Widespread adaptive evolution in angiosperm photosystems provides insight into the evolution of photosystem II repair

The Plant Cell Pub Date : 2024-10-15 DOI:10.1093/plcell/koae281

Elizabeth H J Robbins, Steven Kelly

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Abstract

Oxygenic photosynthesis generates the initial energy source that fuels nearly all life on Earth. At the heart of the process are the photosystems, which are pigment binding multi-protein complexes that catalyse the first step of photochemical conversion of light energy into chemical energy. Here, we investigate the molecular evolution of the plastid-encoded photosystem subunits at single-residue resolution across 773 angiosperm species. We show that despite an extremely high level of conservation, 7% of residues in the photosystems, spanning all photosystem subunits, exhibit hallmarks of adaptive evolution. Through in silico modelling of these adaptive substitutions, we uncover the impact of these changes on the predicted properties of the photosystems, focussing on their effects on co-factor binding and inter-subunit interface formation. By analyzing these cohorts of changes, we reveal that evolution has repeatedly altered the interaction between photosystem II and its D1 subunit in a manner that is predicted to reduce the energetic barrier for D1 turnover and photosystem repair. Together, these results provide insight into the trajectory of photosystem adaptation during angiosperm evolution.

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被子植物光合系统的广泛适应性进化为光合系统 II 修复的进化提供了启示

含氧光合作用是地球上几乎所有生命的最初能源来源。光合作用的核心是光系统，它是色素结合的多蛋白复合物，催化光能转化为化学能的第一步光化学过程。在这里，我们以单残基分辨率研究了 773 个被子植物物种中质体编码的光系统亚基的分子进化。我们的研究表明，尽管光合系统中的残基具有极高的保守性，但在所有光合系统亚基中仍有 7% 的残基表现出适应性进化的特征。通过对这些适应性取代进行硅建模，我们揭示了这些变化对光合系统预测特性的影响，重点是它们对辅助因子结合和亚基间界面形成的影响。通过分析这些变化，我们发现进化反复改变了光系统 II 与其 D1 亚基之间的相互作用，这种方式预计会降低 D1 转换和光系统修复的能量障碍。总之，这些结果让我们深入了解了被子植物进化过程中光合系统的适应轨迹。

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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The Plant Cell

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