Adaptive Mechanism Exploration of Camellia limonia in Karst High Calcium Environment by Integrative Analysis of Metabolomics and Metagenomics

IF 1.8 4区 生物学 Q2 PLANT SCIENCES Tropical Plant Biology Pub Date : 2022-01-26 DOI:10.1007/s12042-021-09308-0
Chunni Liu, Yang Huang, Yu Liang
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引用次数: 2

Abstract

Camellia limonia is a kind of rare plant with high economic and medicinal value. It’s a plant species growing in calcareous soil of limestone, which means they can grow well in high calcium environment. Compared with C. limonia, Camellia nitidissima is a plant growing in acidic soil, which grows slowly or even dies in high calcium environment. However, there are few studies on C. limonia in karst soil environment and its adaptation mechanism is no clear. In this study, we found that under high calcium treatment, the chlorophyll content and leaf areas of C. limonia increased, while those of C. nitidissima decreased. The photosynthetic efficiency of C. limonia was more stable and higher than C. nitidissima. Compared with C. nitidissima, the conductance was larger and the degree of leaf shrinkage was smaller in C. limonia. The metabolomics analysis of both leaves showed that the kaempferol-3-o-rutinoside, tyrosol, 6-o-methyldeacetylisoipecoside and (r)-mandelic acid are the main differently metabolic compounds. The results of metagenomics in karst soil showed that the secretion (propylene oxide) of Acaryochloris marina in rhizosphere is closely related to the adaptation of C. nitidissima in high-calcium regions. Through metabolomics and metageomics integrative analysis, flavone and flavonol biosynthesis were suggested to be the main regulation pathway, which were regulated by metabolites apigenin, kaempferol, astragalin, isoquercitrin and genes TT7, UGT78D1, UGT78D2. This metabolic pathway involved the synthesis of flavonoids. Flavonoids have the characteristics of drought resistance and salt resistance, which play an important role in the adaptation of C. limonia in karst high calcium environment. This omics study identified key regulation metabolites and genes for Camellia and provided important basis for the adaptive mechanism of plants to adapt to the high-calcium environment and the protection of Camellia species.

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利用代谢组学和宏基因组学综合分析探究茶花在喀斯特高钙环境中的适应机制
山茶是一种具有较高经济价值和药用价值的珍稀植物。这是一种生长在石灰石钙质土壤中的植物,这意味着它们可以在高钙环境中生长得很好。与C. limonia相比,山茶是一种生长在酸性土壤中的植物,在高钙环境中生长缓慢甚至死亡。然而,国内外对羊草在喀斯特土壤环境中的研究较少,其适应机制也不明确。本研究发现,在高钙处理下,C. limonia的叶绿素含量和叶面积增加,而C. nitidissima的叶绿素含量和叶面积减少。柠檬草的光合效率稳定且高于牛皮草。与黑皮草相比,黑皮草电导较大,叶片收缩程度较小。代谢组学分析表明,山奈酚-3-o-芦丁苷、酪醇、6-o-甲基去乙酰异木香苷和(r)-扁桃酸是两种叶片代谢差异的主要成分。喀斯特土壤宏基因组学研究结果表明,绿心粉藻根际分泌(环氧丙烷)与C. nitidissima在高钙地区的适应密切相关。通过代谢组学和元组学综合分析,黄酮和黄酮醇的生物合成是主要的调控途径,代谢产物芹菜素、山奈酚、黄芪甲苷、异槲皮苷以及TT7、UGT78D1、UGT78D2基因调控黄酮和黄酮醇的生物合成。这种代谢途径涉及类黄酮的合成。黄酮类化合物具有抗旱和耐盐的特性,在柠檬草适应喀斯特高钙环境中起着重要作用。本组学研究确定了茶花的关键调控代谢产物和基因,为植物适应高钙环境的适应机制和茶花物种保护提供了重要依据。
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来源期刊
Tropical Plant Biology
Tropical Plant Biology PLANT SCIENCES-
CiteScore
3.70
自引率
0.00%
发文量
15
期刊介绍: Tropical Plant Biology covers the most rapidly advancing aspects of tropical plant biology including physiology, evolution, development, cellular and molecular biology, genetics, genomics, genomic ecology, and molecular breeding. It publishes articles of original research, but it also accepts review articles and publishes occasional special issues focused on a single tropical crop species or breakthrough. Information published in this journal guides effort to increase the productivity and quality of tropical plants and preserve the world’s plant diversity. The journal serves as the primary source of newly published information for researchers and professionals in all of the aforementioned areas of tropical science.
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