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Studies on horizontal cells of the carp retina with special reference to temperature and calciumCunningham, Jonathan R. C. January 1995 (has links)
Carp [Cyprinus carpio) were acclimated to 8±1 C, 16±1.5 C and 26±1 C. Dark adapted retinas were isolated and light induced responses of HI horizontal cells recorded. The dynamic range of these cells was affected by temperature, showing a decrease on heating or cooling from an optimum temperature. The effect of acclimation was to shift this optimum in an adaptive manner. A move from 16 C to 8 C resulted in ~44% acclimation, while a move from 16 C to 26 C resulted in ~67% acclimation. The rates of change of membrane potential and latency of the response also showed adaptive changes on acclimation. Isolated horizontal cells were voltage clamped using the whole cell patch clamp technique. The current-voltage (I-V) relationship of the prominent anomalous rectifier current was displaced by changes in the extracellular potassium concentration and was blocked by Ba(^2+) or Rb(^+). Its amplitude did not appear to be affected by thermal acclimation. A pharmacologically isolated sustained Ca(^2+) current, with an I-V relationship characteristic of an L-type current, also showed no apparent thermal acclimation. The ratiometric calcium indicator Fura-2 was used to measure the intracellular calcium concentration in isolated horizontal cells. The intracellular calcium concentration rose on depolarization of the cells, in an extracellular calcium concentration dependent manner. This increase was blocked by various metal ions with varying sensitivities: La(^3+)>Cd(^2+)>Cu(^2+)>Co≥Ni(^2+). The rate of change of intracellular calcium concentration was increased by increased temperature, but did not appear to be affected by thermal acclimation. Sustained depolarizations (up to 15 minutes) resulted in sustained elevations in intracellular calcium concentration proportional to the degree of depolarization. Possible mechanisms underlying the long and short term effects of temperature on the horizontal cell responses are discussed. The sustained calcium current and the intracellular calcium concentration changes are disscused in terms of the potential roles of this current and the significance of the subsequent intracellular calcium concentration changes.
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Thermal Physiology and Responses to Climate Change in a Montane, Desert Lizard CommunityClifton, Ian T. January 2021 (has links)
No description available.
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The roles of transient receptor potential channels in thermostatic behavior, in thermal acclimation, and in tonic immobility in the red flour beetle, Tribolium castaneum (coleoptera: tenebrionidae)Kim, Hong Geun January 1900 (has links)
Doctor of Philosophy / Department of Entomology / David C. Margolies and Yoonseong Park / Organisms are capable of sensing environmental conditions through diverse mechanisms. Transient receptor potential channels (TRPs) are a cation channel family that has been found to function in diverse sensing mechanisms. In this dissertation, I identified the function of several TRPs in thermosensing and mechanosensing in the red flour beetle, Tribolium castaneum. Candidate TRPs were chosen based on homology to TRPs found and studied in Drosophila melanogaster. To identify the function of candidate TRPs in T. castaneum, I suppressed the expression of target genes by RNA interference technique and investigated the phenotype of each treated beetle.
Temperature is a major limiting environmental factor for organisms. I tested the function of candidate TRPs in thermotaxis (behavior) and thermal acclimation (physiology). Using bioinformatics approaches, I identified three candidate TRPs – painless, pyrexia, and trpA1 – involved in high temperature sensing. To test thermotactic behavior, I investigated beetle movement on a temperature arena with two separate temperature zones. Thermal acclimation was tested by pre-exposing beetles to either 42 °C for 10 min. When treated with double stranded RNA of TRPA1 (dstrpA1), the thermotactic response of beetles at 39 and 42 °C was reduced when compared to control groups. With pre-exposure at 42 °C, survivorship of dstrpA1-treated beetles significantly increased after one minute exposure at 52 °C compared to beetles that were not pre-exposed. With dspainless treatment, beetles showed lower response to thermal acclimation and lower long-term survivorship. Beetles treated with dspyrexia showed lower recovery after heat treatment without pre-exposure at 42 °C.
To identify the function of candidate TRPs in mechanosensing, I evaluated dsRNA treated beetles for survival, walking behavior, and tonic immobility. Treatment with dsnompC and dstrpA5 resulted in failure in eclosion, causing 93 % mortality in both treatments. Survivors in dsnompC showed defects in elytra sclerotization. In dsnanchung and dsinactive treatments, adults showed abnormal walking behavior and reduced walking speed that were likely caused by defects of mechanosensing in folding of the joint between the femur and tibia. For tonic immobility, beetles with dsnanchung, dsinactive, dswaterwitch and dsick2 (insect cytokine 2) treatments showed increased sensitivity to mechanical stimulation leading to tonic immobility.
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ENVIRONMENTAL SENSITIVITY OF MITOCHONDRIAL GENE EXPRESSION IN FISHBREMER, KATHARINA 22 October 2013 (has links)
Maintaining energy organismal homeostasis under changing physiological and environmental conditions is vital, and requires constant adjustments of the energy metabolism. Central to meeting energy demands is the regulation of mitochondrial oxidative capacity. When demands increase, animals can increase mitochondrial content/enzymes, known as mitochondrial biogenesis. Central to mammalian mitochondrial biogenesis is the transcriptional master regulator PPARγ (peroxisome proliferator-activated receptor γ) coactivator-1α (PGC-1α), and the network of DNA-binding proteins it coactivates (e.g. nuclear respiratory factor 1 and 2 [NRF-1, NRF-2], estrogen-related receptor α [ERRα], thyroid receptor α [TRα-1], retinoid X receptor α [RXRα]). However, the mechanisms by which mitochondrial content in lower vertebrates such as fish is controlled are less studied.
In my study I investigate underlying mechanisms of the phenomenon that many fish species alter mitochondrial enzyme activities, such as cytochrome c oxidase (COX) in response to low temperatures. In particular, I investigated (i) if the phenomenon of mitochondrial biogenesis during cold-acclimation is related to fish phylogeny, (ii) what role PGC-1α and other transcription factors play in mitochondrial biogenesis in fish, and (iii) if mRNA decay rates are important in the transcriptional control of a multimeric protein like COX.
This study shows that mitochondrial biogenesis does not follow a phylogenetic pattern: while distantly related species displayed the same response to low temperatures, closely related species showed opposite responses. In species exhibiting mitochondrial biogenesis, little evidence was found for PGC-1α as a master regulator, whereas NRF-1 is supported to be an important regulator in mitochondrial biogenesis in fish. Further, there was little support for other transcription factors (NRF-2, ERRα, TRα-1, RXRα) to be part of the regulatory network.
Lastly, results on the post-transcriptional control mechanism of mRNA decay indicate that this mechanism is important in the regulation of COX under mitochondrial biogenesis: it accounts for up to 30% of the change in subunit transcript levels.
In summary, there is no simple temperature-dependent mitochondrial response ubiquitous in fish. Further, the pathways controlling mitochondrial content in fish differ from mammals in the important master regulator PGC-1α, however, NRF-1 is important in regulating cold-induced mitochondrial biogenesis in fish. Lastly, COX subunit mRNA decay rates seem to have a part in controlling COX amounts during mitochondrial biogenesis. / Thesis (Ph.D, Biology) -- Queen's University, 2013-10-21 09:53:59.46
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Genomics and physiological evolution of cold tolerance in Drosophila melanogasterGerken, Alison Renae January 1900 (has links)
Doctor of Philosophy / Division of Biology / Theodore J. Morgan / Thermal stress impacts animals around the globe and understanding how organisms adapt to changes in temperature is of particular interest under current climate change predictions. My research focuses on the evolutionary genetics involved in cold tolerance and plasticity of cold tolerance using both artificially selected and naturally segregating populations, while tying the genes of interest to their physiological components. First I address cross-tolerance of stress traits following artificial selection to a non-lethal cold tolerance metric, chill-coma recovery. Using these artificial selection populations, we found that stress traits such as desiccation tolerance, starvation tolerance, acclimation, and chronic and acute cold tolerance do not correlate with level of cold tolerance as defined by chill-coma recovery time. We next assessed lifetime fitness of these different cold tolerance lines and found that only at low temperatures did fitness differ among cold tolerance levels. We then analyzed gene expression differences between resistant and susceptible populations at three time points to understand where selection pressures are hypothesized to act on genomic variation. Our gene expression analyses found many differences between resistant and susceptible lines, primarily manifesting themselves in the recovery period following cold exposure. We next utilized a community resource, the Drosophila melanogaster reference panel, to identify naturally segregating variation in genes associated with cold acclimation and fitness. We specifically asked if long- and short-term acclimation ability had overlapping genetic regions and if plasticity values from constant rearing environments were associated with demographic parameters in fluctuating environments. We found that long- and short-term acclimation are under unique genetic control and functionally tested several genes for acclimation ability. We also found that acclimation ability in constant environments and fitness in fluctuating environments do not correlate, but that genotypes are constrained in their fitness abilities between a warm and cool environment. Our analyses describe several novel genes associated with cold tolerance selection and long- and short-term acclimation expanding our knowledge of the complex relationship between demographic components and survivorship as well as a unique investigation of the change in gene expression during cold exposure.
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Phenotypic Plasticity and Population-level Variation in Thermal Physiology of the Bumblebee 'Bombus impatiens'Rivière, Bénédicte Aurélie 17 April 2012 (has links)
Temperature variation affects most biological parameters from the molecular level to community structure and dynamics. Current studies on thermal biology assess how populations vary in response to environmental temperature, which can help determine how populations differentially respond to climate change. To date, temperature fluctuation effects on endothermic poikilotherms such as the common eastern bumblebee (Bombus impatiens) are unknown even though bumblebees are the most important natural pollinators in North America. A cold-acclimation experiment with B. impatiens colonies revealed individuals acclimated to 5°C or 10°C at night did not differ in resting metabolic rate, flight metabolic rate, wingbeat frequency, or morphological measurements, compared to the control group. Moreover, an infrared camera showed that all colonies maintained maximum nest temperature consistently above 36.8°C. A latitudinal sampling of flight metabolic rate and morphological measurements of B. impatiens from four locations spanning Ontario (N 45°; W 75°) to North Carolina (N 34°; W 77°) indicated no latitudinal trend in the measured variables. This study shows that bumblebees are well equipped to face a wide range of environmental temperatures, both in the short term and long term, and can use a combination of behavioural and physiological mechanisms to regulate body and nest temperatures. These results are reassuring on the direct effects of climate change on bumblebee ecology, but further studies on the indirect effect of temperature variation on North American bumblebees are required to predict future ecosystem dynamics.
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Phenotypic Plasticity and Population-level Variation in Thermal Physiology of the Bumblebee 'Bombus impatiens'Rivière, Bénédicte Aurélie 17 April 2012 (has links)
Temperature variation affects most biological parameters from the molecular level to community structure and dynamics. Current studies on thermal biology assess how populations vary in response to environmental temperature, which can help determine how populations differentially respond to climate change. To date, temperature fluctuation effects on endothermic poikilotherms such as the common eastern bumblebee (Bombus impatiens) are unknown even though bumblebees are the most important natural pollinators in North America. A cold-acclimation experiment with B. impatiens colonies revealed individuals acclimated to 5°C or 10°C at night did not differ in resting metabolic rate, flight metabolic rate, wingbeat frequency, or morphological measurements, compared to the control group. Moreover, an infrared camera showed that all colonies maintained maximum nest temperature consistently above 36.8°C. A latitudinal sampling of flight metabolic rate and morphological measurements of B. impatiens from four locations spanning Ontario (N 45°; W 75°) to North Carolina (N 34°; W 77°) indicated no latitudinal trend in the measured variables. This study shows that bumblebees are well equipped to face a wide range of environmental temperatures, both in the short term and long term, and can use a combination of behavioural and physiological mechanisms to regulate body and nest temperatures. These results are reassuring on the direct effects of climate change on bumblebee ecology, but further studies on the indirect effect of temperature variation on North American bumblebees are required to predict future ecosystem dynamics.
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Phenotypic Plasticity and Population-level Variation in Thermal Physiology of the Bumblebee 'Bombus impatiens'Rivière, Bénédicte Aurélie January 2012 (has links)
Temperature variation affects most biological parameters from the molecular level to community structure and dynamics. Current studies on thermal biology assess how populations vary in response to environmental temperature, which can help determine how populations differentially respond to climate change. To date, temperature fluctuation effects on endothermic poikilotherms such as the common eastern bumblebee (Bombus impatiens) are unknown even though bumblebees are the most important natural pollinators in North America. A cold-acclimation experiment with B. impatiens colonies revealed individuals acclimated to 5°C or 10°C at night did not differ in resting metabolic rate, flight metabolic rate, wingbeat frequency, or morphological measurements, compared to the control group. Moreover, an infrared camera showed that all colonies maintained maximum nest temperature consistently above 36.8°C. A latitudinal sampling of flight metabolic rate and morphological measurements of B. impatiens from four locations spanning Ontario (N 45°; W 75°) to North Carolina (N 34°; W 77°) indicated no latitudinal trend in the measured variables. This study shows that bumblebees are well equipped to face a wide range of environmental temperatures, both in the short term and long term, and can use a combination of behavioural and physiological mechanisms to regulate body and nest temperatures. These results are reassuring on the direct effects of climate change on bumblebee ecology, but further studies on the indirect effect of temperature variation on North American bumblebees are required to predict future ecosystem dynamics.
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Do northern and southern populations of the eastern newt (<i>Notophthalmus viridescens</i>) exhibit differences in thermal plasticity?Mineo, Patrick 23 July 2014 (has links)
No description available.
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Effects of Age and Thermal Acclimation on the Selected Temperature and Thermal Resistance of Culcid and Simuliid Larvae (Diptera)Thomas, Anthony 05 1900 (has links)
Black-fly larvae, and mosquito larvae and pupae, are shown to select certain temperature ranges when given a choice in a linear gradient. Larval age has little effect on the temperature selected, but pupae are tolerant of higher temperatures than larvae. The significance of this observation is discussed. The temperature selected is affected by the previous thermal history of the insect, although acclimation to the ambient temperature may be rapid. The final selected temperature of fourth-instar Aedes aegypti larvae was determined. Rearing temperature has a profound effect on the thermal resistance of Aedes aegypti exposed to high temperatures. / Thesis / Master of Science (MS)
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