Within-Generation and Transgenerational Plasticity of a Temperate Salmonid in Response to Thermal Acclimation and Acute Temperature Stress.

IF 1.8 3区生物学 Q3 PHYSIOLOGY Physiological and Biochemical Zoology Pub Date : 2022-11-01 DOI:10.1086/721478

Chantelle M Penney, Joshua K R Tabh, Chris C Wilson, Gary Burness

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引用次数: 2

Abstract

AbstractThe rise in temperature associated with climate change may threaten the persistence of stenothermal organisms with limited capacities for beneficial thermal acclimation. We investigated the capacity for within-generation and transgenerational thermal responses in brook trout (Salvelinus fontinalis), a cold-adapted salmonid. Adult fish were acclimated to temperatures within (10°C) and above (21°C) their thermal optimum for 6 mo before spawning, then mated in a full factorial breeding design to produce offspring from cold- and warm-acclimated parents and bidirectional crosses between parents from both temperature treatments. Offspring from families were subdivided and reared at two acclimation temperatures representing their current (15°C) and anticipated future (19°C) habitat temperatures. Offspring thermal physiology was measured as the rate of oxygen consumption (Mo₂) during an acute change in temperature (increase of 2°C h^-1) to observe their Mo₂-temperature relationship. We recorded resting Mo₂, peak (highest achieved, thermally induced) Mo₂, and critical thermal maximum (CTM) as performance metrics. Although limited, within-generation plasticity was greater than transgenerational plasticity, with offspring warm acclimation elevating CTM by 0.5°C but slightly lowering peak thermally induced Mo₂. Transgenerational plasticity was evident as a slightly elevated resting Mo₂ and a shift of the Mo₂-temperature relationship to higher rates overall in offspring from warm-acclimated parents. Furthermore, offspring whose parents were warm acclimated were in worse condition than those whose parents were cold acclimated. Both parents contributed to offspring thermal responses; however, the paternal effect was stronger. Despite the existence of within-generation and transgenerational plasticity in brook trout, it is unlikely that these will be sufficient for coping with long-term changes to environmental temperatures.

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温带鲑科鱼对热驯化和急性温度胁迫的代内和跨代可塑性。

摘要与气候变化相关的温度升高可能威胁到具有有限热适应能力的低温生物的持续生存。我们研究了布鲁克鳟鱼(Salvelinus fontinalis)的代内和跨代热反应能力，这是一种适应冷的鲑鱼。成鱼在产卵前6个月适应温度在(10°C)和(21°C)以上的最佳温度，然后在全因子育种设计中交配，从冷驯化和热驯化的亲本中产生后代，并在两种温度处理的亲本之间进行双向杂交。对来自家庭的后代进行细分，并在代表其当前(15°C)和预期未来(19°C)栖息地温度的两种驯化温度下饲养。后代热生理测量为急性温度变化(升高2°C h-1)时的耗氧量(Mo2)，观察它们的Mo2-温度关系。我们记录了静息Mo2、峰值(热诱导的最高)Mo2和临界热最大值(CTM)作为性能指标。尽管有限，但代内可塑性大于跨代可塑性，后代热驯化使CTM升高0.5°C，但略微降低热诱导Mo2峰值。跨代可塑性是明显的，因为在温暖环境的父母的后代中，静止Mo2的轻微升高和Mo2-温度关系的转变总体上更高。此外，父母温驯化的后代比父母冷驯化的后代更差。父母双方都对后代的热反应有贡献;然而，父亲的影响更强。尽管布鲁克鳟鱼存在代内和跨代可塑性，但这些不太可能足以应对环境温度的长期变化。

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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来源期刊

Physiological and Biochemical Zoology 生物-动物学

CiteScore

3.20

自引率

6.20%

发文量

审稿时长

6-12 weeks

期刊介绍： Physiological and Biochemical Zoology: Ecological and Evolutionary Approaches primarily publishes original research in animal physiology and biochemistry as considered from behavioral, ecological, and/or evolutionary perspectives. Studies at all levels of biological organization from the molecular to the whole organism are welcome, and work that integrates across levels of organization is particularly encouraged. Studies that focus on behavior or morphology are welcome, so long as they include ties to physiology or biochemistry, in addition to having an ecological or evolutionary context. Subdisciplines of interest include nutrition and digestion, salt and water balance, epithelial and membrane transport, gas exchange and transport, acid-base balance, temperature adaptation, energetics, structure and function of macromolecules, chemical coordination and signal transduction, nitrogen metabolism and excretion, locomotion and muscle function, biomechanics, circulation, behavioral, comparative and mechanistic endocrinology, sensory physiology, neural coordination, and ecotoxicology ecoimmunology.