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4. Histological Diversity And Evolution Of Lizard Osteoderms

Author

Vickaryous, Matthew, primary, Williams, Catherine, additional, Willan, Gabriella, additional, Kirby, Alex, additional, Herrel, Anthony, additional, Kever, Loic, additional, Moazen, Mehran, additional, Marghoub, Arsalan, additional, Rai, Shreya, additional, Abzhanov, Arkhat, additional, and Evans, Susan, additional

Published
2022
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7. Darwin's finches - an adaptive radiation constructed from ancestral genetic modules

Author

Rubin, Carl-Johan, primary, Enbody, Erik D, additional, Dobreva, Mariya P, additional, Abzhanov, Arkhat, additional, Davis, Brian W, additional, Lamichhaney, Sangeet, additional, Pettersson, Mats E, additional, Sprehn, Charlotte G, additional, Valle, Carlos A, additional, Vasco, Karla, additional, Wallerman, Ola, additional, Grant, B Rosemary, additional, Grant, Peter, additional, and Andersson, Leif, additional

Published
2021
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8. A review of the osteoderms of lizards (Reptilia: Squamata)

Author

Williams, Catherine, primary, Kirby, Alexander, additional, Marghoub, Arsalan, additional, Kéver, Loïc, additional, Ostashevskaya‐Gohstand, Sonya, additional, Bertazzo, Sergio, additional, Moazen, Mehran, additional, Abzhanov, Arkhat, additional, Herrel, Anthony, additional, Evans, Susan E., additional, and Vickaryous, Matt, additional

Published
2021
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9. Phylogenetic and ontogenetic changes of the anatomical organization and modularity in the skull of archosaurs

Author

Lee, Hiu Wai, Esteve-Altava, Borja, and Abzhanov, Arkhat

Abstract

Comparative anatomy studies of the skull of archosaurs provide insights on the mechanisms of evolution for the morphologically and functionally diverse species of crocodiles and birds. One of the key attributes of skull evolution is the anatomical changes associated with the physical arrangement of cranial bones. Here, we compare the changes in anatomical organization and modularity of the skull of extinct and extant archosaurs using an Anatomical Network Analysis approach. We show that the number of bones, their topological arrangement, and modular organization can discriminate between birds, non-avian dinosaurs, and crurotarsans, and between extant and extinct species. By comparing within the same framework juveniles and adults for crown birds and alligator ( Alligator mississippiensis ), we find that adult and juvenile alligator skulls are topologically similar, whereas juvenile bird skulls have a morphological complexity and anisomerism more similar to that of non-avian dinosaurs and crurotarsans than to their adult forms. Clade-specific ontogenetic differences in skull organization, such as extensive postnatal fusion of cranial bones in crown birds, can explain this pattern. The fact that juvenile and adult skulls in birds do share a similar anatomical integration suggests the presence of specific constraint in their ontogenetic growth.

Published
2020
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15. A review of the osteoderms of lizards (Reptilia: Squamata).

Author

Williams, Catherine, Kirby, Alexander, Marghoub, Arsalan, Kéver, Loïc, Ostashevskaya‐Gohstand, Sonya, Bertazzo, Sergio, Moazen, Mehran, Abzhanov, Arkhat, Herrel, Anthony, Evans, Susan E., and Vickaryous, Matt

Subjects
SQUAMATA, LIZARDS, CANCELLOUS bone, PROTECTIVE clothing, CROCODILIANS, REPTILES, COLUBRIDAE
Abstract

Osteoderms are mineralised structures consisting mainly of calcium phosphate and collagen. They form directly within the skin, with or without physical contact with the skeleton. Osteoderms, in some form, may be primitive for tetrapods as a whole, and are found in representatives of most major living lineages including turtles, crocodilians, lizards, armadillos, and some frogs, as well as extinct taxa ranging from early tetrapods to dinosaurs. However, their distribution in time and space raises questions about their evolution and homology in individual groups. Among lizards and their relatives, osteoderms may be completely absent; present only on the head or dorsum; or present all over the body in one of several arrangements, including non‐overlapping mineralised clusters, a continuous covering of overlapping plates, or as spicular mineralisations that thicken with age. This diversity makes lizards an excellent focal group in which to study osteoderm structure, function, development and evolution. In the past, the focus of researchers was primarily on the histological structure and/or the gross anatomy of individual osteoderms in a limited sample of taxa. Those studies demonstrated that lizard osteoderms are sometimes two‐layered structures, with a vitreous, avascular layer just below the epidermis and a deeper internal layer with abundant collagen within the deep dermis. However, there is considerable variation on this model, in terms of the arrangement of collagen fibres, presence of extra tissues, and/or a cancellous bone core bordered by cortices. Moreover, there is a lack of consensus on the contribution, if any, of osteoblasts in osteoderm development, despite research describing patterns of resorption and replacement that would suggest both osteoclast and osteoblast involvement. Key to this is information on development, but our understanding of the genetic and skeletogenic processes involved in osteoderm development and patterning remains minimal. The most common proposition for the presence of osteoderms is that they provide a protective armour. However, the large morphological and distributional diversity in lizard osteoderms raises the possibility that they may have other roles such as biomechanical reinforcement in response to ecological or functional constraints. If lizard osteoderms are primarily for defence, whether against predators or conspecifics, then this 'bony armour' might be predicted to have different structural and/or mechanical properties compared to other hard tissues (generally intended for support and locomotion). The cellular and biomineralisation mechanisms by which osteoderms are formed could also be different from those of other hard tissues, as reflected in their material composition and nanostructure. Material properties, especially the combination of malleability and resistance to impact, are of interest to the biomimetics and bioinspired material communities in the development of protective clothing and body armour. Currently, the literature on osteoderms is patchy and is distributed across a wide range of journals. Herein we present a synthesis of current knowledge on lizard osteoderm evolution and distribution, micro‐ and macrostructure, development, and function, with a view to stimulating further work. [ABSTRACT FROM AUTHOR]

Published
2022
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16. Time to synchronize our clocks: Connecting developmental mechanisms and evolutionary consequences of heterochrony.

Author

Dobreva, Mariya P., Camacho, Jasmin, and Abzhanov, Arkhat

Subjects
MOLECULAR clock, COMPARATIVE anatomy, CELL morphology, COMPARATIVE method, BIOLOGISTS, ONTOGENY
Abstract

Heterochrony, defined as a change in the timing of developmental events altering the course of evolution, was first recognized by Ernst Haeckel in 1866. Haeckel's original definition was meant to explain the observed parallels between ontogeny and phylogeny, but the interpretation of his work became a source of controversy over time. Heterochrony took its modern meaning following the now classical work in the 1970–80s by Steven J. Gould, Pere Alberch, and co‐workers. Predicted and described heterochronic scenarios emphasize the many ways in which developmental changes can influence evolution. However, while important examples of heterochrony detected with comparative morphological methods have multiplied, the more mechanistic understanding of this phenomenon lagged conspicuously behind. Considering the rapid progress in imaging and molecular tools available now for developmental biologists, this review aims to stress the need to take heterochrony research to the next level. It is time to synchronize the different levels of heterochrony research into a single analysis flow: from studies on organismal‐level morphology to cells to molecules and genes, using complementary techniques. To illustrate how to achieve a more comprehensive understanding of phyletic morphological diversification associated with heterochrony, we discuss several recent case studies at various phylogenetic scales that combine morphological, cellular, and molecular analyses. Such a synergistic approach offers to more fully integrate phylogenetic and ontogenetic dimensions of the fascinating evolutionary phenomenon of heterochrony. Highlights: Heterochrony research focuses on comparative morphology but lags on mechanistic understanding.We propose integrating the different levels of study into a single analysis flow: from morphology to cells to molecules and genes, using modern techniques. [ABSTRACT FROM AUTHOR]

Published
2022
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19. Sequencing three crocodilian genomes to illuminate the evolution of archosaurs and amniotes

Author

St John, John A, primary, Braun, Edward L, additional, Isberg, Sally R, additional, Miles, Lee G, additional, Chong, Amanda Y, additional, Gongora, Jaime, additional, Dalzell, Pauline, additional, Moran, Christopher, additional, Bed'Hom, Bertrand, additional, Abzhanov, Arkhat, additional, Burgess, Shane C, additional, Cooksey, Amanda M, additional, Castoe, Todd A, additional, Crawford, Nicholas G, additional, Densmore, Llewellyn D, additional, Drew, Jennifer C, additional, Edwards, Scott V, additional, Faircloth, Brant C, additional, Fujita, Matthew K, additional, Greenwold, Matthew J, additional, Hoffmann, Federico G, additional, Howard, Jonathan M, additional, Iguchi, Taisen, additional, Janes, Daniel E, additional, Khan, Shahid Yar, additional, Kohno, Satomi, additional, de Koning, AP Jason, additional, Lance, Stacey L, additional, McCarthy, Fiona M, additional, McCormack, John E, additional, Merchant, Mark E, additional, Peterson, Daniel G, additional, Pollock, David D, additional, Pourmand, Nader, additional, Raney, Brian J, additional, Roessler, Kyria A, additional, Sanford, Jeremy R, additional, Sawyer, Roger H, additional, Schmidt, Carl J, additional, Triplett, Eric W, additional, Tuberville, Tracey D, additional, Venegas-Anaya, Miryam, additional, Howard, Jason T, additional, Jarvis, Erich D, additional, Guillette, Louis J, additional, Glenn, Travis C, additional, Green, Richard E, additional, and Ray, David A, additional

Published
2012
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23. The oestrogen pathway underlies the evolution of exaggerated male cranial shapes in Anolis lizards

Author

Sanger, T, Seav, S. M., Tokita, Masayoshi, Langerhans, R. B., Ross Berry, Lee Ann, Losos, Jonathan, and Abzhanov, Arkhat

Subjects
sexual dimorphism, evo-devo, morphometrics, facial length, oestrogen signalling
Abstract

Sexual dimorphisms vary widely among species. This variation must arise through sex-specific evolutionary modifications to developmental processes. Anolis lizards vary extensively in their expression of cranial dimorphism. Compared with other Anolis species, members of the carolinensis clade have evolved relatively high levels of cranial dimorphism; males of this clade have exceptionally long faces relative to conspecific females. Developmentally, this facial length dimorphism arises through an evolutionarily novel, clade-specific strategy. Our analyses herein reveal that sex-specific regulation of the oestrogen pathway underlies evolution of this exaggerated male phenotype, rather than the androgen or insulin growth factor pathways that have long been considered the primary regulators of male-biased dimorphism among vertebrates. Our results suggest greater intricacy in the genetic mechanisms that underlie sexual dimorphisms than previously appreciated., Organismic and Evolutionary Biology

Published
2014
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24. Convergent Evolution of Sexual Dimorphism in Skull Shape Using Distinct Developmental Strategies

Author

Sanger, Thomas, Sherratt, Emma, McGlothlin, Joel W., Brodie, Edmund D., Losos, Jonathan, and Abzhanov, Arkhat

Subjects
Allometry, Anolis, craniofacial, evo-devo, face length
Abstract

Studies integrating evolutionary and developmental analyses of morphological variation are of growing interest to biologists as they promise to shed fresh light on the mechanisms of morphological diversification. Sexually dimorphic traits tend to be incredibly divergent across taxa. Such diversification must arise through evolutionary modifications to sex differences during development. Nevertheless, few studies of dimorphism have attempted to synthesize evolutionary and developmental perspectives. Using geometric morphometric analysis of head shape for 50 Anolis species, we show that two clades have converged on extreme levels of sexual dimorphism through similar, male-specific changes in facial morphology. In both clades, males have evolved highly elongate faces whereas females retain faces of more moderate proportion. This convergence is accomplished using distinct developmental mechanisms; one clade evolved extreme dimorphism through the exaggeration of a widely shared, potentially ancestral, developmental strategy whereas the other clade evolved a novel developmental strategy not observed elsewhere in the genus. Together, our analyses indicate that both shared and derived features of development contribute to macroevolutionary patterns of morphological diversity among Anolis lizards., Organismic and Evolutionary Biology

Published
2013
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25. Insights into the evolution of Darwin’s finches from comparative analysis of the Geospiza magnirostris genome sequence

Author

Rands, Chris M, Darling, Aaron, Fujita, Matthew, Kong, Lesheng, Webster, Matthew T, Clabaut, Céline, Emes, Richard D, Heger, Andreas, Meader, Stephen, Hawkins, Michael Brent, Eisen, Michael B, Teiling, Clotilde, Affourtit, Jason, Boese, Benjamin, Grant, Peter R, Grant, Barbara Rosemary, Eisen, Jonathan A, Abzhanov, Arkhat, and Ponting, Chris P

Subjects
Genomics, Evolution, Darwin’s finches, Large ground finch
Abstract

Background: A classical example of repeated speciation coupled with ecological diversification is the evolution of 14 closely related species of Darwin’s (Galápagos) finches (Thraupidae, Passeriformes). Their adaptive radiation in the Galápagos archipelago took place in the last 2–3 million years and some of the molecular mechanisms that led to their diversification are now being elucidated. Here we report evolutionary analyses of genome of the large ground finch, Geospiza magnirostris. Results: 13,291 protein-coding genes were predicted from a 991.0 Mb G. magnirostris genome assembly. We then defined gene orthology relationships and constructed whole genome alignments between the G. magnirostris and other vertebrate genomes. We estimate that 15% of genomic sequence is functionally constrained between G. magnirostris and zebra finch. Genic evolutionary rate comparisons indicate that similar selective pressures acted along the G. magnirostris and zebra finch lineages suggesting that historical effective population size values have been similar in both lineages. 21 otherwise highly conserved genes were identified that each show evidence for positive selection on amino acid changes in the Darwin's finch lineage. Two of these genes (Igf2r and Pou1f1) have been implicated in beak morphology changes in Darwin’s finches. Five of 47 genes showing evidence of positive selection in early passerine evolution have cilia related functions, and may be examples of adaptively evolving reproductive proteins. Conclusions: These results provide insights into past evolutionary processes that have shaped G. magnirostris genes and its genome, and provide the necessary foundation upon which to build population genomics resources that will shed light on more contemporaneous adaptive and non-adaptive processes that have contributed to the evolution of the Darwin’s finches., Organismic and Evolutionary Biology

Published
2013
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26. Birds have paedomorphic dinosaur skulls

Author

Bhullar, Bhart-Anjan Singh, Marugán-Lobón, Jesús, Racimo, Fernando, Bever, Gabe S., Rowe, Timothy B., Norell, Mark A., and Abzhanov, Arkhat

Abstract

The interplay of evolution and development has been at the heart of evolutionary theory for more than a century. Heterochrony—change in the timing or rate of developmental events—has been implicated in the evolution of major vertebrate lineages such as mammals, including humans1. Birds are the most speciose land vertebrates, with more than 10,000 living species representing a bewildering array of ecologies. Their anatomy is radically different from that of other vertebrates. The unique bird skull houses two highly specialized systems: the sophisticated visual and neuromuscular coordination system allows flight coordination and exploitation of diverse visual landscapes, and the astonishing variations of the beak enable a wide range of avian lifestyles. Here we use a geometric morphometric approach integrating developmental, neontological and palaeontological data to show that the heterochronic process of paedomorphosis, by which descendants resemble the juveniles of their ancestors, is responsible for several major evolutionary transitions in the origin of birds. We analysed the variability of a series of landmarks on all known theropod dinosaur skull ontogenies as well as outgroups and birds. The first dimension of variability captured ontogeny, indicating a conserved ontogenetic trajectory. The second dimension accounted for phylogenetic change towards more bird-like dinosaurs. Basally branching eumaniraptorans and avialans clustered with embryos of other archosaurs, indicating paedomorphosis. Our results reveal at least four paedomorphic episodes in the history of birds combined with localized peramorphosis (development beyond the adult state of ancestors) in the beak. Paedomorphic enlargement of the eyes and associated brain regions parallels the enlargement of the nasal cavity and olfactory brain in mammals. This study can be a model for investigations of heterochrony in evolutionary transitions, illuminating the origin of adaptive features and inspiring studies of developmental mechanisms., Organismic and Evolutionary Biology

Published
2012
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27. Closely related bird species demonstrate flexibility between beak morphology and underlying developmental programs

Author

Mallarino, Ricardo, Campas, O., Fritz, Joerg, Burns, K. J., Weeks, Olivia Grace, Brenner, Michael P., and Abzhanov, Arkhat

Abstract

The astonishing variation in the shape and size of bird beaks reflects a wide range of dietary specializations that played an important role in avian diversification. Among Darwin's finches, ground finches (Geospiza spp.) have beaks that represent scaling variations of the same shape, which are generated by alterations in the signaling pathways that regulate growth of the two skeletal components of the beak: the prenasal cartilage (pnc) and the premaxillary bone (pmx). Whether this developmental mechanism is responsible for variation within groups of other closely related bird species, however, has remained unknown. Here, we report that the Caribbean bullfinches (Loxigilla spp.), which are closely related to Darwin's finches, have independently evolved beaks of a novel shape, different from Geospiza, but also varying from each other only in scaling. However, despite sharing the same beak shape, the signaling pathways and tissues patterning Loxigilla beaks differ among the three species. In Loxigilla noctis, as in Geospiza, the pnc develops first, shaped by Bmp4 and CaM signaling, followed by the development of the pmx, regulated by TGFβIIr, β-catenin, and Dkk3 signaling. In contrast, beak morphogenesis in Loxigilla violacea and Loxigilla portoricensis is generated almost exclusively by the pmx through a mechanism in which Ihh and Bmp4 synergize to promote expansion of bone tissue. Together, our results demonstrate high flexibility in the relationship between morphology and underlying developmental causes, where different developmental programs can generate identical shapes, and similar developmental programs can pattern different shapes., Organismic and Evolutionary Biology

Published
2012
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28. Paths Less Traveled: Evo-Devo Approaches to Investigating Animal Morphological Evolution

Author

Mallarino, Ricardo and Abzhanov, Arkhat

Abstract

One of the chief aims of modern biology is to understand the causes and mechanisms of morphological evolution. Multicellular animals display a stunning diversity of shapes and sizes of their bodies and individual suborganismal structures, much of it important to their survival. What is the most efficient way to study the evolution of morphological diversity? The old-new field of evolutionary developmental biology (evo-devo) can be particularly useful for understanding the origins of animal forms, as it aims to consolidate advances from disparate fields such as phylogenetics, genomics, morphometrics, cell biology, and developmental biology. We analyze the structure of some of the most successful recent evo-devo studies, which we see as having three distinct but highly interdependent components: (a) morphometrics, (b) identification of candidate mechanisms, and (c) functional experiments. Our case studies illustrate how multifarious evo-devo approaches taken within the three-winged evo-devo research program explain developmental mechanisms for morphological evolution across different phylogenetic scales., Organismic and Evolutionary Biology

Published
2012
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29. Sequencing Three Crocodilian Genomes to Illuminate the Evolution of Archosaurs and Amniotes

Author

St John, John A, Braun, Edward L, Isberg, Sally R, Miles, Lee G, Chong, Amanda Y, Gongora, Jaime, Dalzell, Pauline, Bed'Hom, Bertrand, Burgess, Shane C, Cooksey, Amanda M, Castoe, Todd A, Densmore, Llewellyn D, Drew, Jennifer C, Faircloth, Brant C, Greenwold, Matthew J, Hoffmann, Federico G, Howard, Jonathan M, Iguchi, Taisen, Janes, Daniel E, Khan, Shahid Yar, Kohno, Satomi, de Koning, AP Jason, Lance, Stacey L, McCarthy, Fiona M, McCormack, John E, Merchant, Mark E, Peterson, Daniel G, Pollock, David D, Pourmand, Nader, Raney, Brian J, Roessler, Kyria A, Sanford, Jeremy R, Sawyer, Roger H, Schmidt, Carl J, Triplett, Eric W, Tuberville, Tracey D, Venegas-Anaya, Miryam, Howard, Jason T, Jarvis, Erich D, Guillette, Louis J, Glenn, Travis C, Ray, David A, Moran, Christopher J, Abzhanov, Arkhat, Crawford, Nicholas G., Moran, Christopher, Edwards, Scott V., Fujita, Matthew, and Green, Richard E.

Subjects
genomics, evolution, Crocodylia, Archosauria, amniote
Abstract

The International Crocodilian Genomes Working Group (ICGWG) will sequence and assemble the American alligator (Alligator mississippiensis), saltwater crocodile (Crocodylus porosus) and Indian gharial (Gavialis gangeticus) genomes. The status of these projects and our planned analyses are described., Organismic and Evolutionary Biology

Published
2012
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30. Two developmental modules establish 3D beak-shape variation in Darwin's finches

Author

Mallarino, Ricardo, Grant, P. R., Grant, B. R., Herrel, Antony, Kuo, W. P., and Abzhanov, Arkhat

Subjects
craniofacial evolution, evolvability, variability, evolutionary developmental biology, natural variation
Abstract

Bird beaks display tremendous variation in shape and size, which is closely associated with the exploitation of multiple ecological niches and likely played a key role in the diversification of thousands of avian species. Previous studies have demonstrated some of the molecular mechanisms that regulate morphogenesis of the prenasal cartilage, which forms the initial beak skeleton. However, much of the beak diversity in birds depends on variation in the premaxillary bone. It forms later in development and becomes the most prominent functional and structural component of the adult upper beak/jaw, yet its regulation is unknown. Here, we studied a group of Darwin's finch species with different beak shapes. We found that TGFβIIr, β-catenin, and Dickkopf-3, the top candidate genes from a cDNA microarray screen, are differentially expressed in the developing premaxillary bone of embryos of species with different beak shapes. Furthermore, our functional experiments demonstrate that these molecules form a regulatory network governing the morphology of the premaxillary bone, which differs from the network controlling the prenasal cartilage, but has the same species-specific domains of expression. These results offer potential mechanisms that may explain how the tightly coupled depth and width dimensions can evolve independently. The two-module program of development involving independent regulating molecules offers unique insights into how different developmental pathways may be modified and combined to induce multidimensional shifts in beak morphology. Similar modularity in development may characterize complex traits in other organisms to a greater extent than is currently appreciated., Organismic and Evolutionary Biology

Published
2011
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31. Roles for modularity and constraint in the evolution of cranial diversity among anolis lizards

Author

Sanger, Thomas, Mahler, D. Luke, Losos, Jonathan, and Abzhanov, Arkhat

Subjects
Craniofacial, evo-devo, macroevolution, morphology, skull
Abstract

Complex organismal structures are organized into modules, suites of traits that develop, function, and vary in a coordinated fashion. By limiting or directing covariation among component traits, modules are expected to represent evolutionary building blocks and to play an important role in morphological diversification. But how stable are patterns of modularity over macroevolutionary timescales? Comparative analyses are needed to address the macroevolutionary effect of modularity, but to date few have been conducted. We describe patterns of skull diversity and modularity in Caribbean Anolis lizards. We first diagnose the primary axes of variation in skull shape and then examine whether diversification of skull shape is concentrated to changes within modules or whether changes arose across the structure as a whole. We find no support for the hypothesis that cranial modules are conserved as species diversify in overall skull shape. Instead we find that anole skull shape and modularity patterns independently converge. In anoles, skull modularity is evolutionarily labile and may reflect the functional demands of unique skull shapes. Our results suggest that constraints have played little role in limiting or directing the diversification of head shape in Anolis lizards., Organismic and Evolutionary Biology

Published
2011

32. Developing A Community-based Genetic Nomenclature for Anole Lizards

Author

Kusumi, Kenro, Kulathinal, Rob J., Abzhanov, Arkhat, Boissinot, Stephane, Crawford, Nicholas, Faircloth, Brant C., Glenn, Travis C., Janes, Daniel E., Losos, Jonathan, Menke, Douglas B., Poe, Steven, Sanger, Thomas, Schneider, Christopher, Stapley, Jessica, Wade, Juli, and Wilson-Rawls, Jeanne

Abstract

Background: Comparative studies of amniotes have been hindered by a dearth of reptilian molecular sequences. With the genomic assembly of the green anole, Anolis carolinensis available, non-avian reptilian genes can now be compared to mammalian, avian, and amphibian homologs. Furthermore, with more than 350 extant species in the genus Anolis, anoles are an unparalleled example of tetrapod genetic diversity and divergence. As an important ecological, genetic and now genomic reference, it is imperative to develop a standardized Anolis gene nomenclature alongside associated vocabularies and other useful metrics. Results: Here we report the formation of the Anolis Gene Nomenclature Committee (AGNC) and propose a standardized evolutionary characterization code that will help researchers to define gene orthology and paralogy with tetrapod homologs, provide a system for naming novel genes in Anolis and other reptiles, furnish abbreviations to facilitate comparative studies among the Anolis species and related iguanid squamates, and classify the geographical origins of Anolis subpopulations. Conclusions: This report has been generated in close consultation with members of the Anolis and genomic research communities, and using public database resources including NCBI and Ensembl. Updates will continue to be regularly posted to new research community websites such as lizardbase. We anticipate that this standardized gene nomenclature will facilitate the accessibility of reptilian sequences for comparative studies among tetrapods and will further serve as a template for other communities in their sequencing and annotation initiatives., Organismic and Evolutionary Biology, Other Research Unit

Published
2011
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33. Scaling and shear transformations capture beak shape variation in Darwin's finches

Author

Campas, O., Mallarino, Ricardo, Herrel, A, Abzhanov, Arkhat, and Brenner, M

Subjects
Bmp4, craniofacial evolution and development, Geospiza, morphogenesis, morphological hierarchy
Abstract

Evolution by natural selection has resulted in a remarkable diversity of organism morphologies that has long fascinated scientists and served to establish the first relations among species. Despite the essential role of morphology as a phenotype of species, there is not yet a formal, mathematical scheme to quantify morphological phenotype and relate it to both the genotype and the underlying developmental genetics. Herein we demonstrate that the morphological diversity in the beaks of Darwin’s Finches is quantitatively accounted for by the mathematical group of affine transformations. Specifically, we show that all beak shapes of Ground Finches (genus Geospiza) are related by scaling transformations (a subgroup of the affine group), and the same relationship holds true for all the beak shapes of Tree, Cocos, and Warbler Finches (three distinct genera). This analysis shows that the beak shapes within each of these groups differ only by their scales, such as length and depth, which are genetically controlled by Bmp4 and Calmodulin. By measuring Bmp4 expression in the beak primordia of the species in the genus Geospiza, we provide a quantitative map between beak morphology and the expression levels of Bmp4. The complete morphological variation within the beaks of Darwin’s finches can be explained by extending the scaling transformations to the entire affine group, by including shear transformations. Altogether our results suggest that the mathematical theory of groups can help decode morphological variation, and points to a potentially hierarchical structure of morphological diversity and the underlying developmental processes., Organismic and Evolutionary Biology

Published
2010
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34. Are we there yet? Tracking the Development of New Model Systems

Author

Hoekstra, Hopi, Kramer, Elena, Monteiro, Antonia, Hodges, Scott A., Groover, Andrew, Abzhanov, Arkhat, and Extavour, Cassandra

Abstract

It is increasingly clear that additional "model" systems are needed to elucidate the genetic and developmental basis of organismal diversity. Whereas model system development previously required enormous investment, recent advances including the decreasing cost of DNA sequencing and the power of reverse genetics to study gene function are greatly facilitating the process. In this review, we consider two aspects of the development of new genetic model systems: first, the types of questions being advanced using these new models; and second, the essential characteristics and molecular tools for new models, depending on the research focus. We hope that researchers will be inspired to explore this array of emerging models and even consider developing new molecular tools for their own favorite organism., Organismic and Evolutionary Biology

Published
2008
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35. Peripheral Arterial Occlusive Disease: Global Gene Expression Analyses Suggest a Major Role for Immune and Inflammatory Responses

Author

Crawford, Keith, Jin, Jason Gang, Du, Yanzhi, Abzhanov, Arkhat, Zhou, Jianqin, Zhang, Ji, Jiang, Mier, Ohno-Machado, Lucila, Fu, Shijun, Zhao, Haiguang, Shi, Jiantao, and Kuo, Winston

Abstract

Background Peripheral arterial disease (PAD), a major manifestation of atherosclerosis, is associated with significant cardiovascular morbidity, limb loss and death. However, mechanisms underlying the genesis and progression of the disease are far from clear. Genome-wide gene expression profiling of clinical samples may represent an effective approach to gain relevant information. Results After histological classification, a total of 30 femoral artery samples, including 11 intermediate lesions, 14 advanced lesions and 5 normal femoral arteries, were profiled using Affymetrix microarray platform. Following real-time RT-PCR validation, different algorithms of gene selection and clustering were applied to identify differentially expressed genes. Under a stringent cutoff, i.e., a false discovery rate (FDR) <0.5%, we found 366 genes were differentially regulated in intermediate lesions and 447 in advanced lesions. Of these, 116 genes were overlapped between intermediate and advanced lesions, including 68 up-regulated genes and 48 down-regulated ones. In these differentially regulated genes, immune/inflammatory genes were significantly up-regulated in different stages of PAD, (85/230 in intermediate lesions, 37/172 in advanced lesions). Through literature mining and pathway analysis using different databases such as Gene Ontology (GO), and the Kyoto Encyclopedia of Gene and Genomics (KEGG), genes involved in immune/inflammatory responses were significantly enriched in up-regulated genes at different stages of PAD(p < 0.05), revealing a significant correlation between immune/inflammatory responses and disease progression. Moreover, immune-related pathways such as Toll-like receptor signaling and natural killer cell mediated cytotoxicity were particularly enriched in intermediate and advanced lesions (P < 0.05), highlighting their pathogenic significance during disease progression. Conclusion Lines of evidence revealed in this study not only support previous hypotheses, primarily based on studies of animal models and other types of arterial disease, that inflammatory responses may influence the development of PAD, but also permit the recognition of a wide spectrum of immune/inflammatory genes that can serve as signatures for disease progression in PAD. Further studies of these signature molecules may eventually allow us to develop more sophisticated protocols for pharmaceutical interventions., Organismic and Evolutionary Biology

Published
2008
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36. Regulation of skeletogenic differentiation in cranial dermal bone

Author

Abzhanov, Arkhat, Rodda, S. J., McMahon, A. P., and Tabin, Clifford James

Subjects
Dermal bone, intramembranous ossification, cranial development, mouse, chick
Abstract

Although endochondral ossification of the limb and axial skeleton is relatively well-understood, the development of dermal (intramembranous) bone featured by many craniofacial skeletal elements is not nearly as well-characterized. We analyzed the expression domains of a number of markers that have previously been associated with endochondral skeleton development to define the cellular transitions involved in the dermal ossification process in both chick and mouse. This led to the recognition of a series of distinct steps in the dermal differentiation pathways, including a unique cell type characterized by the expression of both osteogenic and chondrogenic markers. Several signaling molecules previously implicated in endochondrial development were found to be expressed during specific stages of dermal bone formation. Three of these were studied functionally using retroviral misexpression. We found that activity of bone morphogenic proteins (BMPs) is required for neural crest-derived mesenchyme to commit to the osteogenic pathway and that both Indian hedgehog (IHH) and parathyroid hormone-related protein (PTHrP, PTHLH) negatively regulate the transition from preosteoblastic progenitors to osteoblasts. These results provide a framework for understanding dermal bone development with an aim of bringing it closer to the molecular and cellular resolution available for the endochondral bone development., Organismic and Evolutionary Biology

Published
2007
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37. Antagonists of Wnt and BMP signaling promote the formation of vertebrate head muscle

Author

Tzahor, Eldad, Kempf, Hervé, Mootoosamy, Roy C., Poon, Andy C., Abzhanov, Arkhat, Tabin, Clifford James, Dietrich, Susanne, and Lassar, Andrew B.

Subjects
Skeletal myogenesis, cranial neural crest, head mesoderm, Wnt, BMP, Noggin, Gremlin, Frzb
Abstract

Recent studies have postulated that distinct regulatory cascades control myogenic differentiation in the head and the trunk. However, although the tissues and signaling molecules that induce skeletal myogenesis in the trunk have been identified, the source of the signals that trigger skeletal muscle formation in the head remain obscure. Here we show that although myogenesis in the trunk paraxial mesoderm is induced by Wnt signals from the dorsal neural tube, myogenesis in the cranial paraxial mesoderm is blocked by these same signals. In addition, BMP family members that are expressed in both the dorsal neural tube and surface ectoderm are also potent inhibitors of myogenesis in the cranial paraxial mesoderm. We provide evidence suggesting that skeletal myogenesis in the head is induced by the BMP inhibitors, Noggin and Gremlin, and the Wnt inhibitor, Frzb. These molecules are secreted by both cranial neural crest cells and by other tissues surrounding the cranial muscle anlagen. Our findings demonstrate that head muscle formation is locally repressed by Wnt and BMP signals and induced by antagonists of these signaling pathways secreted by adjacent tissues., Organismic and Evolutionary Biology

Published
2003
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38. Novel regulation of the homeotic gene Scr associated with a crustacean leg-to-maxilliped appendage transformation.

Author

Abzhanov, Arkhat and Kaufman, Thomas C.

Subjects
Homeotic gene, Sex combs reduced, Porcellio scaber, Isopoda, Crustacean, Maxilliped, Evolution
Abstract

Homeotic genes are known to be involved in patterning morphological structures along the antero-posterior axis of insects and vertebrates. Because of their important roles in development, changes in the function and expression patterns of homeotic genes may have played a major role in the evolution of different body plans. For example, it has been proposed that during the evolution of several crustacean lineages, changes in the expression patterns of the homeotic genes Ultrabithorax and abdominal-A have played a role in transformation of the anterior thoracic appendages into mouthparts termed maxillipeds. This homeotic-like transformation is recapitulated at the late stages of the direct embryonic development of the crustacean Porcellio scaber (Oniscidea, Isopoda). Interestingly, this morphological change is associated with apparent novelties both in the transcriptional and post-transcriptional regulation of the Porcellio scaber ortholog of the Drosophila homeotic gene, Sex combs reduced (Scr). Specifically, we find that Scr mRNA is present in the second maxillary segment and the first pair of thoracic legs (T1) in early embryos, whereas protein accumulates only in the second maxillae. In later stages, however, high levels of SCR appear in the T1 legs, which correlates temporally with the transformation of these appendages into maxillipeds. Our observations provide further insight into the process of the homeotic leg-to-maxilliped transformation in the evolution of crustaceans and suggest a novel regulatory mechanism for this process in this group of arthropods., Organismic and Evolutionary Biology

Published
1999

39. The evolution of form and function across taxonomic scales of passerines

Author

Reaney, Ashley and Abzhanov, Arkhat

Abstract

Adaptive radiations, the process by which organisms diversify both taxonomically and ecologically, have been attributed to underline the majority of living biodiversity. This type of evolutionary radiation typically transpires following the exploitation of vacant niche space though is not restricted to insular communities as numerous large clades likely diversified in much the same way. There is considerable variation in morphological and ecological diversity both within and between clades at all taxonomic scales. Several near-complete phylogenetic trees and datasets were used to investigate clade disparity in abstract space, trait evolution and the associations between morphology, ecology and diversification rates. These were combined to assess whether imbalances in speciation rates occur among taxa possessing particularly extreme morphologies in beak and body traits. New approaches capturing disparity metrics were used to quantitively analyse the hypervolumes of diverse families and smaller subclades within multidimensional space. These metrics were then employed to assess whether passerine families possess greater disparity in either their beak or body morphospaces. Thraupidae are an incredibly diverse passerine family with its various subclades exhibiting contrasting levels of taxonomic and morphological diversity. Analysis of these two evolutionary aspects revealed speciation rates are often decoupled from trait disparity among the various tanager subclades. Finally, the extreme disparity in form among the nested adaptive radiations within Thraupidae and other passerine families were explored to assess their contrasting trajectories with other endemic taxa to understand how such discrepancy in diversity was achieved and the factors that likely generated it.

Published
2021
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40. The Evolution of form and function across taxonomic scales of passerines

Author

Reaney, Ashley, Abzhanov, Arkhat, Engineering and Physical Sciences Research Council, and Natural Environment Research Council (Great Britain)

Abstract

Adaptive radiations, the process by which organisms diversify both taxonomically and ecologically, have been attributed to underline the majority of living biodiversity. This type of evolutionary radiation typically transpires following the exploitation of vacant niche space though is not restricted to insular communities as numerous large clades likely diversified in much the same way. There is considerable variation in morphological and ecological diversity both within and between clades at all taxonomic scales. Several near-complete phylogenetic trees and datasets were used to investigate clade disparity in abstract space, trait evolution and the associations between morphology, ecology and diversification rates. These were combined to assess whether imbalances in speciation rates occur among taxa possessing particularly extreme morphologies in beak and body traits. New approaches capturing disparity metrics were used to quantitively analyse the hypervolumes of diverse families and smaller subclades within multidimensional space. These metrics were then employed to assess whether passerine families possess greater disparity in either their beak or body morphospaces. Thraupidae are an incredibly diverse passerine family with its various subclades exhibiting contrasting levels of taxonomic and morphological diversity. Analysis of these two evolutionary aspects revealed speciation rates are often decoupled from trait disparity among the various tanager subclades. Finally, the extreme disparity in form among the nested adaptive radiations within Thraupidae and other passerine families were explored to assess their contrasting trajectories with other endemic taxa to understand how such discrepancy in diversity was achieved and the factors that likely generated it. Open Access

Published
2020
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41. Role of the Extreme Anterior Domain Organizer in Craniofacial Development

Author

Jacox, Laura Anne and Abzhanov, Arkhat

Subjects
Biology, Cell, Molecular, Health Sciences, Dentistry
Abstract

Craniofacial development is an intricate process, involving cranial neural crest (NC) and anterior facial tissue. NC migration is regulated by multiple mechanisms and activity of one or more organizer regions. Work presented here explores the role of the EAD, an organizer of craniofacial development in Xenopus, and its reciprocal signaling with cranial NC. The EAD later contributes to the mouth, nostrils, and anterior pituitary. EAD function involves the Kinin-Kallikrein pathway that was shown for the first time to be necessary for mouth formation. Facial transplants demonstrate that EAD-localized Kinin-Kallikrein function is required for migration of first arch cranial NC into the face. After migration, cranial NC signals back to the EAD to regulate mouth opening via the Wnt/PCP pathway. This pathway is associated with a process consistent with convergent extension of the EAD, whereby a wide and short epithelial mass narrows and lengthens, and cells and nuclei undergo stereotypical changes. The resultant EAD is a bilayered epithelium that later splits to form the mouth opening. Identification of the EAD as a NC organizer, reciprocal interaction of EAD and NC, and convergent extension associated with mouth formation has not previously been described during craniofacial development. Face formation is widely conserved, so findings in frog are likely relevant to amniotes and will provide insight into causes of craniofacial deformities., Biological Sciences in Dental Medicine

Published
2015

42. The evolution and development of the archosaurian head and the origin of the bird skull

Author

Bhullar, Bhart-Anjan Singh and Abzhanov, Arkhat

Subjects
Evolution & development, Paleontology, Biology, Archosauria, Beak, Craniofacial, Cranium, Crocodylia, Heterochrony
Abstract

Archosauria, the "ruling reptiles," characterized along their stem by relatively large, macrocarnivorous animals, are today represented by two enormously successful but divergent extant clades: Aves, the birds, and Crocodylia, the crocodiles and alligators. This thesis seeks to characterize major transformations in the cranial region of archosaurs, a prominent theme in their evolution.

Published
2014

43. The topological organization of the turtle cranium is constrained and conserved over long evolutionary timescales.

Author

Miller E, Lee HW, Abzhanov A, and Evers SW

Subjects
Animals, Phylogeny, Fossils anatomy & histology, Turtles anatomy & histology, Skull anatomy & histology, Biological Evolution
Abstract

The cranium of turtles (Testudines) is characterized by the secondary reduction of temporal fenestrae and loss of cranial joints (i.e., characteristics of anapsid, akinetic skulls). Evolution and ontogeny of the turtle cranium are associated with shape changes. Cranial shape variation among Testudines can partially be explained by dietary and functional adaptations (neck retraction), but it is unclear if cranial topology shows similar ecomorphological signal, or if it is decoupled from shape evolution. We assess the topological arrangement of cranial bones (i.e., number, relative positioning, connections), using anatomical network analysis. Non-shelled stem turtles have similar cranial arrangements to archosauromorph outgroups. Shelled turtles (Testudinata) evolve a unique cranial organization that is associated with bone losses (e.g., supratemporal, lacrimal, ectopterygoid) and an increase in complexity (i.e., densely and highly interconnected skulls with low path lengths between bones), resulting from the closure of skull openings and establishment of unusual connections such as a parietal-pterygoid contact in the secondary braincase. Topological changes evolutionarily predate many shape changes. Topological variation and taxonomic morphospace discrimination among crown turtles are low, indicating that cranial topology may be constrained. Observed variation results from repeated losses of nonintegral bones (i.e., premaxilla, nasal, epipterygoid, quadratojugal), and changes in temporal emarginations and palate construction. We observe only minor ontogenetic changes. Topology is not influenced by diet and habitat, contrasting cranial shape. Our results indicate that turtles have a unique cranial topology among reptiles that is conserved after its initial establishment, and shows that cranial topology and shape have different evolutionary histories., (© 2023 The Authors. The Anatomical Record published by Wiley Periodicals LLC on behalf of American Association for Anatomy.)

Published
2024
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44. The role of cranial osteoderms on the mechanics of the skull in scincid lizards.

Author

Marghoub A, Kéver L, Williams CJA, Abzhanov A, Vickaryous M, Herrel A, Evans SE, and Moazen M

Subjects
Animals, Bite Force, Skull anatomy & histology, Head, Biomechanical Phenomena, Lizards anatomy & histology
Abstract

Osteoderms (ODs) are calcified organs formed directly within the skin of most major extant tetrapod lineages. Lizards possibly show the greatest diversity in ODs morphology and distribution. ODs are commonly hypothesized to function as a defensive armor. Here we tested the hypothesis that cranial osteoderms also contribute to the mechanics of the skull during biting. A series of in vivo experiments were carried out on three specimens of Tiliqua gigas. Animals were induced to bite a force plate while a single cranial OD was strain gauged. A finite element (FE) model of a related species, Tiliqua scincoides, was developed and used to estimate the level of strain across the same OD as instrumented in the in vivo experiments. FE results were compared to the in vivo data and the FE model was modified to test two hypothetical scenarios in which all ODs were (i) removed from, and (ii) fused to, the skull. In vivo data demonstrated that the ODs were carrying load during biting. The hypothetical FE models showed that when cranial ODs were fused to the skull, the overall strain across the skull arising from biting was reduced. Removing the ODs showed an opposite effect. In summary, our findings suggest that cranial ODs contribute to the mechanics of the skull, even when they are loosely attached., (© 2023 The Authors. The Anatomical Record published by Wiley Periodicals LLC on behalf of American Association for Anatomy.)

Published
2023
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