Your search keyword '"Reptiles embryology"' showing total 173 results

1. Resilience of the replacing dentition in adult reptiles.

Author

Henriquez JI and Richman JM

Subjects

Animals, Biological Evolution, Humans, Stem Cells physiology, Reptiles embryology, Reptiles physiology, Dentition, Tooth embryology, Odontogenesis physiology

Abstract

The dentition is critical to animal survival and teeth are present in modern vertebrates including teleost fish, sharks, amphibians, mammals and reptiles. The developmental processes that give rise to teeth are not just preserved through evolution but also share high level of similarity with the embryogenesis of other ectodermal organs. In this review we go beyond the embryonic phase of tooth development to life-long tooth replacement. We will address the origins of successional teeth, the location of putative tissue-resident stem cells, how de novo tooth formation continues throughout life and how teeth are shed in a spatially and temporally controlled manner. We review the evidence that the dental epithelium, which is the earliest recognizable dental structure in the reptilian dentition, serves as a putative niche for tissue-resident epithelial stem cells and recent molecular findings from transcriptomics carried out in reptilian dentitions. We discuss how odontoclasts resorb the primary tooth allowing eruption of the successional tooth. The reptiles, particularly lizards, are emerging as some of the most accessible animals to study tooth replacement which has relevance to evolution of the dentition and human dental disorders., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

2. Ontogenetic variation in the skull of Stenopterygius quadriscissus with an emphasis on prenatal development.

Author

Miedema F and Maxwell EE

Subjects

Animals, Animals, Newborn, Aquatic Organisms growth & development, Female, Phylogeny, Pregnancy, Reptiles growth & development, Skull growth & development, Embryonic Development physiology, Fossils, Osteogenesis physiology, Reptiles anatomy & histology, Reptiles embryology, Skull anatomy & histology, Skull embryology

Abstract

The availability of a large sample size from a range of ontogenetic stages makes Stenopterygius quadriscissus a good model to study ontogenetic variation in a fossil sauropsid. We qualitatively examined pre- and postnatal ontogenetic changes in the cranium of S. quadriscissus. The prenatal ossification sequence is similar to other diapsids, exhibiting delayed chondrocranial ossification compared to the dermatocranium. In the dermatocranium, the circumorbital area is more ossified earlier in development relative to other elements, especially those of the skull roof where ossification is comparatively weaker across prenatal stages. Perinatally all cranial elements are ossified, and many scarf and step joints are already closed. We propose four prenatal and three postnatal stages in S. quadriscissus on the basis of relative ossification, size and qualitative cranial characters pertaining to the jugal, parietal, frontal, pterygoid and surangular. These will provide a basis for determining ontogenetic stages in other ichthyosaurs. Moreover, our postnatal observations aid in refining ontogenetic characters for phylogenetic studies. Lastly, we observed that the antimeric sutures of the midline of the skull roof are open perinatally and that fusion of the midline only appears in the adult stage. We hypothesize that the loose connection of the midline functions as a fontanelle, limiting potential damage during birth., (© 2022. The Author(s).)

Published

2022

3. Elevation, oxygen, and the origins of viviparity.

Author

Watson CM and Cox CL

Subjects

Animals, Biological Evolution, Female, Reptiles embryology, Altitude, Oxygen, Reptiles physiology, Viviparity, Nonmammalian physiology

Abstract

Research focused on understanding the evolutionary factors that shape parity mode evolution among vertebrates have long focused on squamate reptiles (snakes and lizards), which contain all but one of the evolutionary transitions from oviparity to viviparity among extant amniotes. While most hypotheses have focused on the role of cool temperatures in favoring viviparity in thermoregulating snakes and lizards, there is a growing appreciation in the biogeographic literature for the importance of lower oxygen concentrations at high elevations for the evolution of parity mode. However, the physiological mechanisms underlying how hypoxia might reduce fitness, and how viviparity can alleviate this fitness decrement, has not been systematically evaluated. We qualitatively evaluated previous research on reproductive and developmental physiology, and found that (1) hypoxia can negatively affect fitness of squamate embryos, (2) oxygen availability in the circulatory system of adult lizards can be similar or greater than an egg, and (3) gravid females can possess adaptive phenotypic plasticity in response to hypoxia. These findings suggest that the impact of hypoxia on the development and physiology of oviparous and viviparous squamates would be a fruitful area of research for understanding the evolution of viviparity. To that end, we propose an integrative research program for studying hypoxia and the evolution of viviparity in squamates., (© 2021 Wiley Periodicals LLC.)

Published

2021

4. Immunochemical Detection of Modified Cytosine Species in Lampbrush Chromatin.

Author

Morgan GT

Subjects

Animals, Cell Nucleus immunology, Chromatin genetics, Chromosomes immunology, Cytosine chemistry, Cytosine immunology, Female, Oocytes metabolism, Reptiles embryology, Reptiles immunology, Xenopus laevis genetics, Chromatin immunology, Immunohistochemistry methods, Oocytes immunology

Abstract

The lampbrush chromosomes found in the giant nucleus or germinal vesicle (GV) of amphibian oocytes provide unique opportunities for discrete closed and open chromatin structural domains to be directly observable by simple light microscopy. Moreover, the method described here for preparing spreads of lampbrush chromatin for immunostaining enables a straightforward approach to establishing the distributions of modified nucleotides within and between structurally and functionally distinctive chromatin domains.

Published

2021

5. The thermal ecology and physiology of reptiles and amphibians: A user's guide.

Author

Taylor EN, Diele-Viegas LM, Gangloff EJ, Hall JM, Halpern B, Massey MD, Rödder D, Rollinson N, Spears S, Sun BJ, and Telemeco RS

Subjects

Amphibians embryology, Amphibians growth & development, Animals, Embryo, Nonmammalian physiology, Monitoring, Physiologic, Reptiles embryology, Reptiles growth & development, Amphibians physiology, Body Temperature physiology, Ecosystem, Reptiles physiology

Abstract

Research on the thermal ecology and physiology of free-living organisms is accelerating as scientists and managers recognize the urgency of the global biodiversity crisis brought on by climate change. As ectotherms, temperature fundamentally affects most aspects of the lives of amphibians and reptiles, making them excellent models for studying how animals are impacted by changing temperatures. As research on this group of organisms accelerates, it is essential to maintain consistent and optimal methodology so that results can be compared across groups and over time. This review addresses the utility of reptiles and amphibians as model organisms for thermal studies by reviewing the best practices for research on their thermal ecology and physiology, and by highlighting key studies that have advanced the field with new and improved methods. We end by presenting several areas where reptiles and amphibians show great promise for further advancing our understanding of how temperature relations between organisms and their environments are impacted by global climate change., (© 2020 Wiley Periodicals LLC.)

Published

2021

6. Heat tolerance of reptile embryos: Current knowledge, methodological considerations, and future directions.

Author

Hall JM and Sun BJ

Subjects

Animals, Climate Change, Embryo, Nonmammalian physiology, Hot Temperature, Reptiles embryology, Thermotolerance

Abstract

Aspects of global change result in warming temperatures that threaten biodiversity across the planet. Eggs of non-avian, oviparous reptiles (henceforth "reptiles") are particularly vulnerable to warming due to a lack of parental care during incubation and limited ability to behaviorally thermoregulate. Because warming temperatures will cause increases in both mean and variance of nest temperatures, it is crucial to consider embryo responses to both chronic and acute heat stress. Although many studies have considered embryo survival across constant incubation temperatures (i.e., chronic stress) and in response to brief exposure to extreme temperatures (i.e., acute stress), there are no standard metrics or terminology for determining heat stress of embryos. This impedes comparisons across studies and species and hinders our ability to predict how species will respond to global change. In this review, we compare various methods that have been used to assess embryonic heat tolerance in reptiles and provide new terminology and metrics for quantifying embryo responses to both chronic and acute heat stress. We apply these recommendations to data from the literature to assess chronic heat tolerance in 16 squamates, 16 turtles, five crocodilians, and the tuatara and acute heat tolerance for nine squamates and one turtle. Our results indicate that there is relatively large variation in chronic and acute heat tolerance across species, and we outline directions for future research, calling for more studies that assess embryo responses to acute thermal stress, integrate embryo responses to chronic and acute temperatures in predictive models, and identify mechanisms that determine heat tolerance., (© 2020 Wiley Periodicals LLC.)

Published

2021

7. An overlooked placode: Recharacterizing the papillae in the embryonic eye of reptilia.

Author

Drake PM, Jourdeuil K, and Franz-Odendaal TA

Subjects

Animals, Chick Embryo, Sclera embryology, Skeleton embryology, Eye embryology, Reptiles embryology

Abstract

The papillae in the chicken embryonic eye, described as scleral papillae in the well-known Hamburger and Hamilton (1951) staging table, are one of the key anatomical features used to stage reptilian (including bird) embryos from HH30-36. These papillae are epithelial thickenings of the conjunctiva and are situated above the mesenchymal sclera. Here, we present evidence that the conjunctival papillae, which are required for the induction and patterning of the underlying scleral ossicles, require epithelial pre-patterning and have a placodal stage similar to other placode systems. We also suggest modifications to the Hamburger Hamilton staging criteria that incorporate this change in terminology (from "scleral" to "conjunctival" papillae) and provide a more detailed description of this anatomical feature that includes its placode stage. This enables a more complete and accurate description of chick embryo staging. The acknowledgment of a placode phase, which shares molecular and morphological features with other cutaneous placodes, will direct future research into the early inductive events leading to scleral ossicle formation., (© 2019 Wiley Periodicals, Inc.)

Published

2020

8. Skeletons of the Eye: An Evolutionary and Developmental Perspective.

Author

Franz-Odendaal TA

Subjects

Animals, Bone and Bones anatomy & histology, Eye anatomy & histology, Reptiles anatomy & histology, Sclera anatomy & histology, Biological Evolution, Bone and Bones embryology, Eye embryology, Reptiles embryology, Sclera embryology

Abstract

The ocular skeleton, composed of the scleral cartilage and scleral ossicles, is present in many vertebrates. The morphology of the scleral cartilage and ossicles varies within different extant reptiles (including birds) and also varies dramatically from the morphology in extant teleosts. This incredible range of diverse morphologies is the result of millions of years of evolution. Both the position of these elements within the eye and the timing of development vary amongst different vertebrates. While the development of both the scleral cartilage and scleral ossicles is somewhat understood in reptiles and in teleosts, the functional advantage of these elements is still debated. Most reptiles have a multi-component scleral ossicle ring composed of a series of flat bone plates and a scleral cartilage cup lining the retina, some sharks have calcified cartilage plates, and some teleosts have two bones while most others only have a ring of scleral cartilage. The data presented shows that different vertebrates have adapted to similar selective pressures in different ways. However, the reason why sarcopterygians have a series of overlapping bones in the sclera remains unclear. A better understanding of the ocular skeletal diversity in Reptilia as well as a better understanding of the mechanisms of vision within different environments (i.e., air vs. water) and that used by secondarily aquatic organisms is needed. This review discusses the observed variation in morphology and development of the ocular skeleton in the context of evolution and highlights our knowledge gaps in these areas. Anat Rec, 2018. © 2018 American Association for Anatomy., (© 2018 American Association for Anatomy.)

Published

2020

9. Adaptive responses of the embryos of birds and reptiles to spatial and temporal variations in nest temperatures.

Author

Du WG, Shine R, Ma L, and Sun BJ

Subjects

Animals, Birds embryology, Embryo, Nonmammalian physiology, Reptiles embryology, Spatio-Temporal Analysis, Adaptation, Biological, Birds growth & development, Embryonic Development physiology, Nesting Behavior, Reptiles growth & development, Temperature

Abstract

Natural nests of egg-laying birds and reptiles exhibit substantial thermal variation, at a range of spatial and temporal scales. Rates and trajectories of embryonic development are highly sensitive to temperature, favouring an ability of embryos to respond adaptively (i.e. match their developmental biology to local thermal regimes). Spatially, thermal variation can be significant within a single nest (top to bottom), among adjacent nests (as a function of shading, nest depth etc.), across populations that inhabit areas with different weather conditions, and across species that differ in climates occupied and/or nest characteristics. Thermal regimes also vary temporally, in ways that generate differences among nests within a single population (e.g. due to seasonal timing of laying), among populations and across species. Anthropogenic activities (e.g. habitat clearing, climate change) add to this spatial and temporal diversity in thermal regimes. We review published literature on embryonic adaptations to spatio-temporal heterogeneity in nest temperatures. Although relatively few taxa have been studied in detail, and proximate mechanisms remain unclear, our review identifies many cases in which natural selection appears to have fine-tuned embryogenesis to match local thermal regimes. Developmental rates have been reported to differ between uppermost versus lower eggs within a single nest, between eggs laid early versus late in the season, and between populations from cooler versus warmer climates. We identify gaps in our understanding of thermal adaptations of early (embryonic) phases of the life history, and suggest fruitful opportunities for future research.

Published

2019

10. Evolutionary view of pluripotency seen from early development of non-mammalian amniotes.

Author

Nakanoh S and Agata K

Subjects

Animals, Cell Differentiation, Mammals, Biological Evolution, Birds embryology, Embryonic Development, Pluripotent Stem Cells cytology, Reptiles embryology

Abstract

Early embryonic cells are capable of acquiring numerous developmental fates until they become irreversibly committed to specific lineages depending on intrinsic determinants and/or regional interactions. From fertilization to gastrulation, such pluripotent cells first increase in number and then turn to undergoing differentiation. Mechanisms regulating pluripotency in each species attract great interest in developmental biology. Also, outlining the evolutionary background of pluripotency can enhance our understanding of mammalian pluripotency and provide a broader view of early development of vertebrates. Here, we introduce integrative models of pluripotent states in amniotes (mammals, birds and reptiles) to offer a comprehensive overview of widely accepted knowledge about mammalian pluripotency and our recent findings in non-mammalian amniotes, such as chicken and gecko. In particular, we describe 1) the IL6/Stat3 signaling pathway as a positive regulator of naive pluripotency, 2) Fgf/Erk signaling as a process that prepares cells for differentiation, 3) the role of the interactions between these two signaling pathways during the transition from pluripotency to differentiation, and 4) functional diversification of two transcription factors, Class V POUs and Nanog. In the last section, we also briefly discuss possible relationships of unique cell cycle properties of early embryonic cells with signaling pathways and developmental potentials in the pluripotent cell states., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

11. Embryological development of Salvator merianae (Squamata: Teiidae).

Author

Iungman JL, Molinero MN, Simoncini MS, and Piña CI

Subjects

Animals, Morphogenesis, Reptiles embryology

Abstract

Here we describe the embryonic development of Salvator merianae external morphologic features, as based on observation of 28 embryos across different days of incubation at 31 ± 0.5°C. Observed developmental stages were grouped and classified into the early, middle, and late periods. The early period (Stages 3-11) is distinguished by the origin of the encephalic vesicles, sensory placodes, pharyngeal arches, and degree of body flexion and rotation. The medium period (Stages 8-15) is distinguished by limb differentiation and by cranium-facial characteristics. The late period (Stages 15-18) is determined by scale patterns, pigmentation, and embryo growth., (© 2019 Wiley Periodicals, Inc.)

Published

2019

12. Hox Genes in Reptile Development, Epigenetic Regulation, and Teratogenesis.

Author

Martín-Del-Campo R, Sifuentes-Romero I, and García-Gasca A

Subjects

Animals, Embryo, Nonmammalian embryology, Embryo, Nonmammalian metabolism, Phylogeny, Reptiles classification, Reptiles embryology, Epigenesis, Genetic, Gene Expression Regulation, Developmental, Genes, Homeobox genetics, Reptiles genetics, Teratogenesis genetics

Abstract

Reptiles are ancestral organisms presenting a variety of shapes, from the elongated vertebral column of the snake to the turtle dorsalized ribs or retractile neck. Body plans are specified by a conserved group of homeobox-containing genes (Hox genes), which encode transcription factors important in cell fate and vertebral architecture along the anteroposterior axis during embryonic development; thus, dysregulation of these genes may cause congenital malformations, from mild-sublethal to embryonic-lethal. The genetic pool, maternal transfer, and environmental conditions during egg incubation affect development; environmental factors such as temperature, moisture, oxygen, and pollution may alter gene expression by epigenetic mechanisms. Thus, in this review, we present information regarding Hox genes and development in reptiles, including sex determination and teratogenesis. We also present some evidence of epigenetic regulation of Hox genes and the role of the environment in epigenetic modulation of gene expression. So far, the evidence suggests that the molecular instructions encoded by Hox genes to build a snake, a lizard, or a turtle represent the interplay between genome and epigenome after years of evolution, with occasional environmentally induced molecular mistakes leading to abnormal body shapes., (© 2018 S. Karger AG, Basel.)

Published

2019

13. Reptile Embryology and Regeneration.

Author

Vickaryous MK and Gilbert EAB

Subjects

Animals, Biomarkers, Biopsy, Breeding, Female, Fluorescent Antibody Technique, Immunohistochemistry, Lizards, Male, Embryonic Development, Regeneration, Reptiles embryology, Reptiles physiology

Abstract

Reptiles (lizards, snakes, turtles, and crocodilians) are becoming increasingly popular as models for developmental investigations. In this review the leopard gecko, Eublepharis macularius, is presented as a reptilian model for embryonic and tissue regeneration studies. We provide details of husbandry and breeding and discuss aspects of embryonic nutrition, egg anatomy, and sex determination. We provide comprehensive protocols for transcardial perfusion, short-term anesthesia using the injectable anesthetic Alfaxan, and full-thickness cutaneous biopsy punches, used in geckos for the study of scar-free wound healing. We also provide modifications to three popular histological techniques (whole-mount histochemistry, immunohistochemistry, and double-label immunofluorescence) and provide details on bromodeoxyuridine (BrdU) labeling and immuno-detection.

Published

2019

14. Insights into Germline Development and Differentiation in Molluscs and Reptiles: The Use of Molecular Markers in the Study of Non-model Animals.

Author

Milani L and Maurizii MG

Subjects

Animals, Biomarkers analysis, Biomarkers metabolism, Cell Differentiation, Germ Cells cytology, Germ Cells metabolism, Mollusca cytology, Reptiles embryology

Abstract

When shifting research focus from model to non-model species, many differences in the working approach should be taken into account and usually methodological modifications are required because of the lack of genetics/genomics and developmental information for the vast majority of organisms. This lack of data accounts for the largely incomplete understanding of how the two components-genes and developmental programs-are intermingled in the process of evolution. A deeper level of knowledge was reached for a few model animals, making it possible to understand some of the processes that guide developmental changes during evolutionary time. However, it is often difficult to transfer the obtained information to other, even closely related, animals. In this chapter, we present and discuss some examples, such as the choice of molecular markers to be used to characterize differentiation and developmental processes. The chosen examples pertain to the study of germline in molluscs, reptiles, and other non-model animals.

Published

2019

15. A comprehensive database of thermal developmental plasticity in reptiles.

Author

Noble DWA, Stenhouse V, Riley JL, Warner DA, While GM, Du WG, Uller T, and Schwanz LE

Subjects

Adaptation, Physiological, Animals, Behavior, Animal, Databases, Factual, Female, Male, Reptiles embryology, Climate Change, Reptiles physiology

Abstract

How temperature influences development has direct relevance to ascertaining the impact of climate change on natural populations. Reptiles have served as empirical models for understanding how the environment experienced by embryos can influence phenotypic variation, including sex ratio, phenology and survival. Such an understanding has important implications for basic eco-evolutionary theory and conservation efforts worldwide. While there is a burgeoning empirical literature of experimental manipulations of embryonic thermal environments, addressing widespread patterns at a comparative level has been hampered by the lack of accessible data in a format that is amendable to updates as new studies emerge. Here, we describe a database with nearly 10, 000 phenotypic estimates from 155 species of reptile, collected from 300 studies manipulating incubation temperature (published between 1974-2016). The data encompass various morphological, physiological, behavioural and performance traits along with growth rates, developmental timing, sex ratio and survival (e.g., hatching success). This resource will serve as an important data repository for addressing overarching questions about thermal plasticity of reptile embryos.

Published

2018

16. Developmental plasticity in reptiles: Critical evaluation of the evidence for genetic and maternal effects on temperature-dependent sex determination.

Author

Roush D and Rhen T

Subjects

Animals, Egg Yolk chemistry, Embryo, Nonmammalian embryology, Female, Male, Ovum, Reptiles genetics, Reptiles physiology, Steroids analysis, Reptiles embryology, Sex Determination Processes genetics, Sex Determination Processes physiology, Temperature

Abstract

We critically review literature that examines variation in temperature-dependent sex determination (TSD) within species. Although variation in sex ratio among clutches of eggs from different females is common in reptiles with TSD, the underlying mechanism that causes this variation is not clear. Authors have made claims about genetic variation in TSD and maternal effects on TSD. The latter type of study usually focuses on maternally derived steroids in egg yolk. Here, we outline the types of experiments and data required to unequivocally demonstrate that variation in sex ratio among clutches (1) has a genetic basis, (2) is caused by maternally derived steroids, or (3) is influenced by both factors. To date, few studies have met these requirements., (© 2018 Wiley Periodicals, Inc.)

Published

2018

17. Patterns of developmental plasticity in response to incubation temperature in reptiles.

Author

While GM, Noble DWA, Uller T, Warner DA, Riley JL, Du WG, and Schwanz LE

Subjects

Animals, Adaptation, Physiological, Embryo, Nonmammalian, Embryonic Development physiology, Reptiles embryology, Temperature

Abstract

Early life environments shape phenotypic development in important ways that can lead to long-lasting effects on phenotype and fitness. In reptiles, one aspect of the early environment that impacts development is temperature (termed 'thermal developmental plasticity'). Indeed, the thermal environment during incubation is known to influence morphological, physiological, and behavioral traits, some of which have important consequences for many ecological and evolutionary processes. Despite this, few studies have attempted to synthesize and collate data from this expansive and important body of research. Here, we systematically review research into thermal developmental plasticity across reptiles, structured around the key papers and findings that have shaped the field over the past 50 years. From these papers, we introduce a large database (the 'Reptile Development Database') consisting of 9,773 trait means across 300 studies examining thermal developmental plasticity. This dataset encompasses data on a range of phenotypes, including morphological, physiological, behavioral, and performance traits along with growth rate, incubation duration, sex ratio, and survival (e.g., hatching success) across all major reptile clades. Finally, from our literature synthesis and data exploration, we identify key research themes associated with thermal developmental plasticity, important gaps in empirical research, and demonstrate how future progress can be made through targeted empirical, meta-analytic, and comparative work., (© 2018 Wiley Periodicals, Inc.)

Published

2018

18. How frequent and important is behavioral thermoregulation by embryonic reptiles?

Author

Shine R and Du WG

Subjects

Animals, Embryonic Development, Reptiles physiology, Behavior, Animal physiology, Body Temperature Regulation physiology, Embryo, Nonmammalian physiology, Reptiles embryology

Abstract

The debate about behavioral thermoregulation inside reptile eggs centers on the frequency (and hence, biological significance) of the phenomenon, not about its validity. Both sides of the debate agree that large eggs in shallow nests laid in sun-exposed soil will experience clines in mean temperature and (especially) diel thermal variance; that embryos in the middle phase of development have the ability to reposition themselves, and room to do so; and that small changes in developmental temperatures can influence offspring fitness. Equally, all protagonists agree that thermal clines will be too low in some other kinds of nests, and that embryonic repositioning is impossible very early and very late in development. Based on an array of other fitness-enhancing behaviors exhibited by tetrapod embryos, and general principles for recognizing adaptation, we conclude that behavioral thermoregulation inside the egg likely is adaptive in some but not all reptile species. We identify productive directions for empirical research to resolve points of contention., (© 2018 Wiley Periodicals, Inc.)

Published

2018

19. Temperature fluctuations and maternal estrogens as critical factors for understanding temperature-dependent sex determination in nature.

Author

Bowden RM and Paitz RT

Subjects

Animals, Climate Change, Sex Ratio, Reptiles embryology, Sex Determination Processes, Temperature

Abstract

Vertebrates with temperature-dependent sex determination (TSD) have justifiably received a lot of attention when it comes to the potential effects of climate change. Freshwater turtles have long been used to characterize the physiological and genetic mechanisms underlying TSD and provide a great system to investigate how changing climatic conditions will affect vertebrates with TSD. Unfortunately, most of what we know about the mechanisms underlying TSD comes from laboratory conditions that do not accurately mimic natural conditions (i.e., constant incubation temperatures and supraphysiological steroid manipulations). In this paper, we review recent advances in our understanding of how TSD operates in nature that arose from studies using more natural fluctuating incubation temperatures and natural variation in maternal estrogens within the yolk. By incorporating more natural conditions into laboratory studies, we are better able to use these studies to predict how changing climatic conditions will affect species with TSD., (© 2018 Wiley Periodicals, Inc.)

Published

2018

20. Homologous Recombination between Genetically Divergent Campylobacter fetus Lineages Supports Host-Associated Speciation.

Author

Gilbert MJ, Duim B, van der Graaf-van Bloois L, Wagenaar JA, and Zomer AL

Subjects

Animals, Campylobacter Infections microbiology, Campylobacter fetus pathogenicity, Genetic Drift, Genome, Bacterial genetics, Mammals embryology, Mammals microbiology, Phylogeny, RNA, Ribosomal, 16S genetics, Reptiles embryology, Reptiles microbiology, Species Specificity, Whole Genome Sequencing, Campylobacter Infections genetics, Campylobacter fetus genetics, Genetic Variation, Homologous Recombination genetics

Abstract

Homologous recombination is a major driver of bacterial speciation. Genetic divergence and host association are important factors influencing homologous recombination. Here, we study these factors for Campylobacter fetus, which shows a distinct intraspecific host dichotomy. Campylobacter fetus subspecies fetus (Cff) and venerealis are associated with mammals, whereas C. fetus subsp. testudinum (Cft) is associated with reptiles. Recombination between these genetically divergent C. fetus lineages is extremely rare. Previously it was impossible to show whether this barrier to recombination was determined by the differential host preferences, by the genetic divergence between both lineages or by other factors influencing recombination, such as restriction-modification, CRISPR/Cas, and transformation systems. Fortuitously, a distinct C. fetus lineage (ST69) was found, which was highly related to mammal-associated C. fetus, yet isolated from a chelonian. The whole genome sequences of two C. fetus ST69 isolates were compared with those of mammal- and reptile-associated C. fetus strains for phylogenetic and recombination analysis. In total, 5.1-5.5% of the core genome of both ST69 isolates showed signs of recombination. Of the predicted recombination regions, 80.4% were most closely related to Cft, 14.3% to Cff, and 5.6% to C. iguaniorum. Recombination from C. fetus ST69 to Cft was also detected, but to a lesser extent and only in chelonian-associated Cft strains. This study shows that despite substantial genetic divergence no absolute barrier to homologous recombination exists between two distinct C. fetus lineages when occurring in the same host type, which provides valuable insights in bacterial speciation and evolution.

Published

2018

21. Reptile embryos are not capable of behavioral thermoregulation in the egg.

Author

Cordero GA, Telemeco RS, and Gangloff EJ

Subjects

Animals, Behavior, Animal, Embryo, Nonmammalian cytology, Embryonic Development, Ovum cytology, Temperature, Body Temperature Regulation, Embryo, Nonmammalian physiology, Ovum physiology, Reptiles embryology, Reptiles physiology

Abstract

Reptile embryos have recently been observed moving within the egg in response to temperature, raising the exciting possibility that embryos might behaviorally thermoregulate analogous to adults. However, the conjecture that reptile embryos have ample opportunity and capacity to adaptively control their body temperature warrants further discussion. Using turtles as a model, we discuss the spatiotemporal constraints to movement in reptile embryos. We demonstrate that, as embryos grow, the internal egg space rapidly diminishes such that the temporal window for appreciable displacement is confined to stages that feature incomplete neuromuscular differentiation. During this time, muscles are insufficiently developed to actively and consistently control movement. These constraints are well illustrated by the Chinese softshelled turtle (Pelodiscus sinensis), the first reptile reported to behaviorally thermoregulate. Furthermore, sporadic embryo activity peaks after the temperature-sensitive period in species with temperature-dependent sex determination, thus nullifying the opportunity for embryos to exhibit control over this important phenotype. These embryonic constraints add to previously-identified environmental constraints on behavioral thermoregulation by reptile embryos. We discuss alternative hypotheses to explain previously reported patterns of behavioral thermoregulation. Based on a holistic consideration of embryonic limitations, we conclude that reptile embryos are generally unable to adaptively behaviorally thermoregulate within the egg., (© 2017 Wiley Periodicals, Inc.)

Published

2018

22. Integrating "Evo" and "Devo": The Limb as Model Structure.

Author

Young NM

Subjects

Animals, Birds embryology, Birds genetics, Developmental Biology, Extremities embryology, Mammals embryology, Mammals genetics, Reptiles embryology, Reptiles genetics, Biological Evolution, Birds growth & development, Extremities growth & development, Mammals growth & development, Morphogenesis, Reptiles growth & development

Abstract

Reconciling the origins of morphological diversity with the deep homology of underlying mechanisms is a question fundamental to the goals of evolutionary developmental biology ("evo-devo" or EDB). In this paper I argue that differing research agendas in evolutionary and developmental biology have hindered how we address this question, but that the limb provides ideal "common ground" for their fuller integration. To support this idea, I review two previous analyses of limb variation in mammal, bird, and reptile taxa that offer complementary approaches to explaining diversity. Specifically, I present evidence suggesting that: (1) a shared genetic architecture affects the pattern of between limb developmental integration, while their functional dissociation is linked to both increased phenotypic evolvability and diversity of interlimb proportions, and (2) within limb proportional diversity is biased such that proximal and distal segments function as tradeoffs while the middle segment is more conservative, a signal that is both evident from early in morphogenesis and suggestive of an "inhibitory cascade" model of limb proximo-distal axis development. In the first case, shared genetic mechanisms predict both observed developmental integration between limbs and patterns of clade-specific diversity. In the second case, underappreciated patterns of phenotypic diversity suggest novel insights into the underlying developmental mechanisms by which variation is generated. These studies show how insights from both evolutionary and developmental biology of the limb may be used to generate novel testable hypotheses into the origins of diversity that are broadly applicable to the integration of EDB., (© The Author 2017. Published by Oxford University Press on behalf of the Society for Integrative and Comparative Biology. All rights reserved. For permissions please email: journals.permissions@oup.com.)

Published

2017

23. The evolution of cortical development: the synapsid-diapsid divergence.

Author

Goffinet AM

Subjects

Animals, Humans, Neurogenesis, Reelin Protein, Biological Evolution, Birds embryology, Cerebral Cortex embryology, Mammals embryology, Reptiles embryology

Abstract

The cerebral cortex covers the rostral part of the brain and, in higher mammals and particularly humans, plays a key role in cognition and consciousness. It is populated with neuronal cell bodies distributed in radially organized layers. Understanding the common and lineage-specific molecular mechanisms that orchestrate cortical development and evolution are key issues in neurobiology. During evolution, the cortex appeared in stem amniotes and evolved divergently in two main branches of the phylogenetic tree: the synapsids (which led to present day mammals) and the diapsids (reptiles and birds). Comparative studies in organisms that belong to those two branches have identified some common principles of cortical development and organization that are possibly inherited from stem amniotes and regulated by similar molecular mechanisms. These comparisons have also highlighted certain essential features of mammalian cortices that are absent or different in diapsids and that probably evolved after the synapsid-diapsid divergence. Chief among these is the size and multi-laminar organization of the mammalian cortex, and the propensity to increase its area by folding. Here, I review recent data on cortical neurogenesis, neuronal migration and cortical layer formation and folding in this evolutionary perspective, and highlight important unanswered questions for future investigation., Competing Interests: Competing interestsThe author declares no competing or financial interests., (© 2017. Published by The Company of Biologists Ltd.)

Published

2017

24. Temperature selection by juvenile tuatara (Sphenodon punctatus) is not influenced by temperatures experienced as embryos.

Author

Nelson NJ, Keall SN, and Hare KM

Subjects

Animals, Body Temperature, Body Temperature Regulation, Circadian Clocks, Female, Male, New Zealand, Reptiles embryology, Reptiles physiology, Seasons, Temperature, Reptiles growth & development

Abstract

Most reptiles thermoregulate to achieve body temperatures needed for biological processes, such as digestion and growth. Temperatures experienced during embryogenesis may also influence post-hatching growth rate, potentially through influencing post-hatching choice of temperatures. We investigated in laboratory settings whether embryonic temperatures (constant 18°C, 21°C and 22°C) influence selected body temperatures (T sel ) of juvenile tuatara (Sphenodon punctatus), providing a possible mechanism for differences in growth rates. We found that incubation temperature does not influence T sel . Although the average daily mean T sel was 21.6 ± 0.3°C, we recorded individual T sel values up to 33.5°C in juvenile tuatara, which is higher than expected and above the panting threshold of 31-33°C reported for adults. We found diel patterns of T sel of juvenile tuatara, observing a general pattern of two apparent peaks and troughs per day, with T sel being significantly lower around dawn and at 1500h than any other time. When comparing our results with other studies on tuatara there is a remarkable consistency in mean T sel of ~ 21°C across tuatara of different ages, sizes and acclimatization histories. The ability of juvenile tuatara to withstand a wide range of temperatures supports their former widespread distribution throughout New Zealand and warrants further investigation into their plasticity to withstand climate warming, particularly where they have choices of habitat and the ability to thermoregulate., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

25. Embryonic metabolism of the ornithischian dinosaurs Protoceratops andrewsi and Hypacrosaurus stebingeri and implications for calculations of dinosaur egg incubation times.

Author

Lee SA

Subjects

Animals, Birds embryology, Birds metabolism, Reptiles embryology, Reptiles metabolism, Species Specificity, Time Factors, Zygote metabolism, Dinosaurs embryology, Dinosaurs metabolism, Models, Biological

Abstract

The embryonic metabolisms of the ornithischian dinosaurs Protoceratops andrewsi and Hypacrosaurus stebingeri have been determined and are in the range observed in extant reptiles. The average value of the measured embryonic metabolic rates for P. andrewsi and H. stebingeri are then used to calculate the incubation times for 21 dinosaurs from both Sauischia and Ornithischia using a mass growth model based on conservation of energy. The calculated incubation times vary from about 70 days for Archaeopteryx lithographica to about 180 days for Alamosaurus sanjuanensis. Such long incubation times seem unlikely, particularly for the sauropods and large theropods. Incubation times are also predicted with the assumption that the saurischian dinosaurs had embryonic metabolisms in the range observed in extant birds.

Published

2017

26. Major evolutionary transitions and innovations: the tympanic middle ear.

Author

Tucker AS

Subjects

Animals, Birds anatomy & histology, Ear, Middle anatomy & histology, Mammals anatomy & histology, Reptiles anatomy & histology, Biological Evolution, Birds embryology, Ear, Middle embryology, Mammals embryology, Reptiles embryology

Abstract

One of the most amazing transitions and innovations during the evolution of mammals was the formation of a novel jaw joint and the incorporation of the original jaw joint into the middle ear to create the unique mammalian three bone/ossicle ear. In this review, we look at the key steps that led to this change and other unusual features of the middle ear and how developmental biology has been providing an understanding of the mechanisms involved. This starts with an overview of the tympanic (air-filled) middle ear, and how the ear drum (tympanic membrane) and the cavity itself form during development in amniotes. This is followed by an investigation of how the ear is connected to the pharynx and the relationship of the ear to the bony bulla in which it sits. Finally, the novel mammalian jaw joint and versatile dentary bone will be discussed with respect to evolution of the mammalian middle ear.This article is part of the themed issue 'Evo-devo in the genomics era, and the origins of morphological diversity'., (© 2016 The Authors.)

Published

2017

27. Dinosaur incubation periods directly determined from growth-line counts in embryonic teeth show reptilian-grade development.

Author

Erickson GM, Zelenitsky DK, Kay DI, and Norell MA

Subjects

Animals, Biological Evolution, Birds embryology, Extinction, Biological, Female, Fossils anatomy & histology, Odontogenesis, Reptiles embryology, Species Specificity, Dinosaurs embryology, Tooth embryology

Abstract

Birds stand out from other egg-laying amniotes by producing relatively small numbers of large eggs with very short incubation periods (average 11-85 d). This aspect promotes high survivorship by limiting exposure to predation and environmental perturbation, allows for larger more fit young, and facilitates rapid attainment of adult size. Birds are living dinosaurs; their rapid development has been considered to reflect the primitive dinosaurian condition. Here, nonavian dinosaurian incubation periods in both small and large ornithischian taxa are empirically determined through growth-line counts in embryonic teeth. Our results show unexpectedly slow incubation (2.8 and 5.8 mo) like those of outgroup reptiles. Developmental and physiological constraints would have rendered tooth formation and incubation inherently slow in other dinosaur lineages and basal birds. The capacity to determine incubation periods in extinct egg-laying amniotes has implications for dinosaurian embryology, life history strategies, and survivorship across the Cretaceous-Paleogene mass extinction event., Competing Interests: The authors declare no conflict of interest.

Published

2017

28. Lifting the Veil on Reptile Embryology: The Veiled Chameleon (Chamaeleo calyptratus) as a Model System to Study Reptilian Development.

Author

Diaz RE Jr, Bertocchini F, and Trainor PA

Subjects

Animals, Biological Evolution, Cells, Cultured, Embryo Culture Techniques methods, Embryo, Nonmammalian physiology, Organ Culture Techniques methods, Embryo Culture Techniques veterinary, Embryo, Nonmammalian cytology, Models, Biological, Organ Culture Techniques veterinary, Reptiles embryology

Abstract

Living amniotes comprise three major phylogenetic lineages: mammals, birds, and non-avian reptiles. Mouse and avian embryos continue to be the primary species used in experimental settings to further our knowledge and understanding of the genetics and embryology of amniotes. In comparison, non-avian reptiles, which constitute up to 40% of all living amniotes, have played a comparatively minor role. Studies of non-avian reptiles are, however, paramount for providing insights into the evolutionary changes that occurred in the transition from reptilian-like amniote ancestors to derived mammalian and avian species. Here, we introduce the Veiled Chameleon, a squamate reptile, as a new experimental model for examining fundamental questions in development, evolution, and disease.

Published

2017

29. Neuroendocrine disruption of organizational and activational hormone programming in poikilothermic vertebrates.

Author

Rosenfeld CS, Denslow ND, Orlando EF, Gutierrez-Villagomez JM, and Trudeau VL

Subjects

Amphibians embryology, Amphibians growth & development, Amphibians physiology, Animals, Brain drug effects, Brain embryology, Brain growth & development, Female, Fishes embryology, Fishes growth & development, Fishes physiology, Gonadal Steroid Hormones antagonists & inhibitors, Gonads drug effects, Gonads embryology, Gonads growth & development, Gonads physiology, Male, Neurosecretory Systems drug effects, Neurosecretory Systems embryology, Neurosecretory Systems growth & development, Neurotransmitter Agents antagonists & inhibitors, Neurotransmitter Agents physiology, Reptiles embryology, Reptiles growth & development, Reptiles physiology, Sex Determination Processes drug effects, Sex Determination Processes physiology, Vertebrates embryology, Vertebrates physiology, Endocrine Disruptors adverse effects, Gonadal Steroid Hormones physiology, Vertebrates growth & development

Abstract

In vertebrates, sexual differentiation of the reproductive system and brain is tightly orchestrated by organizational and activational effects of endogenous hormones. In mammals and birds, the organizational period is typified by a surge of sex hormones during differentiation of specific neural circuits; whereas activational effects are dependent upon later increases in these same hormones at sexual maturation. Depending on the reproductive organ or brain region, initial programming events may be modulated by androgens or require conversion of androgens to estrogens. The prevailing notion based upon findings in mammalian models is that male brain is sculpted to undergo masculinization and defeminization. In absence of these responses, the female brain develops. While timing of organizational and activational events vary across taxa, there are shared features. Further, exposure of different animal models to environmental chemicals such as xenoestrogens such as bisphenol A-BPA and ethinylestradiol-EE2, gestagens, and thyroid hormone disruptors, broadly classified as neuroendocrine disrupting chemicals (NED), during these critical periods may result in similar alterations in brain structure, function, and consequently, behaviors. Organizational effects of neuroendocrine systems in mammals and birds appear to be permanent, whereas teleost fish neuroendocrine systems exhibit plasticity. While there are fewer NED studies in amphibians and reptiles, data suggest that NED disrupt normal organizational-activational effects of endogenous hormones, although it remains to be determined if these disturbances are reversible. The aim of this review is to examine how various environmental chemicals may interrupt normal organizational and activational events in poikilothermic vertebrates. By altering such processes, these chemicals may affect reproductive health of an animal and result in compromised populations and ecosystem-level effects.

Published

2017

30. In Vitro and Ex Ovo Culture of Reptilian and Avian Neural Progenitor Cells.

Author

Yamashita W, Shimizu T, and Nomura T

Subjects

Animals, Cells, Cultured, Embryo, Nonmammalian physiology, Neural Stem Cells physiology, Birds embryology, Embryo, Nonmammalian cytology, Neural Stem Cells cytology, Reptiles embryology, Tissue Culture Techniques methods

Abstract

Reptiles and birds have been highlighted as excellent experimental models for the study of developmental biology; however, due to technical limitations in cellular analysis, dynamics of neural stem/progenitor cells of these animals remain unclear. In this chapter, we introduce the protocols for neurosphere culture and ex ovo embryonic culture of developing reptilian and avian embryos, which are modified from the method originally established for rodent embryos. Applications of these techniques provide powerful strategies for the study of comparative neural development of amniotes.

Published

2017

31. Germline development in amniotes: A paradigm shift in primordial germ cell specification.

Author

Bertocchini F and Chuva de Sousa Lopes SM

Subjects

Animals, Biological Evolution, Birds genetics, Epigenesis, Genetic, Mammals genetics, Reptiles genetics, Birds embryology, Embryonic Development, Germ Cells physiology, Mammals embryology, Reptiles embryology

Abstract

In the field of germline development in amniote vertebrates, primordial germ cell (PGC) specification in birds and reptiles remains controversial. Avians are believed to adopt a predetermination or maternal specification mode of PGC formation, contrary to an inductive mode employed by mammals and, supposedly, reptiles. Here, we revisit and review some key aspects of PGC development that channelled the current subdivision, and challenge the position of birds and reptiles as well as the 'binary' evolutionary model of PGC development in vertebrates. We propose an alternative view on PGC specification where germ plasm plays a role in laying the foundation for the formation of PGC precursors (pPGC), but not necessarily of PGCs. Moreover, inductive mechanisms may be necessary for the transition from pPGCs to PGCs. Within this framework, the implementation of data from birds and reptiles could provide new insights on the evolution of PGC specification in amniotes., (© 2016 The Authors BioEssays Published by WILEY Periodicals, Inc.)

Published

2016

32. Reptile Embryos Lack the Opportunity to Thermoregulate by Moving within the Egg.

Author

Telemeco RS, Gangloff EJ, Cordero GA, Mitchell TS, Bodensteiner BL, Holden KG, Mitchell SM, Polich RL, and Janzen FJ

Subjects

Animals, Embryo, Nonmammalian physiology, Movement, Reptiles embryology, Reptiles physiology, Temperature, Turtles physiology, Body Temperature Regulation, Turtles embryology

Abstract

Historically, egg-bound reptile embryos were thought to passively thermoconform to the nest environment. However, recent observations of thermal taxis by embryos of multiple reptile species have led to the widely discussed hypothesis that embryos behaviorally thermoregulate. Because temperature affects development, such thermoregulation could allow embryos to control their fate far more than historically assumed. We assessed the opportunity for embryos to behaviorally thermoregulate in nature by examining thermal gradients within natural nests and eggs of the common snapping turtle (Chelydra serpentina; which displays embryonic thermal taxis) and by simulating thermal gradients within nests across a range of nest depths, egg sizes, and soil types. We observed little spatial thermal variation within nests, and thermal gradients were poorly transferred to eggs. Furthermore, thermal gradients sufficiently large and constant for behavioral thermoregulation were not predicted to occur in our simulations. Gradients of biologically relevant magnitude have limited global occurrence and reverse direction twice daily when they do exist, which is substantially faster than embryos can shift position within the egg. Our results imply that reptile embryos will rarely, if ever, have the opportunity to behaviorally thermoregulate by moving within the egg. We suggest that embryonic thermal taxis instead represents a play behavior, which may be adaptive or selectively neutral, and results from the mechanisms for behavioral thermoregulation in free-living stages coming online prior to hatching.

Published

2016

33. Optimizing and benchmarking de novo transcriptome sequencing: from library preparation to assembly evaluation.

Author

Hara Y, Tatsumi K, Yoshida M, Kajikawa E, Kiyonari H, and Kuraku S

Subjects

Animals, Benchmarking, Gene Expression Profiling standards, Organ Specificity, Reference Standards, Reptiles embryology, Reptiles genetics, Gene Expression Profiling methods, Sequence Analysis, RNA

Abstract

Background: RNA-seq enables gene expression profiling in selected spatiotemporal windows and yields massive sequence information with relatively low cost and time investment, even for non-model species. However, there remains a large room for optimizing its workflow, in order to take full advantage of continuously developing sequencing capacity., Method: Transcriptome sequencing for three embryonic stages of Madagascar ground gecko (Paroedura picta) was performed with the Illumina platform. The output reads were assembled de novo for reconstructing transcript sequences. In order to evaluate the completeness of transcriptome assemblies, we prepared a reference gene set consisting of vertebrate one-to-one orthologs., Result: To take advantage of increased read length of >150 nt, we demonstrated shortened RNA fragmentation time, which resulted in a dramatic shift of insert size distribution. To evaluate products of multiple de novo assembly runs incorporating reads with different RNA sources, read lengths, and insert sizes, we introduce a new reference gene set, core vertebrate genes (CVG), consisting of 233 genes that are shared as one-to-one orthologs by all vertebrate genomes examined (29 species)., The completeness assessment performed by the computational pipelines CEGMA and BUSCO referring to CVG, demonstrated higher accuracy and resolution than with the gene set previously established for this purpose. As a result of the assessment with CVG, we have derived the most comprehensive transcript sequence set of the Madagascar ground gecko by means of assembling individual libraries followed by clustering the assembled sequences based on their overall similarities., Conclusion: Our results provide several insights into optimizing de novo RNA-seq workflow, including the coordination between library insert size and read length, which manifested in improved connectivity of assemblies. The approach and assembly assessment with CVG demonstrated here would be applicable to transcriptome analysis of other species as well as whole genome analyses.

Published

2015

34. How the pterosaur got its wings.

Author

Tokita M

Subjects

Animals, Gene Expression Regulation, Developmental, Reptiles embryology, Reptiles physiology, Wings, Animal embryology, Wings, Animal physiology, Biological Evolution, Fossils, Reptiles anatomy & histology, Wings, Animal anatomy & histology

Abstract

Throughout the evolutionary history of life, only three vertebrate lineages took to the air by acquiring a body plan suitable for powered flight: birds, bats, and pterosaurs. Because pterosaurs were the earliest vertebrate lineage capable of powered flight and included the largest volant animal in the history of the earth, understanding how they evolved their flight apparatus, the wing, is an important issue in evolutionary biology. Herein, I speculate on the potential basis of pterosaur wing evolution using recent advances in the developmental biology of flying and non-flying vertebrates. The most significant morphological features of pterosaur wings are: (i) a disproportionately elongated fourth finger, and (ii) a wing membrane called the brachiopatagium, which stretches from the posterior surface of the arm and elongated fourth finger to the anterior surface of the leg. At limb-forming stages of pterosaur embryos, the zone of polarizing activity (ZPA) cells, from which the fourth finger eventually differentiates, could up-regulate, restrict, and prolong expression of 5'-located Homeobox D (Hoxd) genes (e.g. Hoxd11, Hoxd12, and Hoxd13) around the ZPA through pterosaur-specific exploitation of sonic hedgehog (SHH) signalling. 5'Hoxd genes could then influence downstream bone morphogenetic protein (BMP) signalling to facilitate chondrocyte proliferation in long bones. Potential expression of Fgf10 and Tbx3 in the primordium of the brachiopatagium formed posterior to the forelimb bud might also facilitate elongation of the phalanges of the fourth finger. To establish the flight-adapted musculoskeletal morphology shared by all volant vertebrates, pterosaurs probably underwent regulatory changes in the expression of genes controlling forelimb and pectoral girdle musculoskeletal development (e.g. Tbx5), as well as certain changes in the mode of cell-cell interactions between muscular and connective tissues in the early phase of their evolution. Developmental data now accumulating for extant vertebrate taxa could be helpful in understanding the cellular and molecular mechanisms of body-plan evolution in extinct vertebrates as well as extant vertebrates with unique morphology whose embryonic materials are hard to obtain., (© 2014 The Author. Biological Reviews © 2014 Cambridge Philosophical Society.)

Published

2015

35. Resurrecting embryos of the tuatara, Sphenodon punctatus, to resolve vertebrate phallus evolution.

Author

Sanger TJ, Gredler ML, and Cohn MJ

Subjects

Animals, Male, Organogenesis, Penis embryology, Phylogeny, Biological Evolution, Genitalia, Male embryology, Reptiles embryology

Abstract

The breadth of anatomical and functional diversity among amniote external genitalia has led to uncertainty about the evolutionary origins of the phallus. In several lineages, including the tuatara, Sphenodon punctatus, adults lack an intromittent phallus, raising the possibility that the amniote ancestor lacked external genitalia and reproduced using cloacal apposition. Accordingly, a phallus may have evolved multiple times in amniotes. However, similarities in development across amniote external genitalia suggest that the phallus may have a single evolutionary origin. To resolve the evolutionary history of amniote genitalia, we performed three-dimensional reconstruction of Victorian era tuatara embryos to look for embryological evidence of external genital initiation. Despite the absence of an intromittent phallus in adult tuataras, our observations show that tuatara embryos develop genital anlagen. This illustrates that there is a conserved developmental stage of external genital development among all amniotes and suggests a single evolutionary origin of amniote external genitalia., (© 2015 The Author(s).)

Published

2015

36. The Veiled Chameleon (Chamaeleo calyptratus Duméril and Duméril 1851): A Model for Studying Reptile Body Plan Development and Evolution.

Author

Diaz RE Jr, Anderson CV, Baumann DP, Kupronis R, Jewell D, Piraquive C, Kupronis J, Winter K, Bertocchini F, and Trainor PA

Subjects

Animals, Body Patterning, Models, Animal, Reptiles embryology

Abstract

Vertebrate model organisms have facilitated the discovery and exploration of morphogenetic events and developmental pathways that underpin normal and pathological embryological events. In contrast to amniotes such as Mus musculus (Mammalia) and Gallus gallus (Aves), our understanding of early patterning and developmental events in reptiles (particularly nonavians) remains weak. Squamate reptiles (lizards, snakes, and amphisbaenians) comprise approximately one-third of all living amniotes. But studies of early squamate development have been limited because, in most members of this lineage, embryo development at the time of oviposition is very advanced (limb bud stages and older). In many cases, squamates give birth to fully developed offspring. However, in the veiled chameleon (Chamaeleo calyptratus), embryos have progressed only to a primitive pregastrula stage at the time of oviposition. Furthermore, the body plan of the veiled chameleon is highly specialized for climbing in an arboreal environment. It possesses an entire suite of skeletal and soft anatomical modifications, including cranioskeletal ornamentation, lingual anatomy and biomechanics for projection, autopodial clefting for grasping, adaptations for rapid integumental color changes, a prehensile tail with a lack of caudal autotomy, the loss of the tympanum in the middle ear, and the acquisition of turreted eyes. Thus, C. calyptratus is an important model organism for studying the role of ecological niche specialization, as well as genetic and morphological evolution within an adaptive framework. More importantly, this species is easily bred in captivity, with only a small colony (<10 individuals) needed to obtain hundreds of embryos every year., (© 2015 Cold Spring Harbor Laboratory Press.)

Published

2015

37. Evolution of vertebrate viviparity and specializations for fetal nutrition: A quantitative and qualitative analysis.

Author

Blackburn DG

Subjects

Amphibians embryology, Amphibians physiology, Animals, Female, Mammals embryology, Mammals physiology, Phylogeny, Pregnancy, Reptiles embryology, Reptiles physiology, Biological Evolution, Pregnancy, Animal, Viviparity, Nonmammalian

Abstract

Phylogenetic analyses indicate that viviparity (live-bearing reproduction) has originated independently in more than 150 vertebrate lineages, including a minimum of 115 clades of extant squamate reptiles. Other evolutionary origins of viviparity include 13 origins among bony fishes, nine among chondrichthyans, eight in amphibians, one in Paleozoic placoderms, six among extinct reptiles, and one in mammals. The origins of viviparity range geologically from the mid-Paleozoic through the Mesozoic to the Pleistocene. Substantial matrotrophy (maternal provision of nutrients to embryos during pregnancy) has arisen at least 33 times in these viviparous clades, with most (26) of these origins having occurred among fishes and amphibians. Convergent evolution in patterns of matrotrophy is widespread, as reflected by multiple independent origins of placentotrophy, histotrophy, oophagy, and embryophagy. Specializations for nutrient transfer to embryos are discontinuously distributed, reflecting the roles of phylogenetic inertia, exaptation (preadaptation), and constraint. Ancestral features that function in gas exchange and nutrition repeatedly and convergently have been co-opted for nutrient transfer, often through minor modification of their components and changes in the timing of their expression (heterochrony). Studies on functional and evolutionary morphology continue to play a central role in our attempts to understand viviparity and mechanisms of fetal nutrition., (© 2014 Wiley Periodicals, Inc.)

Published

2015

38. A molecular mechanism for the origin of a key evolutionary innovation, the bird beak and palate, revealed by an integrative approach to major transitions in vertebrate history.

Author

Bhullar BA, Morris ZS, Sefton EM, Tok A, Tokita M, Namkoong B, Camacho J, Burnham DA, and Abzhanov A

Subjects

Animals, Beak embryology, Birds embryology, Birds genetics, Chick Embryo, Chickens, Fossils anatomy & histology, Palate embryology, Phenotype, Reptiles anatomy & histology, Reptiles embryology, Reptiles genetics, Beak anatomy & histology, Biological Evolution, Birds anatomy & histology, Gene Expression Regulation, Developmental, Palate anatomy & histology

Abstract

The avian beak is a key evolutionary innovation whose flexibility has permitted birds to diversify into a range of disparate ecological niches. We approached the problem of the mechanism behind this innovation using an approach bridging paleontology, comparative anatomy, and experimental developmental biology. First, we used fossil and extant data to show the beak is distinctive in consisting of fused premaxillae that are geometrically distinct from those of ancestral archosaurs. To elucidate underlying developmental mechanisms, we examined candidate gene expression domains in the embryonic face: the earlier frontonasal ectodermal zone (FEZ) and the later midfacial WNT-responsive region, in birds and several reptiles. This permitted the identification of an autapomorphic median gene expression region in Aves. To test the mechanism, we used inhibitors of both pathways to replicate in chicken the ancestral amniote expression. Altering the FEZ altered later WNT responsiveness to the ancestral pattern. Skeletal phenotypes from both types of experiments had premaxillae that clustered geometrically with ancestral fossil forms instead of beaked birds. The palatal region was also altered to a more ancestral phenotype. This is consistent with the fossil record and with the tight functional association of avian premaxillae and palate in forming a kinetic beak., (© 2015 The Author(s). Evolution © 2015 The Society for the Study of Evolution.)

Published

2015

39. The behavioural and physiological strategies of bird and reptile embryos in response to unpredictable variation in nest temperature.

Author

Du WG and Shine R

Subjects

Acclimatization, Animals, Ovum physiology, Temperature, Birds embryology, Reptiles embryology

Abstract

Temperature profoundly affects the rate and trajectory of embryonic development, and thermal extremes can be fatal. In viviparous species, maternal behaviour and physiology can buffer the embryo from thermal fluctuations; but in oviparous animals (like most reptiles and all birds), an embryo is likely to encounter unpredictable periods when incubation temperatures are unfavourable. Thus, we might expect natural selection to have favoured traits that enable embryos to maintain development despite those fluctuations. Our review of recent research identifies three main routes that embryos use in this way. Extreme temperatures (i) can be avoided (e.g. by accelerating hatching, by moving within the egg, by cooling the egg by enhanced rates of evaporation, or by hysteresis in rates of heating versus cooling); (ii) can be tolerated (e.g. by entering diapause, by producing heat-shock proteins, or by changing oxygen use); or (iii) the embryo can adjust its physiology and/or developmental trajectory in ways that reduce the fitness penalties of unfavourable thermal conditions (e.g. by acclimating, by exploiting brief windows of favourable conditions, or by producing the hatchling phenotype best suited to those incubation conditions). Embryos are not simply passive victims of ambient conditions. Like free-living stages of the life cycle, embryos exhibit behavioural and physiological plasticity that enables them to deal with unpredictable abiotic challenges., (© 2014 The Authors. Biological Reviews © 2014 Cambridge Philosophical Society.)

Published

2015

40. Lungs of the first amniotes: why simple if they can be complex?

Author

Lambertz M, Grommes K, Kohlsdorf T, and Perry SF

Subjects

Amphibians anatomy & histology, Amphibians embryology, Animals, Birds anatomy & histology, Birds embryology, Lung embryology, Mammals anatomy & histology, Mammals embryology, Reptiles anatomy & histology, Reptiles embryology, Biological Evolution, Lung anatomy & histology, Respiration

Abstract

We show-in contrast to the traditional textbook contention-that the first amniote lungs were complex, multichambered organs and that the single-chambered lungs of lizards and snakes represent a secondarily simplified rather than the plesiomorphic condition. We combine comparative anatomical and embryological data and show that shared structural principles of multichamberedness are recognizable in amniotes including all lepidosaurian taxa. Sequential intrapulmonary branching observed during early organogenesis becomes obscured during subsequent growth, resulting in a secondarily simplified, functionally single-chambered lung in lepidosaurian adults. Simplification of pulmonary structure maximized the size of the smallest air spaces and eliminated biophysically compelling surface tension problems that were associated with miniaturization evident among stem lepidosaurmorphs. The remaining amniotes, however, retained the multichambered lungs, which allowed both large surface area and high pulmonary compliance, thus initially providing a strong selective advantage for efficient respiration in terrestrial environments. Branched, multichambered lungs instead of simple, sac-like organs were part and parcel of the respiratory apparatus of the first amniotes and pivotal for their success on dry land, with the sky literally as the limit., (© 2015 The Author(s) Published by the Royal Society. All rights reserved.)

Published

2015

41. Fitness consequences of maternal and embryonic responses to environmental variation: using reptiles as models for studies of developmental plasticity.

Author

Warner DA

Subjects

Animals, Embryo, Nonmammalian embryology, Environment, Phenotype, Embryonic Development, Genetic Fitness, Reptiles embryology, Reptiles genetics, Selection, Genetic

Abstract

Environmental factors strongly influence phenotypic variation within populations. The environment contributes to this variation in two ways: (1) by acting as a determinant of phenotypic variation (i.e., plastic responses) and (2) as an agent of selection that "chooses" among existing phenotypes. Understanding how these two environmental forces contribute to phenotypic variation is a major goal in the field of evolutionary biology and a primary objective of my research program. The objective of this article is to provide a framework to guide studies of environmental sources of phenotypic variation (specifically, developmental plasticity and maternal effects, and their adaptive significance). Two case studies from my research on reptiles are used to illustrate the general approaches I have taken to address these conceptual topics. Some key points for advancing our understanding of environmental influences on phenotypic variation include (1) merging laboratory-based research that identifies specific environmental effects with field studies to validate ecological relevance; (2) using controlled experimental approaches that mimic complex environments found in nature; (3) integrating data across biological fields (e.g., genetics, morphology, physiology, behavior, and ecology) under an evolutionary framework to provide novel insights into the underlying mechanisms that generate phenotypic variation; (4) assessing fitness consequences using measurements of survival and/or reproductive success across ontogeny (from embryos to adults) and under multiple ecologically-meaningful contexts; and (5) quantifying the strength and form of natural selection in multiple populations over multiple periods of time to understand the spatial and temporal consistency of phenotypic selection. Research programs that focus on organisms that are amenable to these approaches will provide the most promise for advancing our understanding of the environmental factors that generate the remarkable phenotypic diversity observed within populations., (© The Author 2014. Published by Oxford University Press on behalf of the Society for Integrative and Comparative Biology. All rights reserved. For permissions please email: journals.permissions@oup.com.)

Published

2014

42. Thermoregulatory behavior is widespread in the embryos of reptiles and birds.

Author

Li T, Zhao B, Zhou YK, Hu R, and Du WG

Subjects

Animals, Embryo, Nonmammalian, Ovum physiology, Species Specificity, Behavior, Animal physiology, Birds embryology, Body Temperature Regulation, Reptiles embryology

Abstract

Recent studies have demonstrated that thermoregulatory behavior occurs not only in posthatching turtles but also in turtles prior to hatching. Does thermoregulatory behavior also occur in the embryos of other reptile and bird species? Our experiments show that such behavior is widespread but not universal in reptile and bird embryos. We recorded repositioning within the egg, in response to thermal gradients, in the embryos of three species of snakes (Xenochrophis piscator, Elaphe bimaculata, and Zaocys dhumnades), two turtles (Chelydra serpentina and Ocadia sinensis), one crocodile (Alligator sinensis), and four birds (Coturnix coturnix, Gallus gallus domesticus, Columba livia domestica, and Anas platyrhynchos domestica). However, we detected no significant thermoregulation by the embryos of two lizard species (Takydromus septentrionalis and Phrynocephalus frontalis). Overall, embryonic thermoregulatory behavior is widespread in reptile as well as bird species but may be unimportant in the small eggs laid by most lizards.

Published

2014

43. Terrestrial origin of viviparity in mesozoic marine reptiles indicated by early triassic embryonic fossils.

Author

Motani R, Jiang DY, Tintori A, Rieppel O, and Chen GB

Subjects

Animals, Biological Evolution, Classification, Environment, Extinction, Biological, Female, Oceans and Seas, Phylogeny, Skull, Temperature, Fossils, Reptiles anatomy & histology, Reptiles embryology, Viviparity, Nonmammalian

Abstract

Viviparity in Mesozoic marine reptiles has traditionally been considered an aquatic adaptation. We report a new fossil specimen that strongly contradicts this traditional interpretation. The new specimen contains the oldest fossil embryos of Mesozoic marine reptile that are about 10 million years older than previous such records. The fossil belongs to Chaohusaurus (Reptilia, Ichthyopterygia), which is the oldest of Mesozoic marine reptiles (ca. 248 million years ago, Early Triassic). This exceptional specimen captures an articulated embryo in birth position, with its skull just emerged from the maternal pelvis. Its headfirst birth posture, which is unlikely to be a breech condition, strongly indicates a terrestrial origin of viviparity, in contrast to the traditional view. The tail-first birth posture in derived ichthyopterygians, convergent with the conditions in whales and sea cows, therefore is a secondary feature. The unequivocally marine origin of viviparity is so far not known among amniotes, a subset of vertebrate animals comprising mammals and reptiles, including birds. Therefore, obligate marine amniotes appear to have evolved almost exclusively from viviparous land ancestors. Viviparous land reptiles most likely appeared much earlier than currently thought, at least as early as the recovery phase from the end-Permian mass extinction.

Published

2014

44. Amniote yolk sacs: diversity in reptiles and a hypothesis on their origin.

Author

Elinson RP, Stewart JR, Bonneau LJ, and Blackburn DG

Subjects

Amnion cytology, Animals, Egg Proteins genetics, Embryo, Nonmammalian blood supply, Yolk Sac cytology, Reptiles embryology, Yolk Sac blood supply, Yolk Sac embryology

Abstract

Oviparous amniotes produce a large yolky egg that gives rise to a free-living hatchling. Structural characteristics and functional attributes of the egg are best known for birds, which have a large mass of fluid yolk surrounded by an extraembryonic yolk sac. Yolk nutrients are delivered to the embryo via the vascular yolk sac. This developmental pattern and nutrient transport mechanism is thought to be representative of all other lineages of amniotes. Recent discovery of a snake with cellularized yolk organized around a meshwork of blood vessels reveals an additional pattern for yolk mobilization, which may also occur in other squamate reptiles (lizards and snakes). This complex yolk sac raises interesting questions about developmental mechanisms and suggests a possible model for the transition between the egg of anamniotes and that of amniotes.

Published

2014

45. Developmental Herpetology--state of the art of amphibian and reptile developmental biology.

Author

Kubiak JZ and Kloc M

Subjects

Animals, Amphibians embryology, Developmental Biology, Reptiles embryology

Published

2014

46. Transition from embryonic to adult epidermis in reptiles occurs by the production of corneous beta-proteins.

Author

Alibardi L

Subjects

Animals, Biological Evolution, Cell Differentiation genetics, Embryo, Nonmammalian embryology, Epidermis growth & development, Hydrophobic and Hydrophilic Interactions, Reptilian Proteins biosynthesis, Epidermis embryology, Keratins, Type I metabolism, Reptiles embryology, Reptilian Proteins genetics, beta-Keratins metabolism

Abstract

The adaptation of the epidermis in amniote vertebrates to life on land took place by a drastic change from an embryonic epidermis made of two-four periderm layers to a terrestrial-proof epidermis. This transition occurred by the increase in types and number of specialized corneous proteins coded by genes of the Epidermal Differentiation Complex. The prevalent types of corneous proteins produced in the reptilian epidermis contain a beta-sheet region of high amino acid homology which allows their polymerization into a meshwork of filaments forming the hard corneous material of scales and claws. The present immunogold ultrastructural study shows that this transition occurs with the synthesis of glycine-rich corneous beta-proteins (formerly indicated as beta-keratins) that are added to the initial framework of acidic intermediate filaments produced in the embryonic epidermis of lizards, snake, alligator and turtle. These corneous beta-proteins are accumulated in the transitional and definitive layers of reptilian epidermis formed underneath the transitory two-four layered embryonic epidermis. In the more specialized reptiles capable of shedding the epidermis as a single unit, such as lizards and snakes, special glycine-cysteine rich beta-proteins are initially produced in a single layer immediately formed beneath the embryonic epidermis, the oberhautchen. The latter layer allows the in ovo shedding of the embryonic epidermis in preparation for hatching, and in the following shedding cycles of the adult epidermis. The production of specialized corneous-specific beta-proteins in addition to intermediate filament keratins was probably an essential addition for terrestrial life during the evolution of reptiles into different lineages, including birds. The increase of glycine and cysteine in epidermal proteins enhanced the hydrophobicity, insolubility and mechanical strength of the stratum corneum in these amniotes.

Published

2014

47. Reptile genomes open the frontier for comparative analysis of amniote development and regeneration.

Author

Tollis M, Hutchins ED, and Kusumi K

Subjects

Animals, Biological Evolution, Developmental Biology, Genome genetics, Phylogeny, Regeneration physiology, Reptiles classification, Transcriptome genetics, Gene Expression Regulation, Developmental genetics, Reptiles embryology, Reptiles genetics

Abstract

Developmental genetic studies of vertebrates have focused primarily on zebrafish, frog and mouse models, which have clear application to medicine and well-developed genomic resources. In contrast, reptiles represent the most diverse amniote group, but have only recently begun to gather the attention of genome sequencing efforts. Extant reptilian groups last shared a common ancestor ?280 million years ago and include lepidosaurs, turtles and crocodilians. This phylogenetic diversity is reflected in great morphological and behavioral diversity capturing the attention of biologists interested in mechanisms regulating developmental processes such as somitogenesis and spinal patterning, regeneration, the evolution of "snake-like" morphology, the formation of the unique turtle shell, and the convergent evolution of the four-chambered heart shared by mammals and archosaurs. The complete genome of the first non-avian reptile, the green anole lizard, was published in 2011 and has provided insights into the origin and evolution of amniotes. Since then, the genomes of multiple snakes, turtles, and crocodilians have also been completed. Here we will review the current diversity of available reptile genomes, with an emphasis on their evolutionary relationships, and will highlight how these genomes have and will continue to facilitate research in developmental and regenerative biology.

Published

2014

48. Fetal nutrition in lecithotrophic squamate reptiles: toward a comprehensive model for evolution of viviparity and placentation.

Author

Stewart JR

Subjects

Animals, Biological Evolution, Embryo, Nonmammalian metabolism, Female, Oviparity physiology, Reproduction, Viviparity, Nonmammalian physiology, Reptiles embryology, Reptiles physiology

Abstract

The primary pattern of embryonic nutrition for squamate reptiles is lecithotrophy; with few exceptions, all squamate embryos mobilize nutrients from yolk. The evolution of viviparity presents an opportunity for an additional source of embryonic nutrition through delivery of uterine secretions, or placentotrophy. This pattern of embryonic nutrition is thought to evolve through placental supplementation of lecithotrophy, followed by increasing dependence on placentotrophy. This review analyzes the relationship between reproductive mode and pattern of embryonic nutrition in three lecithotrophic viviparous species, and oviparous counterparts, for concordance with a current model for the evolution of viviparity and placentation. The assumptions of the model, that nutrients for oviparous embryos are mobilized from yolk, and that this source is not disrupted in the transition to viviparity, are supported for most nutrients. In contrast, calcium, an essential nutrient for embryonic development, is mobilized from both yolk and eggshell by oviparous embryos and reduction of eggshell calcium is correlated with viviparity. If embryonic fitness is compromised by disruption of a primary source of calcium, selection may not favor evolution of viviparity, yet viviparity has arisen independently in numerous squamate lineages. Studies of fetal nutrition in reproductively bimodal species suggest a resolution to this paradox. If uterine calcium secretion occurs during prolonged intrauterine egg retention, calcium placentotrophy evolves prior to viviparity as a replacement for eggshell calcium and embryonic nutrition will not be compromised. This hypothesis is integrated into the current model for evolution of viviparity and placentation to address the unique attributes of calcium nutrition. The sequence of events requires a shift in timing of uterine calcium secretion and the embryonic mechanism of calcium retrieval to be responsive to calcium availability. Regulation of uterine calcium secretion and the mechanism of embryonic uptake of calcium are important elements to understanding evolution of viviparity and placentation., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

49. Towards an understanding of the evolution of the chorioallantoic placenta: steroid biosynthesis and steroid hormone signaling in the chorioallantoic membrane of an oviparous reptile.

Author

Cruze L, Kohno S, McCoy MW, and Guillette LJ Jr

Subjects

Alligators and Crocodiles embryology, Alligators and Crocodiles genetics, Alligators and Crocodiles metabolism, Alligators and Crocodiles physiology, Animals, Chick Embryo, Chickens, Chorioallantoic Membrane anatomy & histology, Comprehension, Cytochrome P-450 Enzyme System genetics, Cytochrome P-450 Enzyme System metabolism, Embryo, Nonmammalian, Female, Gene Expression Regulation, Developmental, Models, Biological, Signal Transduction genetics, Signal Transduction physiology, Biological Evolution, Chorioallantoic Membrane metabolism, Chorioallantoic Membrane physiology, Gonadal Steroid Hormones metabolism, Oviparity genetics, Oviparity physiology, Reptiles embryology, Reptiles genetics, Reptiles metabolism, Reptiles physiology, Steroids biosynthesis

Abstract

Amniotes, mammals, reptiles, and birds form common extraembryonic membranes during development to perform essential functions, such as protection, nutrient transfer, gas exchange, and waste removal. Together with the maternal uterus, extraembryonic membranes of viviparous (live-bearing) amniotes develop as an endocrine placenta that synthesizes and responds to steroid hormones critical for development. The ability of these membranes to synthesize and respond to steroid hormone signaling has traditionally been considered an innovation of placental amniotes. However, our laboratory recently demonstrated that this ability extends to the chorioallantoic membrane (CAM) of an oviparous (egg-laying) amniote, the domestic chicken, and we hypothesized that steroidogenic extraembryonic membranes could be an evolutionarily conserved characteristic of all amniotes because of similarities in basic structure, function, and shared evolutionary ancestry. In this study, we examined steroid hormone synthesis and signaling in the CAM of another oviparous amniote, the American alligator (Alligator mississippiensis). We quantified mRNA expression of a steroidogenic factor involved in the regulation of steroidogenesis (NR5A1), the key steroidogenic enzymes involved in the synthesis of progestins (HSD3B1), androgens (CYP17A1), and estrogens (CYP19A1), and the receptors involved in the signaling of progestins (PR), androgens (AR), estrogens (ESR1 and ESR2), and glucocorticoids (GR). Furthermore, we performed protein immunolocalization for PR and ESR1. Collectively, our findings indicate that the alligator CAM has the capability to regulate, synthesize, and respond to steroid hormone signaling, thus, supporting our hypothesis that the extraembryonic membranes of Amniota share a unifying characteristic, that is, the ability to synthesize and respond to steroid hormones.

Published

2012

50. Heterochronically early decline of Hox expression prior to cartilage formation in the avian hindlimb zeugopod.

Author

Kamiyama N, Seki R, Yokoyama H, and Tamura K

Subjects

Animals, Cartilage embryology, Cartilage metabolism, Chick Embryo, Chickens genetics, Chickens metabolism, Embryonic Development, Fibula anatomy & histology, Fibula embryology, Fibula metabolism, Hindlimb anatomy & histology, Hindlimb metabolism, Homeodomain Proteins genetics, Limb Buds anatomy & histology, Limb Buds embryology, Limb Buds metabolism, Mesoderm embryology, Mesoderm metabolism, Mice, Reptiles anatomy & histology, Reptiles embryology, Reptiles genetics, Species Specificity, Transcription Factors genetics, Chickens growth & development, Gene Expression Regulation, Developmental, Hindlimb embryology, Homeodomain Proteins metabolism, Transcription Factors metabolism

Abstract

The fibula, a zeugopod bone in the hindlimb, exhibits various morphologies in tetrapod species. The fibula in some species has a similar length with the other zeugopod element, the tibia, while other species have obvious differences in the sizes of the two elements. In the avian hindlimb, for example, the fibula is extremely short, thin, and truncated. Basic morphology of the fibula is established during development, and cartilage primordium of the bone emerges in a certain region defined by a distinct combination of expression of Hox genes (Hox code). In order to elucidate how the different morphologies are produced from a region that is defined as the fixed Hox code, we examined spatial and temporal patterns of Hoxd11/Hoxd12 expression in the developing limb bud, which defines the region from which the fibula emerges, in comparison with the sites of precartilaginous mesenchymal condensations representing regions for cartilage formation among chick, mouse, and gecko embryos. We found that in the chick hindlimb, expression of Hoxd11/Hoxd12 decreased and disappeared from the presumptive zeugopod region before cartilage formation. This heterochronically early decline of expression of Hox genes is strongly correlated with the peculiar trait of the fibula in the avian hindlimb, since in the other species examined, expression of those genes continued after the onset of cartilage formation. This is morphological phenotype-related because the early disappearance was not seen in the chick forelimb. Our results suggest that temporal change of the Hox code governs diversification in morphology of homologous structures among related species., (© 2012 The Authors Development, Growth & Differentiation © 2012 Japanese Society of Developmental Biologists.)

Published

2012