五种蜥蜴在不同环境条件下的亚细胞能量代谢分析

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Anamarija Žagar , Urban Dajčman , Rodrigo Megía-Palma , Tatjana Simčič , Frederico M. Barroso , Senka Baškiera , Miguel A. Carretero
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引用次数: 0

摘要

有氧呼吸是大多数真核生物的主要能量来源,高效的线粒体能量转移在很大程度上影响着生物体的健康状况。为了在环境变化中生存,细胞进化到可以调整其生物化学。因此,在亚细胞水平测量能量代谢可以加深我们对个体表现、种群动态和物种分布范围的了解。我们在从海平面到海拔2000米的不同海拔高度采样的五个蜥蜴物种中研究了亚细胞水平的三个重要代谢特征。我们检测了血红蛋白浓度、氧化应激的两个标志物(过氧化氢酶活性和羰基浓度)以及亚细胞水平的最大代谢呼吸速率(电子传输系统的潜在代谢活性)。对实验室适应的成年雄性蜥蜴的性状进行了分析,以研究其对当地采样地点多变环境条件的适应性代谢反应。在28 °C、30 °C、32 °C和34 °C四种温度下测量了细胞水平的潜在代谢活动,这四种温度涵盖了所研究物种喜欢的体温范围。不同物种的血红蛋白含量、羰基浓度和潜在代谢活性没有显著差异。在过氧化氢酶活性方面发现了种间差异,所有五个物种的潜在代谢活性都随着温度的升高而增加。高山物种 Iberolacerta monticola 的代谢率随温度(Q10)和阿伦尼乌斯活化能(Ea)的变化最大。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Analysis of subcellular energy metabolism in five Lacertidae lizards across varied environmental conditions

Analysis of subcellular energy metabolism in five Lacertidae lizards across varied environmental conditions

Aerobic respiration is the main energy source for most eukaryotes, and efficient mitochondrial energy transfer greatly influences organismal fitness. To survive environmental changes, cells have evolved to adjust their biochemistry. Thus, measuring energy metabolism at the subcellular level can enhance our understanding of individual performance, population dynamics, and species distribution ranges. We investigated three important metabolic traits at the subcellular level in five lacertid lizard species sampled from different elevations, from sea level up to 2000 m. We examined hemoglobin concentration, two markers of oxidative stress (catalase activity and carbonyl concentration) and maximum rate of metabolic respiration at the subcellular level (potential metabolic activity at the electron transport system). The traits were analysed in laboratory acclimated adult male lizards to investigate the adaptive metabolic responses to the variable environmental conditions at the local sampling sites. Potential metabolic activity at the cellular level was measured at four temperatures – 28 °C, 30 °C, 32 °C and 34 °C – covering the range of preferred body temperatures of the species studied. Hemoglobin content, carbonyl concentration and potential metabolic activity did not differ significantly among species. Interspecific differences were found in the catalase activity, Potential metabolic activity increased with temperature in parallel in all five species. The highest response of the metabolic rate with temperature (Q10) and Arrhenius activation energy (Ea) was recorded in the high-mountain species Iberolacerta monticola.

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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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