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The reproductive physiology of the burrowing Cuban cockroach Byrsotria fumigata (Guerin) and the role of the brood sac in oviposition and embryo developmentBlane, Edward James January 1990 (has links)
No description available.
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A Holobiont Characterization of Reproduction in a Live-bearing Cockroach, Diploptera punctataJennings, Emily C. 02 August 2019 (has links)
No description available.
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Life history evolution of the lizard Sceloporus scalaris : comparisons of lowland and montane populations /Mathies, Thomas C., January 1994 (has links)
Thesis (M.S.)--Virginia Polytechnic Institute and State University, 1994. / Vita. Abstract. Includes bibliographical references (leaves 71-78). Also available via the Internet.
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Placental Transfer of Nutrients During Gestation in the Viviparous Lizard, Pseudemoia spenceriThompson, M. B., Stewart, J. R., Speake, B. K., Russell, K. J., McCartney, R. J. 01 July 1999 (has links)
Energy, ionic, protein and lipid contents and fatty acid profiles for the major lipid classes of freshly ovulated eggs and neonates of the viviparous lizard, Pseudemoia spenceri, were measured. Litter size is 1.7 ± 0.1, with larger females producing larger neonates. Placentotrophy results in approximately 23% more dry matter in the neonates than in the fresh egg. The increase in the quantity of protein and lipid during development is not significant and is reflected in the similarity of energy densities of eggs and neonates. As a percentage of dry matter, neonates have slightly lower proportions of lipid and protein than eggs because of significant uptake of ash, calcium, potassium and sodium, but not of magnesium, across the placenta. The amounts of triacylglycerol and phospholipid are not significantly different between the egg and the neonate, but neonates contain significantly more cholesterol and cholesteryl ester. The amounts of the major fatty acids, palmitic and oleic acids, recovered from the total lipids of the neonate do not differ significantly from the amounts present in the egg lipids, but the neonates contain significantly less linoleic and α-linolenic acids and more palmitoleic, stearic and arachidonic acids than the eggs. The amount of docosahexaenoic acid recovered from the lipids of the neonate is 2.6-times greater than the amount initially present in the egg. P. spenceri has a relatively larger egg and a smaller reliance on placentotrophy than other species in the same genus, all of which have a similar placental morphology. Nevertheless, the pattern of embryonic nutrition includes both obligative and facultative placentotrophy. All the major components of yolk of oviparous species are present in eggs of P. spenceri, but most are augmented during development by placental transfer.
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Developmental Morphology and Evolution of Extraembryonic Membranes of Lizards and Snakes (Reptilia, Squamata)Stewart, James R. 01 July 2021 (has links)
Amniote embryos are supported and nourished by a suite of tissues, the extraembryonic membranes, that provide vascular connections to the egg contents. Oviparous reptiles share a basic pattern of development inherited from a common ancestor; a vascular chorioallantoic membrane, functioning as a respiratory organ, contacts the eggshell and a vascular yolk sac membrane conveys nutrients to the embryo. Squamates (lizards, snakes) have evolved a novel variation in morphogenesis of the yolk sac that results in a unique structure, the yolk cleft/isolated yolk mass complex. This structure is a source of phylogenetic variation in architecture of the extraembryonic membranes among oviparous squamates. The yolk cleft/isolated yolk mass complex is retained in viviparous species and influences placental architecture. The aim of this paper is to review extraembryonic membrane development and morphology in oviparous and related viviparous squamates to explore patterns of variation. The survey includes all oviparous species for which data are available (11 species; 4 families). Comparisons with viviparous species encompass six independent origins of viviparity. The comparisons reveal that both phylogeny and reproductive mode influence variation in extraembryonic membrane development and that phylogenetic variation influences placental evolution. Models of the evolution of squamate placentation have relied primarily on comparisons between independently derived viviparous species. The inclusion of oviparous species in comparative analyses largely supports these models, yet exposes convergent patterns of evolution that become apparent when phylogenetic variation is recognized.
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Novel Placental Structure in the Mexican Gerrhonotine Lizard, Mesaspis viridiflava (Lacertilia; Anguidae)Stewart, James R., Mendez de la Cruz, Fausto R. 01 January 2019 (has links)
The evolution of viviparity alters the physical relationship between mothers and offspring and the prevalence of viviparity among squamate reptiles presents an opportunity to uncover patterns in the evolution of placental structure. Understanding the breadth of this diversity is limited because studies of placental structure and function have emphasized a limited number of lineages. We studied placental ontogeny using light microscopy for an embryological series of the Mexican gerrhonotine lizard, Mesaspis viridiflava. This species develops an elaborate yolk sac placenta, an omphaloplacenta, which receives vascular support arising in a structure known only from other gerrhonotine lizards. A prominent feature of the omphaloplacenta is a zone of uterine and embryonic epithelial cell hyperplasia located at the upper shoulder of the yolk mass, often extending above the yolk mass. The omphaloplacenta covers more than one-half of the surface area of maternal—embryonic contact. The chorioallantoic placenta has a more restricted distribution because the allantois remains in the embryonic hemisphere of the egg throughout development and lies internal to the vascular support for the omphaloplacenta in areas where they overlap. The structural profile of the chorioallantoic placenta indicates a potential for respiratory exchange and/or hemotrophic nutritive transport, while that of the omphaloplacenta suggests that nutritive transfer is primarily via histotrophy. An eggshell is present in the earliest embryonic stages examined but regresses relatively early in development. Placental specializations of this species are consistent with a pattern of matrotrophic embryonic nutrition and have evolved in a unique lineage specific developmental pattern.
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Developmental Morphology and Evolution of Extraembryonic Membranes of Lizards and Snakes (Reptilia, Squamata)Stewart, James R. 01 January 2020 (has links)
Amniote embryos are supported and nourished by a suite of tissues, the extraembryonic membranes, that provide vascular connections to the egg contents. Oviparous reptiles share a basic pattern of development inherited from a common ancestor; a vascular chorioallantoic membrane, functioning as a respiratory organ, contacts the eggshell and a vascular yolk sac membrane conveys nutrients to the embryo. Squamates (lizards, snakes) have evolved a novel variation in morphogenesis of the yolk sac that results in a unique structure, the yolk cleft/isolated yolk mass complex. This structure is a source of phylogenetic variation in architecture of the extraembryonic membranes among oviparous squamates. The yolk cleft/isolated yolk mass complex is retained in viviparous species and influences placental architecture. The aim of this paper is to review extraembryonic membrane development and morphology in oviparous and related viviparous squamates to explore patterns of variation. The survey includes all oviparous species for which data are available (11 species; 4 families). Comparisons with viviparous species encompass six independent origins of viviparity. The comparisons reveal that both phylogeny and reproductive mode influence variation in extraembryonic membrane development and that phylogenetic variation influences placental evolution. Models of the evolution of squamate placentation have relied primarily on comparisons between independently derived viviparous species. The inclusion of oviparous species in comparative analyses largely supports these models, yet exposes convergent patterns of evolution that become apparent when phylogenetic variation is recognized.
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Impact of Reproductive Mode on Skeletal Development in a Reproductively Bimodal Squamate SpeciesTedder, Amanda 01 August 2018 (has links) (PDF)
Viviparity has evolved multiple times within squamates. Eggshells are reduced in viviparous forms, which reduces calcium available to embryos during development. This study tested the hypothesis that reduced calcium impacts neonates of viviparous forms. Developmental series from oviparous and viviparous populations of Zootoca vivipara (reproductively bimodal) were cleared & stained to reveal bone development. Photographs (high magnification, calibrated to size) were used to obtain measurements of lengths of the body, humerus, femur, skull and lower jaw, and of ossified portions of limb bones. Percent ossification was scored for targeted skull bones. Results were analyzed using general linear models and revealed no differences in ossification in either limbs or skull. Overall size of oviparous neonates was significantly larger. Findings do not support our hypothesis and indicate that reduction in eggshell calcium in embryos of viviparous populations does not negatively impact limb or skull ossification during development but may influence overall size.
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Constraints on the Evolution of Viviparity in the Lizard Genus SceloporusMathies, Tom 15 October 1999 (has links)
I evaluated possible constraints on the evolution of viviparity in the lizard genus Sceloporus by experimentally extending the length of egg retention past the normal time of oviposition for a number of oviparous species. Observations also included a representative of the genus Urosaurus, the sister genus to Sceloporus. I determined the effects of retention on embryonic development, hatchlings, and gravid females. Results indicated that the proximate constraints on longer retention times and viviparity are 1) embryonic development becomes arrested or severely retarded in utero, and 2) the ability to maintain gravidity past the normal time of oviposition is limited in some species. Observations on Urosaurus further showed that extended egg retention results in hatchlings with traits that are associated with lower fitness.
I also tested the hypothesis that reproductive Sceloporus lower their body temperatures during activity because their normal body temperatures are detrimental to embryos. Observations on a viviparous species of Sceloporus indicated that the normal body temperature of the female was detrimental to embryonic development. This result is indicates that viviparity would be constrained in some squamate lineages if maternal body temperatures are too high for successful embryonic development.
I also evaluated the hypothesis that the evolutionary transition from oviparity to viviparity involves a "reduction" of the eggshell concurrent with longer durations of egg retention. If this hypothesis is correct, then attributes of eggshells that should enhance exchange of respiratory gases (i.e., thickness, density, permeability to water vapor) would be correlated with the maximal developmental stage that embryos are able to attain in the oviducts (i.e., stage of developmental arrest). The results of this study indicated that these features of shells do not determine the stage at which development becomes arrested. Thus, the results do not support the hypothesis that shell reduction occurs concurrently with longer periods of egg retention. The results are consistent with the alternative hypothesis that reduction of the eggshell occurs after viviparity has evolved. / Ph. D.
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The molecular basis of a maternal-fetal oxygen shift in the viviparous seaperch, Embiotoca lateralisIngermann, Rolf L. 06 1900 (has links)
xii, 154 leaves : ill. ; 28 cm
Typescript. (Another copy on microfilm is located in Archives)
Thesis (Ph.D) -- University of Oregon
Includes vita and abstract
Bibliography: leaves 134-154
University of Oregon theses, Dept. of Biology, Ph.D., 1980
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