Paul Anna-Lisa, Haveman Natasha, Califar Brandon, Ferl Robert J
Plant Molecular and Cellular Biology Program, University of Florida, Gainesville, FL, United States.
Horticultural Sciences Department, University of Florida, Gainesville, FL, United States.
Front Plant Sci. 2021 Sep 13;12:691790. doi: 10.3389/fpls.2021.691790. eCollection 2021.
Plants subjected to the novel environment of spaceflight show transcriptomic changes that resemble aspects of several terrestrial abiotic stress responses. Under investigation here is whether epigenetic modulations, similar to those that occur in terrestrial stress responses, have a functional role in spaceflight physiological adaptation. The Advanced Plant Experiment-04 - Epigenetic Expression experiment examined the role of cytosine methylation in spaceflight adaptation. The experiment was conducted onboard the International Space Station, and evaluated the spaceflight-altered, genome-wide methylation profiles of two methylation-regulating gene mutants [methyltransferase 1 ( and elongator complex subunit 2 ()] along with a wild-type Col-0 control. The plants suffered in their physiological adaptation to spaceflight in that their roots failed to extend away from the seed and the overall development of the plants was greatly impaired in space. The plants suffered less, with their morphology affected by spaceflight in a manner similar to that of the Col-0 controls. The differentially expressed genes (DEGs) in spaceflight were dramatically different in the and plants compared to Col-0, indicating that the disruptions in these mutants resulted in a reprogramming of their spaceflight responses, especially in . Many of the genes comprising the spaceflight transcriptome of each genotype were differentially methylated in spaceflight. In Col-0 the majority of the DEGs were representative of the now familiar spaceflight response, which includes genes associated with cell wall remodeling, pathogen responses and ROS signaling. However, the spaceflight transcriptomes of and each presented patterns of DEGs that are almost completely different than Col-0, and to each other. Further, the DEGs of the mutant genotypes suggest a more severe spaceflight stress response in the mutants, particularly in . Arabidopsis physiological adaptation to spaceflight results in differential DNA methylation in an organ-specific manner. Disruption of Met1 methyltransferase function does not dramatically affect spaceflight growth or morphology, yet reprograms the spaceflight transcriptomic response in a unique manner. Disruption of results in poor development in spaceflight grown plants, together with a diminished, dramatically reprogrammed transcriptomic response.
经历太空飞行新环境的植物表现出转录组变化,这些变化类似于几种陆地非生物胁迫反应的某些方面。这里正在研究的是,类似于陆地胁迫反应中发生的表观遗传调控,是否在太空飞行生理适应中发挥功能作用。高级植物实验-04 - 表观遗传表达实验研究了胞嘧啶甲基化在太空飞行适应中的作用。该实验在国际空间站上进行,评估了两个甲基化调节基因突变体[甲基转移酶1()和延伸因子复合物亚基2()]以及野生型Col-0对照在太空飞行中改变的全基因组甲基化谱。植物在对太空飞行的生理适应方面遇到困难,因为它们的根未能从种子中延伸出来,并且植物的整体发育在太空中受到极大损害。植物受影响较小,其形态受到太空飞行的影响,方式与Col-0对照相似。与Col-0相比,太空飞行中差异表达基因(DEGs)在和植物中差异显著,表明这些突变体中的破坏导致了它们太空飞行反应的重新编程,尤其是在中。每个基因型的太空飞行转录组中的许多基因在太空飞行中甲基化不同。在Col-0中,大多数DEGs代表了现在熟悉的太空飞行反应,其中包括与细胞壁重塑、病原体反应和ROS信号相关的基因。然而,和的太空飞行转录组各自呈现出与Col-0几乎完全不同且彼此不同的DEGs模式。此外,突变基因型的DEGs表明突变体中太空飞行应激反应更严重,尤其是在中。拟南芥对太空飞行的生理适应导致器官特异性的DNA甲基化差异。Met1甲基转移酶功能的破坏不会显著影响太空飞行生长或形态,但会以独特的方式重新编程太空飞行转录组反应。的破坏导致太空飞行生长的植物发育不良,同时转录组反应减少且显著重新编程。
