微生物细胞对光暗交替的分子响应机制

doi:10.19586/j.2095-2341.2026.0023

生物技术进展 ›› 2026, Vol. 16 ›› Issue (2): 260-266.DOI: 10.19586/j.2095-2341.2026.0023

• 进展评述 • 上一篇

微生物细胞对光暗交替的分子响应机制

张建磊(), 卜凡立()

东平县东平街道办事处，山东泰安 271500

收稿日期:2026-01-12 接受日期:2026-02-01 出版日期:2026-03-25 发布日期:2026-04-27
通讯作者: 卜凡立
作者简介:张建磊 E-mail: dpjdxjb@163.com；

Molecular Response Mechanism of Microbial Cells to Light-dark Alternation

Jianlei ZHANG(), Fanli BU()

Dongping Sub-district Office，Dongping County of Shandong Province，Shandong Tai'an 271500，China

Received:2026-01-12 Accepted:2026-02-01 Online:2026-03-25 Published:2026-04-27
Contact: Fanli BU

摘要/Abstract

摘要：

光暗交替作为地球最基本的环境节律之一，对自然界和人工环境中微生物的生存与功能具有深远影响。微生物进化出了一系列精密而复杂的响应机制，以适应这种周期性的能量与信息输入变化。系统综述了微生物在光暗交替条件下，代谢、转录及蛋白质水平上的多维度响应机制。在代谢层面，微生物通过动态调整中心碳代谢、能量代谢和氧化还原平衡，优化能量获取与物质合成；在转录层面，以生物钟基因网络和光感知信号转导通路为核心，全局重编程基因表达，实现时间维度上的有序调控；在蛋白质层面，则通过转录后修饰、蛋白稳定性调控及复合体动态组装等策略，快速执行适应性功能。重点探讨了这三个层面响应机制的相互作用与整合，揭示其内在的时序性与网络化特征，并展望了其在合成生物学、生物制造及环境修复等领域的应用前景。

关键词: 光暗交替, 微生物, 代谢重编程, 转录调控, 蛋白质组

Abstract:

As one of the most fundamental environmental rhythms on earth， light-dark alternation exerts a profound impact on the survival and functions of microorganisms in both natural and artificial environments. Microbes have evolved a series of sophisticated and complex response mechanisms to adapt to such periodic changes in energy and information input. This review systematically summarized the multi-dimensional response mechanisms of microorganisms at the metabolic， transcriptional， and protein levels under light-dark alternation conditions. At the metabolic level， microorganisms dynamically regulate central carbon metabolism， energy metabolism， and redox balance to optimize energy acquisition and substance synthesis. At the transcriptional level， with circadian clock gene networks and light-sensing signal transduction pathways as the core， they globally reprogram gene expression to achieve orderly regulation in the temporal dimension. At the protein level， they rapidly perform adaptive functions through strategies such as post-translational modification， protein stability regulation， and dynamic assembly of protein complexes. This review focused on the interaction and integration of the response mechanisms at these three levels， revealed their inherent temporal and network characteristics， and looked forward to their application prospects in fields such as synthetic biology， biomanufacturing， and environmental remediation.

Key words: light-dark alternation, microorganism, metabolic reprogramming, transcriptional regulation, proteome

中图分类号:

Q932

张建磊, 卜凡立. 微生物细胞对光暗交替的分子响应机制[J]. 生物技术进展, 2026, 16(2): 260-266.

Jianlei ZHANG, Fanli BU. Molecular Response Mechanism of Microbial Cells to Light-dark Alternation[J]. Current Biotechnology, 2026, 16(2): 260-266.

图/表 1

参考文献 26

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微生物细胞对光暗交替的分子响应机制

Molecular Response Mechanism of Microbial Cells to Light-dark Alternation

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