沿资源化学计量梯度的最佳代谢调节

Optimal metabolic regulation along resource stoichiometry gradients.

作者信息

Manzoni Stefano, Čapek Petr, Mooshammer Maria, Lindahl Björn D, Richter Andreas, Šantrůčková Hana

机构信息

Department of Physical Geography and Bolin Centre for Climate Research, Stockholm University, Stockholm, Sweden.

Department of Ecosystem Biology, University of South Bohemia, České Budějovice, Czech Republic.

出版信息

Ecol Lett. 2017 Sep;20(9):1182-1191. doi: 10.1111/ele.12815. Epub 2017 Jul 30.

DOI:10.1111/ele.12815

PMID:28756629

Abstract

Most heterotrophic organisms feed on substrates that are poor in nutrients compared to their demand, leading to elemental imbalances that may constrain their growth and function. Flexible carbon (C)-use efficiency (CUE, C used for growth over C taken up) can represent a strategy to reduce elemental imbalances. Here, we argue that metabolic regulation has evolved to maximise the organism growth rate along gradients of nutrient availability and translated this assumption into an optimality model that links CUE to substrate and organism stoichiometry. The optimal CUE is predicted to decrease with increasing substrate C-to-nutrient ratio, and increase with nutrient amendment. These predictions are generally confirmed by empirical evidence from a new database of c. 2200 CUE estimates, lending support to the hypothesis that CUE is optimised across levels of organisation (microorganisms and animals), in aquatic and terrestrial systems, and when considering nitrogen or phosphorus as limiting nutrients.

摘要

与自身需求相比，大多数异养生物所摄取的底物营养匮乏，从而导致元素失衡，这可能会限制它们的生长和功能。灵活的碳（C）利用效率（CUE，即用于生长的C与摄取的C之比）可以代表一种减少元素失衡的策略。在此，我们认为代谢调节已经进化，以沿着养分可利用性梯度最大化生物体生长速率，并将这一假设转化为一个最优模型，该模型将CUE与底物和生物体化学计量联系起来。预计最优CUE会随着底物碳与养分比率的增加而降低，并随着养分添加而增加。来自一个约有2200个CUE估计值的新数据库的经验证据普遍证实了这些预测，支持了这样一种假设，即CUE在组织水平（微生物和动物）、水生和陆地系统以及将氮或磷视为限制养分的情况下都是最优的。

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沿资源化学计量梯度的最佳代谢调节

Optimal metabolic regulation along resource stoichiometry gradients.

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