Proteomic and physiological signatures of altitude adaptation in a Myrsine coriacea population under common garden conditions

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Roberta Pena da Paschoa , Vitor Batista Pinto , Jéssica Priscilla Pereira , Paulo Cezar Cavatte , Mário Luís Garbin , Tiago Godinho , Lucas Rodrigues Xavier , Tatiana Tavares Carrijo , Vanildo Silveira
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Abstract

Plants exhibit phenotypic plasticity in response to environmental variations, which can lead to stable genetic and physiological adaptations if exposure to specific conditions is prolonged. Myrsine coriacea demonstrates this through its ability to thrive in diverse environments. The objective of the article is to investigate potential differences in protein accumulation and physiological responses of M. coriacea by cultivating plants from seeds collected from four populations at different altitudes in a common garden experiment. Additionally, we aim to evaluate whether these differences exhibit genetic fixation. Through integrated physiological and proteomic analyses, we identified 170 differentially accumulated proteins and observed significant physiological differences among the populations. The high-altitude population (POP1) exhibited a unique proteomic profile with significant down-regulation of proteins involved in carbon fixation and energy metabolism, suggesting a potential reduction in photosynthetic efficiency. Physiological analyses showed lower leaf nitrogen content, net CO2 assimilation rate, specific leaf area, and relative growth rate in stem height for POP1, alongside higher leaf carbon isotopic composition (δ13C) and leaf carbon (C) content. These findings provide insight into the complex interplay between proteomic and physiological adaptations in M. coriacea and underscore the importance of local adaptations.

Significance

We investigate the adaptive responses of M. coriacea, a shrub with a broad phenotypic range, by cultivating plants from seeds collected at four different altitudes in a common garden experiment. These findings provide insight into the complex interplay between proteomic and physiological adaptations in M. coriacea and underscore the importance of local adaptations in the face of climate change. This study contributes to advancing our understanding of the influence of altitude-specific selection pressures on the molecular biology and physiology of plants in natural populations. Our findings provide valuable insights that enhance our ability to predict and comprehend how plants respond to climate change.

Abstract Image

在普通花园条件下,Myrsine coriacea 种群对海拔适应的蛋白质组和生理特征。
植物在应对环境变化时表现出表型可塑性,如果长期暴露在特定条件下,就会产生稳定的遗传和生理适应。Myrsine coriacea在不同环境中茁壮成长的能力就证明了这一点。本文的目的是通过在一个共同的花园实验中培养从不同海拔的四个种群中收集的种子所培育出的植物,研究M. coriacea在蛋白质积累和生理反应方面的潜在差异。此外,我们还旨在评估这些差异是否表现出遗传固定性。通过生理学和蛋白质组学综合分析,我们确定了 170 种不同积累的蛋白质,并观察到不同种群之间存在显著的生理差异。高海拔种群(POP1)表现出独特的蛋白质组特征,参与碳固定和能量代谢的蛋白质显著下调,表明光合效率可能降低。生理分析表明,POP1 的叶片氮含量、净二氧化碳同化率、比叶面积和茎高相对增长率较低,而叶片碳同位素组成(δ13C)和叶片碳(C)含量较高。这些发现深入揭示了冠突散囊菌蛋白质组和生理适应之间复杂的相互作用,并强调了局部适应的重要性。意义:我们通过在一个普通花园实验中培养从四种不同海拔高度收集的种子培育出的植物,研究了M. coriacea(一种表型范围很广的灌木)的适应性反应。这些发现深入揭示了M. coriacea蛋白质组和生理适应之间复杂的相互作用,并强调了当地适应气候变化的重要性。这项研究有助于加深我们对海拔特异性选择压力对自然种群中植物分子生物学和生理学影响的理解。我们的研究结果提供了宝贵的见解,提高了我们预测和理解植物如何应对气候变化的能力。
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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