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Author: Phillip Ross Pearson Publisher: ISBN: Category : Languages : en Pages : 0
Book Description
Sex in vertebrates is typically understood to follow two primary modes of sex determination: genotypic sex determination and environmental sex determination. In genotypic sex determination (GSD), the genes that trigger sex differentiation are located on sex-specific chromosomes and are typically either male heterogametic (XX female and XY male) or female heterogametic (ZZ male and ZW female). Organisms with environmental sex determination (ESD) have no sex chromosomes, and the presence of an environmental cue (e.g., temperature) triggers sexual differentiation. Despite this conceptual dichotomy in sex determination, several lineages of vertebrates with GSD have shown a temperature override of sexual differentiation pathways producing sex-reversed individuals. These sex-reversed individuals have a mismatched sexual genotype and phenotype (e.g., ZZ female). Within reptiles, several species have exhibited sex reversal under laboratory and natural conditions, and it has been proposed that the propensity for sex reversal may partly explain the multiple evolutionary transitions between GSD and ESD (in the form of temperature-dependent sex determination (TSD)) seen in this taxon. Identifying how or if sex reversal influences fitness related traits of a species is critical to understanding how modes of sex determination evolve or persist in a population. Here, I use a combination of laboratory and field-based studies to understand the consequences of sex reversal in the Central Bearded Dragon lizard (Pogona vitticeps) by 1) quantifying reproductive output and the propensity to sex reverse between captive concordant and sex-reversed females; 2) quantifying morphology, growth, survival, and locomotor performance of the offspring of both concordant and sex-reversed females; 3) quantifying the nesting behaviours of free-ranging P. vitticeps, and 4) using predictive models to understand the relative risk of sex reversal. Using a captive colony of P. vitticeps, I measured the reproductive rate of concordant (ZW) and sex-reversed (ZZ) females across two reproductive seasons and analysed historical data. I found that sex-reversed females produce fewer eggs per reproductive season than concordant females. This is contrary to previous published findings. I show that one hyper-fecund, sex-reversed female drove the results from the previous study. Additionally, I note that the pivotal temperature for offspring of concordant mothers is lower than previously suggested and not significantly different than sex-reversed mothers. I also found that sex-reversed females produce larger eggs suggesting that there may be a trade-off between reproductive rate and egg size. These results suggest that sex reversal does not provide a reproductive advantage. Then, I used the offspring produced from the previous study to quantify fitness-related phenotypes. I found that offspring of sex-reversed mothers are larger with better body condition at hatching than those of concordant mothers, but this difference dissipates quickly after hatching. Maternal sex genotype did not influence growth, survival, performance, or critical thermal limits. However, developmental temperatures did influence locomotor performance as well as the critical thermal minimums of offspring. The larger size at hatching afforded to offspring of sex-reversed mothers may provide an advantage allowing survival to adulthood increasing the persistence of sex reversal in a population. I next used free-ranging, concordant female P. vitticeps to quantify nesting behaviours and nest site microclimate variables. I provide the first documentation of the nesting ecology in this species. Although sample sizes were relatively low, I found that nesting concordant females chose open canopy locations but varied the depth of their nests across the reproductive season, which alters the temperatures experienced by the developing embryos. I show that late season nests have a higher risk of sex reversal than early nests. So far, sex reversal has only been documented in approximately 24 percent of the range of P. vitticeps, while ambient temperatures suggest that sex reversal should extend well beyond. To address my final aim, I deployed temperature loggers and collected microhabitat data from open and shaded potential nest sites at eight locations to determine the relative risk of sex reversal across the species' range. I used these data to test the accuracy of and then inform the microclimate model NicheMapR (Shiny app interface) to predict the risk of sex reversal at these point locations. I found that areas where no sex reversal has been recorded may have refugia that allow females to mitigate the risk of sex reversal. Furthermore, I show that open canopy areas where sex reversal has been documented may be at the greatest risk if females continue to choose open canopy nest sites. Overall, my research suggests a change in the perception of sex reversal in P. vitticeps in the context of evolutionary transitions. Sex reversal does not convey a reproductive advantage, nor does it provide much of an advantage past hatching. Although free-ranging females choose nest sites that may induce sex reversal late in the reproductive season, they may be able to mitigate the risk of sex reversal by altering their behaviours or shifting their reproductive phenology. In full, the phenotypes associated with sex reversal in P. vitticeps alone are unlikely to provide the momentum to advance this species towards a transition in mode of sex determination.
Author: Phillip Ross Pearson Publisher: ISBN: Category : Languages : en Pages : 0
Book Description
Sex in vertebrates is typically understood to follow two primary modes of sex determination: genotypic sex determination and environmental sex determination. In genotypic sex determination (GSD), the genes that trigger sex differentiation are located on sex-specific chromosomes and are typically either male heterogametic (XX female and XY male) or female heterogametic (ZZ male and ZW female). Organisms with environmental sex determination (ESD) have no sex chromosomes, and the presence of an environmental cue (e.g., temperature) triggers sexual differentiation. Despite this conceptual dichotomy in sex determination, several lineages of vertebrates with GSD have shown a temperature override of sexual differentiation pathways producing sex-reversed individuals. These sex-reversed individuals have a mismatched sexual genotype and phenotype (e.g., ZZ female). Within reptiles, several species have exhibited sex reversal under laboratory and natural conditions, and it has been proposed that the propensity for sex reversal may partly explain the multiple evolutionary transitions between GSD and ESD (in the form of temperature-dependent sex determination (TSD)) seen in this taxon. Identifying how or if sex reversal influences fitness related traits of a species is critical to understanding how modes of sex determination evolve or persist in a population. Here, I use a combination of laboratory and field-based studies to understand the consequences of sex reversal in the Central Bearded Dragon lizard (Pogona vitticeps) by 1) quantifying reproductive output and the propensity to sex reverse between captive concordant and sex-reversed females; 2) quantifying morphology, growth, survival, and locomotor performance of the offspring of both concordant and sex-reversed females; 3) quantifying the nesting behaviours of free-ranging P. vitticeps, and 4) using predictive models to understand the relative risk of sex reversal. Using a captive colony of P. vitticeps, I measured the reproductive rate of concordant (ZW) and sex-reversed (ZZ) females across two reproductive seasons and analysed historical data. I found that sex-reversed females produce fewer eggs per reproductive season than concordant females. This is contrary to previous published findings. I show that one hyper-fecund, sex-reversed female drove the results from the previous study. Additionally, I note that the pivotal temperature for offspring of concordant mothers is lower than previously suggested and not significantly different than sex-reversed mothers. I also found that sex-reversed females produce larger eggs suggesting that there may be a trade-off between reproductive rate and egg size. These results suggest that sex reversal does not provide a reproductive advantage. Then, I used the offspring produced from the previous study to quantify fitness-related phenotypes. I found that offspring of sex-reversed mothers are larger with better body condition at hatching than those of concordant mothers, but this difference dissipates quickly after hatching. Maternal sex genotype did not influence growth, survival, performance, or critical thermal limits. However, developmental temperatures did influence locomotor performance as well as the critical thermal minimums of offspring. The larger size at hatching afforded to offspring of sex-reversed mothers may provide an advantage allowing survival to adulthood increasing the persistence of sex reversal in a population. I next used free-ranging, concordant female P. vitticeps to quantify nesting behaviours and nest site microclimate variables. I provide the first documentation of the nesting ecology in this species. Although sample sizes were relatively low, I found that nesting concordant females chose open canopy locations but varied the depth of their nests across the reproductive season, which alters the temperatures experienced by the developing embryos. I show that late season nests have a higher risk of sex reversal than early nests. So far, sex reversal has only been documented in approximately 24 percent of the range of P. vitticeps, while ambient temperatures suggest that sex reversal should extend well beyond. To address my final aim, I deployed temperature loggers and collected microhabitat data from open and shaded potential nest sites at eight locations to determine the relative risk of sex reversal across the species' range. I used these data to test the accuracy of and then inform the microclimate model NicheMapR (Shiny app interface) to predict the risk of sex reversal at these point locations. I found that areas where no sex reversal has been recorded may have refugia that allow females to mitigate the risk of sex reversal. Furthermore, I show that open canopy areas where sex reversal has been documented may be at the greatest risk if females continue to choose open canopy nest sites. Overall, my research suggests a change in the perception of sex reversal in P. vitticeps in the context of evolutionary transitions. Sex reversal does not convey a reproductive advantage, nor does it provide much of an advantage past hatching. Although free-ranging females choose nest sites that may induce sex reversal late in the reproductive season, they may be able to mitigate the risk of sex reversal by altering their behaviours or shifting their reproductive phenology. In full, the phenotypes associated with sex reversal in P. vitticeps alone are unlikely to provide the momentum to advance this species towards a transition in mode of sex determination.
Author: Timothy A. Mousseau Publisher: Oxford University Press ISBN: 0195344405 Category : Science Languages : en Pages : 390
Book Description
Mothers have the ability to profoundly affect the quality of their offspring--from the size and quality of their eggs to where, when, and how eggs and young are placed, and from providing for and protecting developing young to choosing a mate. In many instances, these maternal effects may be the single most important contributor to variation in offspring fitness. This book explores the wide variety of maternal effects that have evolved in plants and animals as mechanisms of adaptation to temporally and spatially heterogeneous environments. Topics range from the evolutionary implications of maternal effects to the assessment and measurement of maternal effects. Four detailed case studies are also included. This book represents the first synthesis of the current state of knowledge concerning the evolution of maternal effects and their adaptive significance.
Author: Anne Charmantier Publisher: Oxford University Press ISBN: 019967423X Category : Medical Languages : en Pages : 293
Book Description
This book gathers the expertise of 30 evolutionary biologists from around the globe to highlight how applying the field of quantitative genetics - the analysis of the genetic basis of complex traits - aids in the study of wild populations.
Author: Ettore Olmo Publisher: S. Karger AG (Switzerland) ISBN: Category : Medical Languages : en Pages : 152
Book Description
Reptiles are a fascinating group for the study of sexual development because they exhibit a wide range of sex-determining mechanisms, from strict genetic sex determination (GSD) to strict thermal sex determination (TSD) and intermediate systems of GSD that are to various degrees overridden by environmental effects . This thematic issue presents the latest data on different aspects of sex determination in reptiles. Following an evolutionary perspective on why reptiles might be predisposed to evolve TSD, the papers in this issue explore in detail the different genetic and molecular mechanisms of sex determination and differentiation. They consider recent findings such as the discovery of new genes differentially expressed at male and female sex-determining temperatures, a new model of the role of aromatase, and the contribution of heat-shock proteins to TSD in the American alligator. Further studies examine the role played by sex allocation, the advantage of viviparity, and the effects of anthropogenic climate change on the sex ratio in TSD reptile populations. Providing a valuable overview for both students and researchers, this publication is essential reading for developmental and reproductive biologists, herpetologists, comparative endocrinologists, evolutionary biologists and geneticists.
Author: David O. Norris Publisher: Elsevier ISBN: 0443160236 Category : Science Languages : en Pages : 398
Book Description
Hormones and Reproduction of Vertebrates, Volume 3: Reptiles is the third of five second-edition volumes representing a comprehensive and integrated overview of hormones and reproduction in fishes, amphibians, reptiles, birds, and mammals. The book includes coverage of endocrinology, neuroendocrinology, physiology, behavior, and anatomy of reptilian reproduction. It provides a broad treatment of the roles of pituitary, thyroid, adrenal, and gonadal hormones in all aspects of reproduction, as well as descriptions of major life history events. New to this edition is a concluding assessment of the effect of environmental influences on reptiles. Initial chapters in this book broadly examine sex determination, reproductive neuroendocrinology, stress, and hormonal regulation as it relates to testicular and ovarian function. Subsequent chapters examine hormones and reproduction of specific taxa, including turtles, crocodilians, lizards, and snakes. The book concludes with an examination of endocrine disruption of reproduction in reptiles. Hormones and Reproduction of Vertebrates, Volume 3: Reptiles is designed to provide a readable, coordinated description of reproductive basics in reptiles, as well as an introduction to the latest trends in reproductive research and a presentation of our understanding of reproductive events gained over the past decade. It may serve as a stand-alone reference for researchers and practitioners in the field of herpetology or as one of five coordinated references aligned to provide topical treatment across vertebrate taxa for researchers, practitioners, and students focused on vertebrate endocrinology. Covers endocrinology, neuroendocrinology, physiology, behavior, and anatomy of reptile reproduction Includes pituitary, thyroid, adrenal, and gonadal hormones Focuses on turtles, crocodilians, lizards, and snakes Provides new coverage on environmental influences on reptiles
Author: Nicole Valenzuela Publisher: Smithsonian Institution Scholarly Press ISBN: Category : Science Languages : en Pages : 212
Book Description
Edited by the world's foremost authorities on the subject, with essays by leading scholars in the field, this work shows how the sex of reptiles and many fish is determined not by the chromosomes they inherit but by the temperature at which incubation takes place.
Author: Russell Bonduriansky Publisher: Princeton University Press ISBN: 0691204144 Category : Science Languages : en Pages : 304
Book Description
Bonduriansky and Day challenge the premise that genes alone mediate the transmission of biological information across generations and provide the raw material for natural selection. They explore the latest research showing that what happens during our lifetimes—and even our parents’ and grandparents’ lifetimes—can influence the features of our descendants. Based on this evidence, Bonduriansky and Day develop an extended concept of heredity that upends ideas about how traits can and cannot be transmitted across generations, opening the door to a new understanding of inheritance, evolution, and even human health. --Adapted from publisher description.
Author: Phillip Ross Pearson
Author: Phillip Ross Pearson
Author: J. Sean Doody
Author: Timothy A. Mousseau
Author: Anne Charmantier
Author: Ettore Olmo
Author: David O. Norris
Author: Nicole Valenzuela
Author: 
Author: Russell Bonduriansky
Author: