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Author: Nick Barts Publisher: ISBN: Category : Languages : en Pages :
Book Description
The physiological mechanisms underlying adaptation, and how physiological differences observed in natural populations relate to underlying genetic variation, remain largely unknown for many natural systems. My dissertation seeks to close these gaps in knowledge by addressing three major questions: 1) How does variation across levels of biological organization integrate to explain divergence in organismal phenotypes? 2) Are patterns of physiological adaptation predictable across populations experiencing similar sources of selection? 3) What are the evolutionary origins of physiological traits facilitating adaptation to novel environmental conditions? Organisms inhabiting extreme environments are ideal systems to investigate questions about the mechanisms underlying adaptation and the predictability of evolution at molecular scales. These habitats are characterized by harsh physiochemical stressors that often target specific biochemical and physiological pathways, allowing for hypothesis-driven tests of the effects of the stressor on organismal function and trait evolution. Additionally, powerful comparisons can be made between closely related lineages inhabiting extreme and ancestral habitats, which allows for investigations into the predictability of evolution in response to similar sources of selection. In my research, I leveraged a unique study system of fishes that have independently colonized extreme aquatic habitats rich in hydrogen sulfide (H2S), a naturally occurring toxin that is known to interfere with oxygen transport and mitochondrial function address four objectives: 1) I determined the predictability and repeatability of molecular evolution and changes in gene expression of oxygen transport genes in ten lineages of sulfide-tolerant fishes, 2) I assessed the convergence in biochemical, physiological, and organismal function in pathways exhibiting evidence of molecular evolution and gene expression variation, 3) I measured the functional consequences of genetic variation on the metabolic function of enzymes, mitochondria, and whole organisms to identify the predictability of metabolic evolution across levels of organization and between sulfide-tolerant and -intolerant lineages of fish, and 4) I identified potential adaptive plasticity in gene expression in ancestral freshwater species that may represent pre-adaptations for the colonization of H2S-rich springs. Through the integration of genomic, biochemical, and organismal data, I found that (1) oxygen transport genes are predictable targets of natural selection in sulfide spring fishes, but the modifications in gene expression and sequence variation were not repeatable across groups, (2) both H2S detoxification and oxidative phosphorylation are predictable targets of natural selection in H2S-rich environments, and modification of these integral pathways results in functional differences at the biochemical, physiological, and organismal levels, (3) the degree to which metabolic physiology varies between sulfide-tolerant and -intolerant fish differs depending on the level of organization observed, suggesting that researchers must be cautious when making inferences about function solely from genetic data, and (4) genes exhibiting adaptive plasticity in H2S detoxification, metabolic pathways, and oxygen sensing may have been pre-adaptations that facilitated colonization of sulfide-rich springs. The research detailed in this dissertation has important implications for how scientists perceive the predictability of both evolution and phenotype, highlighting the role environmental and physiological constraints play in our ability to predict the outcomes of natural variation across habitats and within organisms.
Author: Nick Barts Publisher: ISBN: Category : Languages : en Pages :
Book Description
The physiological mechanisms underlying adaptation, and how physiological differences observed in natural populations relate to underlying genetic variation, remain largely unknown for many natural systems. My dissertation seeks to close these gaps in knowledge by addressing three major questions: 1) How does variation across levels of biological organization integrate to explain divergence in organismal phenotypes? 2) Are patterns of physiological adaptation predictable across populations experiencing similar sources of selection? 3) What are the evolutionary origins of physiological traits facilitating adaptation to novel environmental conditions? Organisms inhabiting extreme environments are ideal systems to investigate questions about the mechanisms underlying adaptation and the predictability of evolution at molecular scales. These habitats are characterized by harsh physiochemical stressors that often target specific biochemical and physiological pathways, allowing for hypothesis-driven tests of the effects of the stressor on organismal function and trait evolution. Additionally, powerful comparisons can be made between closely related lineages inhabiting extreme and ancestral habitats, which allows for investigations into the predictability of evolution in response to similar sources of selection. In my research, I leveraged a unique study system of fishes that have independently colonized extreme aquatic habitats rich in hydrogen sulfide (H2S), a naturally occurring toxin that is known to interfere with oxygen transport and mitochondrial function address four objectives: 1) I determined the predictability and repeatability of molecular evolution and changes in gene expression of oxygen transport genes in ten lineages of sulfide-tolerant fishes, 2) I assessed the convergence in biochemical, physiological, and organismal function in pathways exhibiting evidence of molecular evolution and gene expression variation, 3) I measured the functional consequences of genetic variation on the metabolic function of enzymes, mitochondria, and whole organisms to identify the predictability of metabolic evolution across levels of organization and between sulfide-tolerant and -intolerant lineages of fish, and 4) I identified potential adaptive plasticity in gene expression in ancestral freshwater species that may represent pre-adaptations for the colonization of H2S-rich springs. Through the integration of genomic, biochemical, and organismal data, I found that (1) oxygen transport genes are predictable targets of natural selection in sulfide spring fishes, but the modifications in gene expression and sequence variation were not repeatable across groups, (2) both H2S detoxification and oxidative phosphorylation are predictable targets of natural selection in H2S-rich environments, and modification of these integral pathways results in functional differences at the biochemical, physiological, and organismal levels, (3) the degree to which metabolic physiology varies between sulfide-tolerant and -intolerant fish differs depending on the level of organization observed, suggesting that researchers must be cautious when making inferences about function solely from genetic data, and (4) genes exhibiting adaptive plasticity in H2S detoxification, metabolic pathways, and oxygen sensing may have been pre-adaptations that facilitated colonization of sulfide-rich springs. The research detailed in this dissertation has important implications for how scientists perceive the predictability of both evolution and phenotype, highlighting the role environmental and physiological constraints play in our ability to predict the outcomes of natural variation across habitats and within organisms.
Author: European Society for Comparative Physiology and Biochemistry. Conference Publisher: ISBN: 9783805544719 Category : Adaptation (Physiology) Languages : en Pages : 240
Author: Hanns-Christian Gunga Publisher: Elsevier ISBN: 0123869986 Category : Science Languages : en Pages : 336
Book Description
Human Physiology in Extreme Environments is the one publication that offers how human biology and physiology is affected by extreme environments while highlighting technological innovations that allow us to adapt and regulate environments. Covering a broad range of extreme environments, including high altitude, underwater, tropical climates, and desert and arctic climates as well as space travel, this book will include case studies for practical application. Graduate students, medical students and researchers will find Human Physiology in Extreme Environments an interesting, informative and useful resource for human physiology, environmental physiology and medical studies. Presents human physiological challenges in Extreme Environments combined in one single resource Provides an excellent source of information regarding paleontological and anthropological aspects Offers practical medical and scientific use of current concepts
Author: European Society for Comparative Physiology and Biochemistry. Conference Publisher: S. Karger AG (Switzerland) ISBN: Category : Medical Languages : en Pages : 240
Author: RĂ¼diger Riesch Publisher: Springer ISBN: 3319133624 Category : Science Languages : en Pages : 329
Book Description
This book summarizes the key adaptations enabling extremophile fishes to survive under harsh environmental conditions. It reviews the most recent research on acidic, Antarctic, cave, desert, hypersaline, hypoxic, temporary, and fast-flowing habitats, as well as naturally and anthropogenically toxic waters, while pointing out generalities that are evident across different study systems. Knowledge of the different adaptations that allow fish to cope with stressful environmental conditions furthers our understanding of basic physiological, ecological, and evolutionary principles. In several cases, evidence is provided for how the adaptation to extreme environments promotes the emergence of new species. Furthermore, a link is made to conservation biology, and how human activities have exacerbated existing extreme environments and created new ones. The book concludes with a discussion of major open questions in our understanding of the ecology and evolution of life in extreme environments.
Author: Frances Ashcroft Publisher: Univ of California Press ISBN: 9780520234208 Category : Science Languages : en Pages : 354
Book Description
Explores the limits of human survival and the physiological adaptations that enable us to exist under extreme conditions. The author reviews limits to human life underwater, at high altitudes, at high speeds, at micro levels, and at freezing and hot temperatures.
Author: Emma F. Camp Publisher: Frontiers Media SA ISBN: 2889457176 Category : Languages : en Pages : 198
Book Description
Examination of corals and reef-associated organisms which endure in extreme coral reef environments is challenging our understanding of the conditions that organisms can survive under. By studying individuals naturally adapted to unfavorable conditions, we begin to better understand the important traits required to survive rapid environmental and climate change. This Research Topic, comprising reviews, and original research articles, demonstrates the current state of knowledge regarding the diversity of extreme coral habitats, the species that have been studied, and the knowledge to-date on the mechanisms, traits and trade-offs that have facilitated survival.
Author: David A. Baum Publisher: Princeton University Press ISBN: 069117587X Category : Science Languages : en Pages : 886
Book Description
The essential one-volume reference to evolution The Princeton Guide to Evolution is a comprehensive, concise, and authoritative reference to the major subjects and key concepts in evolutionary biology, from genes to mass extinctions. Edited by a distinguished team of evolutionary biologists, with contributions from leading researchers, the guide contains some 100 clear, accurate, and up-to-date articles on the most important topics in seven major areas: phylogenetics and the history of life; selection and adaptation; evolutionary processes; genes, genomes, and phenotypes; speciation and macroevolution; evolution of behavior, society, and humans; and evolution and modern society. Complete with more than 100 illustrations (including eight pages in color), glossaries of key terms, suggestions for further reading on each topic, and an index, this is an essential volume for undergraduate and graduate students, scientists in related fields, and anyone else with a serious interest in evolution. Explains key topics in some 100 concise and authoritative articles written by a team of leading evolutionary biologists Contains more than 100 illustrations, including eight pages in color Each article includes an outline, glossary, bibliography, and cross-references Covers phylogenetics and the history of life; selection and adaptation; evolutionary processes; genes, genomes, and phenotypes; speciation and macroevolution; evolution of behavior, society, and humans; and evolution and modern society
Author: Nick Barts
Author: Nick Barts
Author: European Society for Comparative Physiology and Biochemistry. Conference
Author: Hanns-Christian Gunga
Author: European Society for Comparative Physiology and Biochemistry. Conference
Author: RĂ¼diger Riesch
Author: Frances Ashcroft
Author: Guido di Prisco
Author: Emma F. Camp
Author: David A. Baum
Author: Charles Darwin