转录和代谢洞察拟南芥对最佳和超最佳大气 CO2 的差异生理响应。

Transcriptional and metabolic insights into the differential physiological responses of arabidopsis to optimal and supraoptimal atmospheric CO2.

机构信息

Center for Medical, Agricultural and Veterinary Entomology, Agricultural Research Service, United States Department of Agriculture (USDA-ARS), Gainesville, Florida, USA.

出版信息

PLoS One. 2012;7(8):e43583. doi: 10.1371/journal.pone.0043583. Epub 2012 Aug 20.

DOI:10.1371/journal.pone.0043583

PMID:22916280

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3423350/

Abstract

BACKGROUND

In tightly closed human habitats such as space stations, locations near volcano vents and closed culture vessels, atmospheric CO(2) concentration may be 10 to 20 times greater than Earth's current ambient levels. It is known that super-elevated (SE) CO(2) (>1,200 µmol mol(-1)) induces physiological responses different from that of moderately elevated CO(2) (up to 1,200 µmol mol(-1)), but little is known about the molecular responses of plants to supra-optimal [CO(2)].

METHODOLOGY/PRINCIPAL FINDINGS: To understand the underlying molecular causes for differential physiological responses, metabolite and transcript profiles were analyzed in aerial tissue of Arabidopsis plants, which were grown under ambient atmospheric CO(2) (400 µmol mol(-1)), elevated CO(2) (1,200 µmol mol(-1)) and SE CO(2) (4,000 µmol mol(-1)), at two developmental stages early and late vegetative stage. Transcript and metabolite profiling revealed very different responses to elevated versus SE [CO(2)]. The transcript profiles of SE CO(2) treated plants were closer to that of the control. Development stage had a clear effect on plant molecular response to elevated and SE [CO(2)]. Photosynthetic acclimation in terms of down-regulation of photosynthetic gene expression was observed in response to elevated [CO(2)], but not that of SE [CO(2)] providing the first molecular evidence that there appears to be a fundamental disparity in the way plants respond to elevated and SE [CO(2)]. Although starch accumulation was induced by both elevated and SE [CO(2)], the increase was less at the late vegetative stage and accompanied by higher soluble sugar content suggesting an increased starch breakdown to meet sink strength resulting from the rapid growth demand. Furthermore, many of the elevated and SE CO(2)-responsive genes found in the present study are also regulated by plant hormone and stress.

CONCLUSIONS/SIGNIFICANCE: This study provides new insights into plant acclimation to elevated and SE [CO(2)] during development and how this relates to stress, sugar and hormone signaling.

摘要

背景

在空间站、火山口附近和封闭培养容器等密闭的人类栖息地中，大气中的二氧化碳浓度可能是地球目前环境水平的 10 到 20 倍。已知超高浓度（SE）二氧化碳（>1200μmol mol(-1))）引起的生理反应与中高浓度二氧化碳（高达 1200μmol mol(-1)))）不同，但对植物对超最佳 [CO(2)] 的分子反应知之甚少。

方法/主要发现：为了了解植物对不同生理反应的潜在分子原因，分析了在大气二氧化碳浓度为 400μmol mol(-1))、中高浓度二氧化碳（1200μmol mol(-1)))）和 SE CO(2)（4000μmol mol(-1)))）下生长的拟南芥植株气生组织的代谢物和转录谱。在早期和晚期营养阶段两个发育阶段。转录和代谢物谱分析显示，高浓度和 SE [CO(2)] 处理的植物对高浓度和 SE [CO(2)] 的反应非常不同。SE CO(2)处理植物的转录谱更接近对照。发育阶段对植物对高浓度和 SE [CO(2)] 的分子反应有明显影响。在响应高浓度 [CO(2)] 时观察到光合作用基因表达下调的光合适应，但在 SE [CO(2)] 中没有观察到，这首次提供了分子证据，表明植物对高浓度和 SE [CO(2)] 的反应方式似乎存在根本差异。尽管淀粉积累是由高浓度和 SE [CO(2)] 引起的，但在晚期营养阶段的增加较少，并且伴随着更高的可溶性糖含量，这表明为了满足快速生长需求的吸收强度，淀粉分解增加。此外，本研究中发现的许多对高浓度和 SE CO(2)有反应的基因也受植物激素和胁迫的调节。

结论/意义：本研究为植物在发育过程中对高浓度和 SE [CO(2)] 的适应提供了新的见解，以及这与胁迫、糖和激素信号之间的关系。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ca1d/3423350/b4245bdfeea8/pone.0043583.g001.jpg

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转录和代谢洞察拟南芥对最佳和超最佳大气 CO2 的差异生理响应。

Transcriptional and metabolic insights into the differential physiological responses of arabidopsis to optimal and supraoptimal atmospheric CO2.

机构信息

出版信息

BACKGROUND

背景

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