲本的压力遗产有可能已传递给子代植株,而压力遗产至少有一部分是基于可遗传的表观遗传变异。受胁迫遗传调节的表型变异会影响籼稻的生长表现、生物量分配策略甚至行为。
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来源期刊
Epigenetics
Epigenetics 生物-生化与分子生物学
CiteScore
6.80
自引率
2.70%
发文量
82
审稿时长
3-8 weeks
期刊介绍: Epigenetics publishes peer-reviewed original research and review articles that provide an unprecedented forum where epigenetic mechanisms and their role in diverse biological processes can be revealed, shared, and discussed. Epigenetics research studies heritable changes in gene expression caused by mechanisms others than the modification of the DNA sequence. Epigenetics therefore plays critical roles in a variety of biological systems, diseases, and disciplines. Topics of interest include (but are not limited to): DNA methylation Nucleosome positioning and modification Gene silencing Imprinting Nuclear reprogramming Chromatin remodeling Non-coding RNA Non-histone chromosomal elements Dosage compensation Nuclear organization Epigenetic therapy and diagnostics Nutrition and environmental epigenetics Cancer epigenetics Neuroepigenetics
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