利用电子传递系统作为机体热耐受性和呼吸利用的指标。

IF 1 4区 生物学 Q3 ZOOLOGY
E. Stell, S. Brewer, Lindsay Horne, R. Wright, D. DeVries
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引用次数: 0

摘要

淡水生态系统正在经历快速的热转换,因此了解物种对这些变化的特定反应变得越来越重要。测定一个物种的热耐受性的传统技术往往是致命的和耗时的。利用与电子传递系统(ETS)相关的酶活性;以下简称酶测定法)可以为某些物种提供一种非致死、快速和有效的替代传统技术的方法。本研究以大口黑鲈Micropterus salmoides Lacepede, 1802为实验材料,采用酶法测定不同驯化温度下的热耐受性和呼吸利用的有效性。从适应于20、25或30°C的鱼中解剖出三种组织类型,并在7.5-40°C的温度范围内用于ETS试验。不同组织类型和驯化温度之间存在显著差异,在25.23 ~ 31.91℃时酶活性最高。在传统的CTmax试验中,鱼在39-42°C时失去平衡,这明显高于通过酶分析确定的最高最佳范围。酶活性与测定的全生物呼吸速率之比随着水温的升高而降低,在酶测定的最适温度范围上变化最大。我们的研究结果表明,ETS分析可能有助于获得与生物学相关的热耐受性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Using the electron transport system as an indicator of organismal thermal tolerance and respiratory exploitation.
Freshwater ecosystems are undergoing rapid thermal shifts, making it increasingly important to understand species-specific responses to these changes. Traditional techniques for determining a species’ thermal tolerance are often lethal and time consuming. Using the enzyme activity associated with the electron transport system (ETS; hereafter referred to as enzyme assay) may provide a non-lethal, rapid, and efficient alternative to traditional techniques for some species. We used largemouth bass Micropterus salmoides Lacepede, 1802 to test the efficacy of using an enzyme assay to determine thermal tolerance and respiratory exploitation in response to variable acclimation temperatures. Three tissue types were dissected from fish acclimated to 20, 25, or 30°C and used in ETS assays at temperatures ranging from 7.5-40°C. While there were significant differences among tissue types and acclimation temperatures, maximal enzyme activity occurred from 25.23-31.91°C. Fish lost equilibrium at 39-42°C in traditional CTmax trials, significantly higher than the upper optimum range determined via enzyme assays. The ratio of enzyme activity to measured whole organism respiration rate decreased with increasing water temperature, with the largest changes occurring at the upper optimum thermal range determined by enzyme assays. Our results indicate ETS analysis may prove useful for obtaining biologically relevant thermal tolerances.
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来源期刊
Canadian Journal of Zoology
Canadian Journal of Zoology 生物-动物学
CiteScore
2.40
自引率
0.00%
发文量
82
审稿时长
3 months
期刊介绍: Published since 1929, the Canadian Journal of Zoology is a monthly journal that reports on primary research contributed by respected international scientists in the broad field of zoology, including behaviour, biochemistry and physiology, developmental biology, ecology, genetics, morphology and ultrastructure, parasitology and pathology, and systematics and evolution. It also invites experts to submit review articles on topics of current interest.
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