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Chronic Social Stress Impairs the Thermal Tolerance of Rainbow Trout (Oncorhynchus Mykiss)Bard, Brittany 15 July 2020 (has links)
Juvenile rainbow trout (Oncorhynchus mykiss) held in pairs form dominance hierarchies, with subordinate individuals experiencing chronic social stress, as evidenced by prolonged elevation of the stress hormone cortisol. Prior work revealed that the thermal tolerance (measured as critical thermal maximum, CTmax) of subordinate fish was reduced, but the cause of this impairment was unknown. Here we tested the hypothesis that reduced thermal tolerance in subordinate trout is caused by prolonged elevation of circulating cortisol levels, affecting cardiac structure and function. In support of this hypothesis, subordinate trout that were allowed to recover from social stress for 48 h, a period sufficient to return cortisol to normal baseline levels, no longer showed a reduced CTmax. Furthermore, treatment of subordinates with cortisol to maintain elevated cortisol levels during the period of recovery from social stress prevented thermal tolerance from recovering. The possibility that prolonged elevation of cortisol levels induces cardiac remodelling in subordinate trout was explored by assessing heart histology and cardiac remodelling markers, and monitoring heart rate (fH). Picrosirius red staining revealed lower collagen levels in the ventricles of subordinate relative to dominant trout, although this difference was not accompanied by changes in collagen type I transcript abundances or protein levels, or by changes in markers of collagen turnover. Transcript abundances of markers of cardiac remodelling and ventricle mass were not significantly altered by chronic social stress. Heart rate in subordinates during social interactions was comparable to that in dominant fish. However, differences in fH responses of subordinate versus dominant fish were detected during acute warming. Specifically, peak heart rates tended to be observed at lower temperatures in subordinate fish relative to dominant. Thus, high baseline cortisol levels in subordinate trout result in lowered thermal tolerance, and chronic social stress has only minor effects on cardiac structure and function.
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PHYSIOLOGICAL, ECOLOGICAL, AND MICROBIAL FACTORS SHAPING THERMAL TOLERANCE AND PERFORMANCE IN ECTOTHERMIC VERTEBRATESDallas, Jason Warren 01 August 2023 (has links) (PDF)
Temperature represents a major driving force in biology as it influences essential functions across multiple levels of biological organization. The role of temperature is especially important for ectothermic animals, whose biotic processes are dependent on both body and environmental temperature. Assessing the relationship between temperature and organismal performance represents an important research direction as temperatures continue to warm under anthropogenic climate change. Chapters two and three are focused on a recently colonized population of the invasive Mediterranean House Geckos at the northern edge of their invasion front. These chapters examine the ecological and physiological factors that enable these lizards to persist in a cooler and more temperate environment than their native range. The thermal breadth of a reptile greatly influences its ability to tolerate a thermally variable environment, particularly when environmental options are limited for behavioral thermoregulation. These chapters explore the thermal performance of this species, and the results show that the eurythermality of these geckos promotes their rapid colonization of novel environments despite experiencing prolonged periods of cool temperatures. Chapters four, five, and six, by contrast, shift focus to larval amphibians to explore the constraints and factors underlying plasticity in acclimation to temperature extremes. As habitats continue to warm with climate change, ectotherms with limited capacity to thermoregulate, such as larval amphibians in shallow ponds, will be under a heightened threat of heat stress and mortality. Resultantly, identifying different factors that can increase organismal heat tolerance would reduce the risk of overheating and promote survival. Chapters four, five, and six explore this topic by measuring the critical thermal maximum (CTmax) of larval wood frogs. Chapter four focuses on the tradeoff between basal CTmax and plasticity of CTmax and its consequences for how a larval anuran responds to an acute heat shock. Chapter five examines the role a viral pathogen, ranavirus, has on larval CTmax. Surprisingly, a lethal dose of ranavirus did not reduce CTmax which goes against the common pattern of pathogenic infections lowering host heat tolerance. Lastly, chapter six explores the relationship between the gut microbiota and host CTmax with a particular focus on cross-species microbiota transplants. In line with our prediction, transplanting the gut microbiota of a heat-tolerant donor species promoted greater CTmax in the heat-sensitive recipient species.
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Upper thermal limits differ among component species in a host-parasitoid-hyperparasitoid systemJoshi, Kanchan A 01 January 2016 (has links)
Among the predicted impacts associated with global climate change, warming is of special interest because the rates of physiological processes are temperature-dependent. Insects and other ectotherms are likely to be affected due to their limited ability to control body temperature. In this study, I measured the tolerance to extreme high temperatures, i.e., critical thermal maximum (CTmax), of component species in a tri-trophic system, including an herbivore (Manduca sexta), a primary larval parasitoid (Cotesia congregata) and a hyperparasitoid (genus Silochalcis). For wild insects, the parasitoid had the lowest CTmax, the hyperparasitoid had the highest, and the herbivore was intermediate. For laboratory insects, the parasitoid had a lower CTmax than the herbivore. Results suggest that laboratory colonies can be used to predict relative thermal performance of interacting species in the field. Variations in tolerance to high temperature among component species could disrupt the outcome of interactions in multi-trophic systems.
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Temperatura crítica máxima de artrópodes em biomas brasileiros: uma abordagem macrofisiológica / Critical thermal maximum of arthropods in brazilian biomes: macrophysiological approachSilva, Antonio Carlos da 08 September 2016 (has links)
As mudanças climáticas influenciarão as médias de temperaturas ambientais e a frequência de eventos extremos com consequências ainda desconhecidas para a fauna. Conhecer os limites fisiológicos dos organismos ao aumento de temperatura pode ajudar a ampliar os marcos conceituais dos impactos regionais das mudanças climáticas sobre a fauna. Este trabalho abordou como a diversidade fisiológica representada pela tolerância termal da fauna de artrópodes terrestres estava relacionada entre os biomas do Brasil, em uma perspectiva macrofisiológica (ampla escala espacial). Especificamente, coletou-se a temperatura crítica máxima (TCMax) de espécimens de artrópodes das Classes Arachnida, Chilopoda, Dipoploda, Entognatha (Collembola), Insecta e Malacostraca (Oniscidea) nos biomas de Mata Atlântica (strictu sensu), Mata Atlântica de Altitude, Cerrado, Amazônia e Caatinga. Os artrópodes foram utilizados como modelo de estudo por permitirem uma associação mais clara com a teoria disponível sobre limites fisiológicos e o ambiente físico. Assim, foram investigados padrões de variação da TCMax entre e dentro dos biomas, considerando ou não a categoria sistemática. Igualmente, foi avaliada a relação da TCMax da fauna de artrópodes com variáveis bioclimáticas representantes do ambiente termal nos biomas. No aspecto de margem de segurança termal, avaliou-se a potencial tolerância ao aquecimento da fauna de artrópodes nos biomas. Os resultados mostraram que existe ampla diversidade fisiológica da fauna de artrópodes, com padrões atrelados aos biomas do Brasil. A relação do padrão de tolerância termal dos espécimens de artrópodes com o bioma é complexa, havendo nuances de variação dentro e entre os biomas. Houve grande proporção de fauna termotolerante no bioma da Caatinga e menor proporção de fauna termotolerante na Mata Atlântica. Quanto às margens de segurança termal, os dados de tolerância ao aquecimento sugerem que não há grande susceptibilidade ao aquecimento da fauna de artrópodes nos biomas do Brasil. Este trabalho contribui para ampliar a discussão dos possíveis impactos das mudanças climáticas em seus aspectos regionais, tendo em vista a diversidade fisiológica da fauna de artrópodes terrestres nos biomas brasileiros. Igualmente, os dados podem servir como uma importante base para a incorporação em avaliações globais da vulnerabilidade dos ectotérmicos frente às mudanças do clima / Climate change will affect the average environmental temperatures and the frequency of extreme events with still unknown consequences for wildlife. To understand the physiological limits of organisms in relation to the increase in environmental temperature can help extend the conceptual frameworks of climate change regional impacts on wildlife. This work discussed how the physiological diversity represented by the thermal tolerance of terrestrial arthropod fauna was related among biomes of Brazil in a macrophysiological perspective (large spatial scale). It was collected critical thermal maximum (CTMax) of specimens of the class Arachnida, Chilopoda, Dipoploda, Entognatha (Collembola), Insecta and Malacostraca (Oniscidea) in the biomes of the Atlantic Forest (strictu sensu), Atlantic Forest Highland, Cerrado (Brazilian Savanna), Amazonia and Caatinga. The arthropods were used as model to allow a better association with the available theory of physiological limits and the physical environment. Thus, it was investigated variation in patterns of CTMax between and within biomes considering or not the systematic category. It was also evaluated the relationship of CTMax of the arthropod fauna with bioclimatic variables as representative of the thermal environment in the biomes. In terms of thermal safety margin, it was evaluated potential warming tolerance of the arthropod fauna in the biomes. The results showed that there is a broad physiological diversity of arthropod fauna with patterns linked to brazilian biomes. The ratio between thermal tolerance patterns of arthropod specimens and the biome is complex, there were varying nuances within and between biomes. There is a large proportion of thermotolerant fauna in the Caatinga biome and a lesser proportion of thermotolerant fauna in the Atlantic Forest. The warming tolerance data suggest that the susceptibility to heat of the arthropod fauna in brazilian biomes is small. This work will help to expand discussions of potential impacts of climate change regional aspects considering the view of the physiological diversity of terrestrial arthropod fauna in the brazilian biomes. In addition, the data can be as an important basis for incorporation into global vulnerability assessments on terrestrial ectotherms in view of climate change
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Adjusting to the extreme : Thermal adaptation in a freshwater gastropodJohansson, Magnus January 2015 (has links)
Temperature is a ubiquitous force influencing biological processes ranging from cellular responses to life span. The thermal environment for many organisms is predicted to change with globally increasing temperatures and studies conducted in natural systems incorporating various evolutionary forces, such as gene flow, is needed. In my thesis, I investigate how snails (Radix balthica) originating from distinct geothermal environments within Lake Mývatn in northern Iceland have adapted, both genetically and phenotypically, to the respective thermal regime. Locations were classified as either cold, warm or seasonal depending on the average and variance in temperature. A high resolution spatial distribution of genetic variation within Mývatn was obtained using both neutral and outlier AFLPs. In addition, the genetic profile enabled me identify warm origin snails irrespective of geographic location in Iceland. Warm environments were often more stressful than cold or seasonal environments but snails originating from a high temperature location benefited from increased performance elsewhere. Patterns of growth were identical in both common garden and reciprocal transplant experiment; warm origin snails grew faster than both cold and seasonal origin snails. This result is in concordance with quantitative genetics models of thermal adaptation but suggesting cogradient rather than countergradient variation. Although warm origin snails generally had superior performance, survival at cold temperatures (< 12 °C) was reduced. All snails matured at similar size in the common garden experiment but cold origin snails were observed to mature later and lay fewer eggs. Also, snails had a common optimum for growth rate at 20 °C irrespective of thermal origin. This is arguably the reason why snails were observed to have a common thermal preference. Interestingly, warm origin snails had a reduced tolerance to high temperatures compared to cold and seasonal origin snails which did not differ in tolerance. Putatively, natural selection has reduced a putatively unnecessary trait (high temperature tolerance in a stable thermal environment) in favour of higher growth rate and performance in warm habitats. In conclusion, the price of high performance in a warm environment was paid in terms of reduced survival at low temperatures and a potential disadvantage of reduced genetic variability.
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