41 results on '"Organ, Chris"'
Search Results
2. The relationship between genome size and metabolic rate in extant vertebrates
- Author
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Gardner, Jacob D., Laurin, Michel, and Organ, Chris L.
- Published
- 2020
3. The evolution and ecology of gigantism in terror birds (Aves, Phorusrhacidae).
- Author
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LaBarge, Thomas W., Gardner, Jacob D., and Organ, Chris L.
- Subjects
ECOLOGICAL succession ,TOP predators ,BODY size ,BAYESIAN field theory ,ERECTOR spinae muscles - Abstract
Terror birds (Aves, Phorusrhacidae) were large flightless apex predators in South America during the Cenozoic. Here, we estimate a new phylogeny for phorusrhacids using Bayesian inference. We demonstrate phylogenetic evidence for a monophyletic Patagornithinae and find significant support for a distinct crown group associated with the quintessential 'terror bird' characteristics. We use this phylogeny to analyse the evolution of body size and cursoriality. Our results reveal that size overlap was rare between co-occurring subfamilies, supporting the hypothesis that these traits were important for niche partitioning. We observe that gigantism evolved in a single clade, containing Phorusrhacinae and Physornithinae. The members of this lineage were consistently larger than all other phorusrhacids. Phorusrhacinae emerged following the extinction of Physornithinae, suggesting the ecological succession of the apex predator niche. The first known phorusrhacine, Phorusrhacos longissimus, was gigantic but significantly smaller and more cursorial than any physornithine. These traits likely evolved in response to the expansion of open environments. Following the Santacrucian SALMA, phorusrhacines increased in size, further converging on the morphology of Physornithinae. These findings suggest that the evolution and displacement of body size drove terror bird niche partitioning and competitive exclusion controlled phorusrhacid diversity. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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4. Biomechanics of Ossified Tendons in Ornithopod Dinosaurs
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Organ, Chris L.
- Published
- 2006
5. A Non-Invasive Quarry Mapping System
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Organ, Chris L., Cooley, Joseph B., and Hieronymus, Tobin L.
- Published
- 2003
6. The coevolution of rostral keratin and tooth distribution in dinosaurs.
- Author
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Aguilar-Pedrayes, Isaura, Gardner, Jacob D., and Organ, Chris L.
- Subjects
KERATIN ,DINOSAURS ,DENTITION ,COEVOLUTION ,SURFACE texture - Abstract
Teeth evolved early in vertebrate evolution, and their morphology reflects important specializations in diet and ecology among species. The toothless jaws (edentulism) in extant birds likely coevolved with beak keratin, which functionally replaced teeth. However, extinct dinosaurs lost teeth multiple times independently and exhibited great variation in toothrow distribution and rhamphotheca-like keratin structures. Here, we use rostral jawbone surface texture as a proxy for rostral keratin covering and phylogenetic comparative models to test for the influence of rostral keratin on toothrow distribution in Mesozoic dinosaurs. We find that the evolution of rostral keratin covering explains partial toothrow reduction but not jaw toothlessness. Toothrow reduction preceded the evolution of rostral keratin cover in theropods. Non-theropod dinosaurs evolved continuous toothrows despite evolving rostral keratin covers (e.g. some ornithischians and sauropodomorphs). We also show that rostral keratin covers did not significantly increase the evolutionary rate of tooth loss, which further delineates the antagonistic relationship between these structures. Our results suggest that the evolution of rostral keratin had a limited effect on suppressing tooth development. Independent changes in jaw development may have facilitated further tooth loss. Furthermore, the evolution of strong chemical digestion, a gizzard, and a dietary shift to omnivory or herbivory likely alleviated selective pressures for tooth development. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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7. Osteology and Phylogenetic Relationships of the Mid-Cretaceous Neornithischian Dinosaur Oryctodromeus cubicularis Varricchio, 2007.
- Author
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Krumenacker, L. J., Varricchio, David J., Organ, Chris, Gardner, Jacob D., Britt, Brooks B., and Boyd, Clint
- Abstract
The vertebrate assemblages of the Albian to Cenomanian Wayan Formation of southeastern Idaho and southwestern Montana's coeval Vaughn Member of the Blackleaf Formation are dominated by the small, burrowing orodromine dinosaur Oryctodromeus cubicularis. Here, we describe in detail the osteology of Oryctodromeus based on new specimens from Idaho and Montana that add substantially to the preliminary description of the types from Montana, and provide a suite of additional diagnostic characters for the taxon: ilium with elongate preacetabular process; elongate cervical vertebra centra with an anteroposterior length 1.6 times the dorsoventral height; elongate dorsal vertebra centra with an anteroposterior length 1.4 times the dorsoventral height; more than 55 elongate caudal vertebrae enveloped in hypaxial and epaxial ossified tendons; and a femoral head on an elongate neck—similar to that of Koreanosaurus—projecting from the greater trochanter at about 35°. The tail, comprising two-thirds of the animal's roughly 3 meters length, and associated tendon sheaths in the axial column indicate greater flexibility than previously supposed for ossified tendons or, alternatively, suggest that the Oryctodromeus burrows had separate, or multiple entrances and exits. The elongated and angled femoral head likely facilitated digging via a braced splayed-leg posture. Our phylogenetic analysis incorporates new characteristics and supports the monophyly of Orodrominae, a clade of neornithischian dinosaurs from the middle to Late Cretaceous of Asia and western North America that utilized burrowing. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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8. Detecting punctuated evolution in SARS-CoV-2 over the first year of the pandemic.
- Author
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Surya, Kevin, Gardner, Jacob D., and Organ, Chris L.
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SARS-CoV-2 ,COVID-19 - Abstract
The Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) evolved slowly over the first year of the Coronavirus Disease 19 (COVID-19) pandemic with differential mutation rates across lineages. Here, we explore how this variation arose. Whether evolutionary change accumulated gradually within lineages or during viral lineage branching is unclear. Using phylogenetic regression models, we show that ~13% of SARS-CoV-2 genomic divergence up to May 2020 is attributable to lineage branching events (punctuated evolution). The net number of branching events along lineages predicts ~5% of the deviation from the strict molecular clock. We did not detect punctuated evolution in SARS-CoV-1, possibly due to the small sample size, and in sarbecovirus broadly, likely due to a different evolutionary process altogether. Punctuation in SARS-CoV-2 is probably neutral because most mutations were not positively selected and because the strength of the punctuational effect remained constant over time, at least until May 2020, and across continents. However, the small punctuational contribution to SARS-CoV-2 diversity is consistent with the founder effect arising from narrow transmission bottlenecks. Therefore, punctuation in SARS-CoV-2 may represent the macroevolutionary consequence (rate variation) of a microevolutionary process (transmission bottleneck). [ABSTRACT FROM AUTHOR]
- Published
- 2023
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9. Phylogenetic rate shifts in feeding time during the evolution of Homo
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Organ, Chris, Nunn, Charles L., Machanda, Zarin, and Wrangham, Richard W.
- Published
- 2011
10. Biogeography across the ages
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Organ, Chris
- Published
- 2018
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11. Three Tiers of Genome Evolution in Reptiles
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Organ, Chris L., Moreno, Ricardo Godínez, and Edwards, Scott V.
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- 2008
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12. Genotypic sex determination enabled adaptive radiations of extinct marine reptiles
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Organ, Chris L., Janes, Daniel E., Meade, Andrew, and Pagel, Mark
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Origin of species -- Methods -- Research -- Genetic aspects ,Extinct animals -- Genetic aspects -- Methods -- Research ,Sex determination, Genetic -- Research -- Methods -- Genetic aspects ,Environmental issues ,Science and technology ,Zoology and wildlife conservation ,Research ,Genetic aspects ,Methods - Abstract
Adaptive radiations often follow the evolution of key traits, such as the origin of the amniotic egg and the subsequent radiation of terrestrial vertebrates. The mechanism by which a species determines the sex of its offspring has been linked to critical ecological and life-history traits (103) but not to major adaptive radiations, in part because sex-determining mechanisms do not fossilize. Here we establish a previously unknown coevolutionary relationship in 94 amniote species between sex-determining mechanism and whether a species bears live young or lays eggs. We use that relationship to predict the sex-determining mechanism in three independent lineages of extinct Mesozoic marine reptiles (mosasaurs, sauropterygians and ichthyosaurs), each of which is known from fossils to have evolved live birth (4-7). Our results indicate that each lineage evolved genotypic sex determination before acquiring live birth. This enabled their pelagic radiations, where the relatively stable temperatures of the open ocean constrain temperature-dependent sex determination in amniote species. Freed from the need to move and nest on land (4,5,8), extreme physical adaptations to a pelagic lifestyle evolved in each group, such as the flaked tails, dorsal fms and wing-shaped limbs of ichthyosaurs. With the inclusion of ichthyosaurs, mosasaurs and sauropterygians, genotypic sex determination is present in all known fully pelagic amniote groups (sea snakes, sirenians and cetaceans), suggesting that this mode of sex determination and the subsequent evolution of live birth are key traits required for marine adaptive radiations in amniote lineages., Sea snakes, which comprise more than 60 species, are the only living obligate seagoing reptiles and they rely on sex chromosomes (a genotypic mechanism) to determine the sex of their [...]
- Published
- 2009
13. Biomolecular characterization and protein sequences of the Campanian hadrosaur B. Canadensis
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Schweitzer, Mary H., Zheng, Wenxia, Organ, Chris L., Avci, Recep, Suo, Zhiyong, Freimark, Lisa M., Lebleu, Valerie S., Duncan, Michael B., Heiden, Matthew G. Vander, Neveu, John M., Lane, William S., Cottrell, John S., Horner, John R., Cantley, Lewis C., Kalluri, Raghu, and Asara, John M.
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Hadrosaurids -- Physiological aspects ,Science and technology - Abstract
Molecular preservation in non-avian dinosaurs is controversial. We present multiple lines of evidence that endogenous proteinaceous material is preserved in bone fragments and soft tissues from an 80-million-year-old Campanian hadrosaur, Brachylophosaurus canadensis [Museum of the Rockies (MOR) 2598]. Microstructural and immunological data are consistent with preservation of multiple bone matrix and vessel proteins, and phylogenetic analyses of Brochylophosourus collagen sequenced by mass spectrometry robustly support the bird-dinosaur clade, consistent with an endogenous source for these collagen peptides. These data complement earlier results from Tyrannosaurus rex (MOR 1125) and confirm that molecular preservation in Cretaceous dinosaurs is not a unique event.
- Published
- 2009
14. Origin of avian genome size and structure in non-avian dinosaurs
- Author
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Organ, Chris L., Shedlock, Andrew M., Meade, Andrew, Pagel, Mark, and Edwards, Scott V.
- Subjects
Environmental issues ,Science and technology ,Zoology and wildlife conservation - Abstract
Author(s): Chris L. Organ (corresponding author) [1]; Andrew M. Shedlock [1]; Andrew Meade [2]; Mark Pagel [2]; Scott V. Edwards [1] Avian genomes are small and streamlined compared with those [...]
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- 2007
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15. The African coelacanth genome provides insights into tetrapod evolution
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Amemiya, Chris T., Alföldi, Jessica J, Lee, Alison P., Fan, Shaohua S, Philippe, Hervé H, MacCallum, Iain I, Braasch, Ingo I, Manousaki, Tereza T, Schneider, Igor I, Rohner, Nicolas N, Organ, Chris C, Chalopin, Domitille D, Smith, Jeramiah J., Robinson, Mark M, Dorrington, Rosemary A., Gerdol, Marco M, Aken, Bronwen B, Biscotti, Maria Assunta, Barucca, Marco M, Baurain, Denis D, Berlin, Aaron M., Blatch, Gregory L., Buonocore, Francesco F, Burmester, Thorsten T, Campbell, Michael S., Canapa, Adriana A, Cannon, John P., Christoffels, Alan A, De Moro, Gianluca G, Edkins, Adrienne L., Fan, Lin L, Fausto, Anna Maria, Feiner, Nathalie N, Forconi, Mariko M, Gamieldien, Junaid J, Gnerre, Sante S, Gnirke, Andreas A, Goldstone, Jared V., Haerty, Wilfried W, Hahn, Mark E., Hesse, Uljana U, Hoffmann, Steve S, Johnson, Jeremy J, Karchner, Sibel I., Kuraku, Shigehiro S, Lara, Marcia M, Levin, Joshua Z., Litman, Gary W., Mauceli, Evan E, Miyake, Tsutomu T, Mueller, Gail M., Nelson, David R., Nitsche, Anne A, Olmo, Ettore E, Ota, Tatsuya T, Pallavicini, Alberto A, Panji, Sumir S, Picone, Barbara B, Ponting, Chris P., Prohaska, Sonja J., Przybylski, Dariusz D, Saha, Nil Ratan, Ravi, Vydianathan V, Ribeiro, Filipe J., Sauka-Spengler, Tatjana T, Scapigliati, Giuseppe G, Searle, Stephen M. J., Sharpe, Ted T, Simakov, Oleg O, Stadler, Peter F., Stegeman, John J., Sumiyama, Kenta K, Tabbaa, Diana D, Tafer, Hakim H, Turner-Maier, Jason J, van Heusden, Peter P, White, Simon S, Williams, Louise L, Yandell, Mark M, Brinkmann, Henner H, Volff, Jean-Nicolas J, Tabin, Clifford J., Shubin, Neil N, Schartl, Manfred M, Jaffe, David B., Postlethwait, John H., Venkatesh, Byrappa B, Di Palma, Federica F, Lander, Eric S., Meyer, Axel A, and Lindblad-Toh, Kerstin K
- Published
- 2013
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16. The genome of the green anole lizard and a comparative analysis with birds and mammals
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Alföldi, Jessica, Di Palma, Federica, Grabherr, Manfred, Williams, Christina, Kong, Lesheng, Mauceli, Evan, Russell, Pamela, Lowe, Craig B., Glor, Richard E., Jaffe, Jacob D., Ray, David A., Boissinot, Stephane, Shedlock, Andrew M., Botka, Christopher, Castoe, Todd A., Colbourne, John K., Fujita, Matthew K., Moreno, Ricardo Godinez, ten Hallers, Boudewijn F., Haussler, David, Heger, Andreas, Heiman, David, Janes, Daniel E., Johnson, Jeremy, de Jong, Pieter J., Koriabine, Maxim Y., Lara, Marcia, Novick, Peter A., Organ, Chris L., Peach, Sally E., Poe, Steven, Pollock, David D., de Queiroz, Kevin, Sanger, Thomas, Searle, Steve, Smith, Jeremy D., Smith, Zachary, Swofford, Ross, Turner-Maier, Jason, Wade, Juli, Young, Sarah, Zadissa, Amonida, Edwards, Scott V., Glenn, Travis C., Schneider, Christopher J., Losos, Jonathan B., Lander, Eric S., Breen, Matthew, Ponting, Chris P., and Lindblad-Toh, Kerstin
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- 2011
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17. Molecular Phylogenetics of Mastodon and Tyrannosaurus rex
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Organ, Chris L., Schweitzer, Mary H., Zheng, Wenxia, Freimark, Lisa M., Cantley, Lewis C., and Asara, John M.
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- 2008
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18. Evolutionary Sample Size and Consilience in Phylogenetic Comparative Analysis.
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Gardner, Jacob D and Organ, Chris L
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SAMPLE size (Statistics) , *DATA distribution , *COMPARATIVE studies , *MAMMARY glands , *PARAMETER estimation - Abstract
Phylogenetic comparative methods (PCMs) are commonly used to study evolution and adaptation. However, frequently used PCMs for discrete traits mishandle single evolutionary transitions. They erroneously detect correlated evolution in these situations. For example, hair and mammary glands cannot be said to have evolved in a correlated fashion because each evolved only once in mammals, but a commonly used model (Pagel's Discrete) statistically supports correlated (dependent) evolution. Using simulations, we find that rate parameter estimation, which is central for model selection, is poor in these scenarios due to small effective (evolutionary) sample sizes of independent character state change. Pagel's Discrete model also tends to favor dependent evolution in these scenarios, in part, because it forces evolution through state combinations unobserved in the tip data. This model prohibits simultaneous dual transitions along branches. Models with underlying continuous data distributions (e.g. Threshold and GLMM) are less prone to favor correlated evolution but are still susceptible when evolutionary sample sizes are small. We provide three general recommendations for researchers who encounter these common situations: i) create study designs that evaluate a priori hypotheses and maximize evolutionary sample sizes; ii) assess the suitability of evolutionary models—for discrete traits, we introduce the phylogenetic imbalance ratio; and iii) evaluate evolutionary hypotheses with a consilience of evidence from disparate fields, like biogeography and developmental biology. Consilience plays a central role in hypothesis testing within the historical sciences where experiments are difficult or impossible to conduct, such as many hypotheses about correlated evolution. These recommendations are useful for investigations that employ any type of PCM. [Class imbalance; consilience; correlated evolution; evolutionary sample size; phylogenetic comparative methods.] [ABSTRACT FROM AUTHOR]
- Published
- 2021
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19. The tuatara genome reveals ancient features of amniote evolution.
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Gemmell, Neil J., Rutherford, Kim, Prost, Stefan, Tollis, Marc, Winter, David, Macey, J. Robert, Adelson, David L., Suh, Alexander, Bertozzi, Terry, Grau, José H., Organ, Chris, Gardner, Paul P., Muffato, Matthieu, Patricio, Mateus, Billis, Konstantinos, Martin, Fergal J., Flicek, Paul, Petersen, Bent, Kang, Lin, and Michalak, Pawel
- Abstract
The tuatara (Sphenodon punctatus)—the only living member of the reptilian order Rhynchocephalia (Sphenodontia), once widespread across Gondwana1,2—is an iconic species that is endemic to New Zealand2,3. A key link to the now-extinct stem reptiles (from which dinosaurs, modern reptiles, birds and mammals evolved), the tuatara provides key insights into the ancestral amniotes2,4. Here we analyse the genome of the tuatara, which—at approximately 5 Gb—is among the largest of the vertebrate genomes yet assembled. Our analyses of this genome, along with comparisons with other vertebrate genomes, reinforce the uniqueness of the tuatara. Phylogenetic analyses indicate that the tuatara lineage diverged from that of snakes and lizards around 250 million years ago. This lineage also shows moderate rates of molecular evolution, with instances of punctuated evolution. Our genome sequence analysis identifies expansions of proteins, non-protein-coding RNA families and repeat elements, the latter of which show an amalgam of reptilian and mammalian features. The sequencing of the tuatara genome provides a valuable resource for deep comparative analyses of tetrapods, as well as for tuatara biology and conservation. Our study also provides important insights into both the technical challenges and the cultural obligations that are associated with genome sequencing. The approximately 5-Gb tuatara (Sphenodon punctatus) genome assembly provides a resource for analysing amniote evolution, and highlights the imperative for meaningful cultural engagement with Indigenous communities in genome-sequencing endeavours. [ABSTRACT FROM AUTHOR]
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- 2020
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20. The genome of the green anole lizard and a comparative analysis with birds and mammals
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Grabherr, Manfred, Fujita, Matthew K., Russell, Pamela, Jaffe, Jacob D., Mauceli, Evan, Pollock, David D., Novick, Peter A., Lowe, Craig B., Koriabine, Maxim Y., Haussler, David, ten Hallers, Boudewijn F., Shedlock, Andrew M., Peach, Sally E., Moreno, Ricardo Godinez, Colbourne, John K., Glor, Richard E., Boissinot, Stephane, Poe, Steven, Kong, Lesheng, Lara, Marcia, Janes, Daniel E., Di Palma, Federica, Castoe, Todd A., Williams, Christina, Heiman, David, Ray, David A., Alföldi, Jessica, Botka, Christopher, Johnson, Jeremy, Heger, Andreas, de Jong, Pieter J., and Organ, Chris L.
- Abstract
The evolution of the amniotic egg was one of the great evolutionary innovations in the history of life, freeing vertebrates from an obligatory connection to water and thus permitting the conquest of terrestrial environments1. Among amniotes, genome sequences are available for mammals2 and birds3–5, but not for non-avian reptiles. Here we report the genome sequence of the North American green anole lizard, Anolis carolinensis. We find that A. carolinensis microchromosomes are highly syntenic with chicken microchromosomes, yet do not exhibit the high GC and low repeat content that are characteristic of avian microchromosomes3. Also, A. carolinensis mobile elements are very young and diverse – more so than in any other sequenced amniote genome. This lizard genome’s GC content is also unusual in its homogeneity, unlike the regionally variable GC content found in mammals and birds6. We describe and assign sequence to the previously unknown A. carolinensis X chromosome. Comparative gene analysis shows that amniote egg proteins have evolved significantly more rapidly than other proteins. An anole phylogeny resolves basal branches to illuminate the history of their repeated adaptive radiations.
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- 2011
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21. Vertebral Adaptations to Large Body Size in Theropod Dinosaurs.
- Author
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Wilson, John P., Woodruff, D. Cary, Gardner, Jacob D., Flora, Holley M., Horner, John R., and Organ, Chris L.
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SAURISCHIA ,DINOSAURS ,METAPLASIA ,PHYLOGENY ,BIOMECHANICS - Abstract
Rugose projections on the anterior and posterior aspects of vertebral neural spines appear throughout Amniota and result from the mineralization of the supraspinous and interspinous ligaments via metaplasia, the process of permanent tissue-type transformation. In mammals, this metaplasia is generally pathological or stress induced, but is a normal part of development in some clades of birds. Such structures, though phylogenetically sporadic, appear throughout the fossil record of non-avian theropod dinosaurs, yet their physiological and adaptive significance has remained unexamined. Here we show novel histologic and phylogenetic evidence that neural spine projections were a physiological response to biomechanical stress in large-bodied theropod species. Metaplastic projections also appear to vary between immature and mature individuals of the same species, with immature animals either lacking them or exhibiting smaller projections, supporting the hypothesis that these structures develop through ontogeny as a result of increasing bending stress subjected to the spinal column. Metaplastic mineralization of spinal ligaments would likely affect the flexibility of the spinal column, increasing passive support for body weight. A stiff spinal column would also provide biomechanical support for the primary hip flexors and, therefore, may have played a role in locomotor efficiency and mobility in large-bodied species. This new association of interspinal ligament metaplasia in Theropoda with large body size contributes additional insight to our understanding of the diverse biomechanical coping mechanisms developed throughout Dinosauria, and stresses the significance of phylogenetic methods when testing for biological trends, evolutionary or not. [ABSTRACT FROM AUTHOR]
- Published
- 2016
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22. Macroevolution of genome size in sarcopterygians during the water–land transition.
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Organ, Chris, Struble, Mikayla, Canoville, Aurore, de Buffrénil, Vivian, and Laurin, Michel
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MACROEVOLUTION , *CROSSOPTERYGIANS , *VERTEBRATE genetics , *PHYLOGENY , *EUSTHENOPTERON - Abstract
Genome size spans over a 300-fold range among vertebrates (132 pg for Protopterus aethiopicus , the marbled lungfish, and 0.35 pg for Tetraodon nigroviridis , the green spotted pufferfish). While phylogenetic analysis of genome size has helped clarify how this variation evolved in multiple tetrapod groups, the ancestral tetrapod condition still remains poorly characterized, and this obscures our understanding of character state polarity and macroevolutionary trends in genome size. To address this problem, we used phylogenetic comparative methods to analyze paleohistological data from eight taxa of the Middle and Late Paleozoic to the Early Mesozoic: Eusthenopteron , Ichthyostega , Acheloma , Eryops , Trimerorhachis , Wetlugasaurus , an unidentified dissorophoid, and Chroniosaurus . Five other extinct taxa were included from previous studies to better frame our results, including Marmorerpeton , Cardiocephalus , Diplocaulus , an unidentified basal sauropsid, and Mycterosaurus . We augmented a previously reported histological and genome size data set (including data from 14 lissamphibians, three testudines, Sphenodon , five squamates, two crocodilians, 11 birds, and 22 mammals) with genome size and histological data from extant Latimeria and three extant actinopterygians. Our results suggest that all eight of the newly analyzed extinct taxa had genome sizes ranging between 3.2 and 3.9 pg. These results imply that basal tetrapods had genome sizes (and underlying genomic architectures) similar to extant mammals and lepidosaurs. We find no major shifts in genome size during the tetrapod water-to-land transition. Our analysis suggests that Eusthenopteron and Ichthyostega had genome sizes well within the range of extant actinopterygians and Latimeria , despite several whole-genome duplications in actinopterygians. [ABSTRACT FROM AUTHOR]
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- 2016
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23. Multiple Phylogenetically Distinct Events Shaped the Evolution of Limb Skeletal Morphologies Associated with Bipedalism in the Jerboas.
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Moore, Talia Y., Organ, Chris L., Edwards, Scott V., Biewener, Andrew A., Tabin, Clifford J., Jr.Jenkins, Farish A., and Cooper, Kimberly L.
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PHYLOGENY , *BIOLOGICAL evolution , *BIPEDALISM , *JERBOAS , *GENETICISTS , *MUSCULOSKELETAL system - Abstract
Summary Recent rapid advances in experimental biology have expanded the opportunity for interdisciplinary investigations of the evolution of form and function in non-traditional model species. However, historical divisions of philosophy and methodology between evolutionary/organismal biologists and developmental geneticists often preclude an effective merging of disciplines. In an effort to overcome these divisions, we take advantage of the extraordinary morphological diversity of the rodent superfamily Dipodoidea, including the bipedal jerboas, to experimentally study the developmental mechanisms and biomechanical performance of a remarkably divergent limb structure. Here, we place multiple limb character states in a locomotor and phylogenetic context. Whereas obligate bipedalism arose just once in the ancestor of extant jerboas, we find that digit loss, metatarsal fusion, between-limb proportions, and within-hindlimb proportions all evolved independently of one another. Digit loss occurred three times through at least two distinct developmental mechanisms, and elongation of the hindlimb relative to the forelimb is not simply due to growth mechanisms that change proportions within the hindlimb. Furthermore, we find strong evidence for punctuated evolution of allometric scaling of hindlimb elements during the radiation of Dipodoidea. Our work demonstrates the value of leveraging the evolutionary history of a clade to establish criteria for identifying the developmental genetic mechanisms of morphological diversification. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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24. Macroevolutionary developmental biology: Embryos, fossils, and phylogenies.
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Organ, Chris L., Cooper, Lisa Noelle, and Hieronymus, Tobin L.
- Abstract
The field of evolutionary developmental biology is broadly focused on identifying the genetic and developmental mechanisms underlying morphological diversity. Connecting the genotype with the phenotype means that evo-devo research often considers a wide range of evidence, from genetics and morphology to fossils. In this commentary, we provide an overview and framework for integrating fossil ontogenetic data with developmental data using phylogenetic comparative methods to test macroevolutionary hypotheses. We survey the vertebrate fossil record of preserved embryos and discuss how phylogenetic comparative methods can integrate data from developmental genetics and paleontology. Fossil embryos provide limited, yet critical, developmental data from deep time. They help constrain when developmental innovations first appeared during the history of life and also reveal the order in which related morphologies evolved. Phylogenetic comparative methods provide a powerful statistical approach that allows evo-devo researchers to infer the presence of nonpreserved developmental traits in fossil species and to detect discordant evolutionary patterns and processes across levels of biological organization. Developmental Dynamics 244:1184-1192, 2015. © 2015 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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25. THE EVOLUTION OF BIPEDALISM IN JERBOAS (RODENTIA: DIPODOIDEA): ORIGIN IN HUMID AND FORESTED ENVIRONMENTS.
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Wu, Shaoyuan, Zhang, Fuchun, Edwards, Scott V., Wu, Wenyu, Ye, Jie, Bi, Shundong, Ni, Xijun, Quan, Cheng, Meng, Jin, and Organ, Chris L.
- Subjects
JERBOAS ,BIPEDALISM ,RODENT evolution ,RODENT ecology ,PALEONTOLOGY ,MOLECULAR biology - Abstract
Mammalian bipedalism has long been thought to have arisen in response to arid and open environments. Here, we tested whether bipedalism coevolved with environmental changes using molecular and paleontological data from the rodent superfamily Dipodoidea and statistical methods for reconstructing ancestral characteristics and past climates. Our results show that the post-Late Miocene aridification exerted selective pressures on tooth shape, but not on leg length of bipedal jerboas. Cheek tooth crown height has increased since the Late Miocene, but the hind limb/head-body length ratios remained stable and high despite the environmental change from humid and forested to arid and open conditions, rather than increasing from low to high as predicted by the arid-bipedalism hypothesis. The decoupling of locomotor and dental character evolution indicates that bipedalism evolved under selective pressure different from that of dental hypsodonty in jerboas. We reconstructed the habitats of early jerboas using floral and faunal data, and the results show that the environments in which bipedalism evolved were forested. Our results suggest that bipedalism evolved as an adaptation to humid woodlands or forests for vertical jumping. Running at high speeds is likely a by-product of selection for jumping, which became advantageous in open environments later on. [ABSTRACT FROM AUTHOR]
- Published
- 2014
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26. ACTN3 Allele Frequency in Humans Covaries with Global Latitudinal Gradient.
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Friedlander, Scott M., Herrmann, Amanda L., Lowry, Daniel P., Mepham, Emily R., Lek, Monkol, North, Kathryn N., and Organ, Chris L.
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GENETIC code ,MUSCLE strength ,SKELETAL muscle ,ALLELES ,MUSCLE metabolism ,GENE flow ,SPECIES diversity - Abstract
A premature stop codon in ACTN3 resulting in a-actinin-3 deficiency (the ACTN3 577XX genotype) is common in humans and reduces strength, muscle mass, and fast-twitch fiber diameter, but increases the metabolic efficiency of skeletal muscle. Linkage disequilibrium data suggest that the ACTN3 R577X allele has undergone positive selection during human evolution. The allele has been hypothesized to be adaptive in environments with scarce resources where efficient muscle metabolism would be selected. Here we test this hypothesis by using recently developed comparative methods that account for evolutionary relatedness and gene flow among populations. We find evidence that the ACTN3 577XX genotype evolved in association with the global latitudinal gradient. Our results suggest that environmental variables related to latitudinal variation, such as species richness and mean annual temperature, may have influenced the adaptive evolution of ACTN3 577XX during recent human history. [ABSTRACT FROM AUTHOR]
- Published
- 2013
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27. Molecular and Paleontological Evidence for a Post-Cretaceous Origin of Rodents.
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Shaoyuan Wu, Wenyu Wu, Fuchun Zhang, Jie Ye, Xijun Ni, Jimin Sun, Edwards, Scott V., Jin Meng, and Organ, Chris L.
- Subjects
RODENTS ,ANIMAL diversity ,MOLECULAR clock ,FOSSIL rodents ,CENOZOIC Era ,GENETIC markers - Abstract
The timing of the origin and diversification of rodents remains controversial, due to conflicting results from molecular clocks and paleontological data. The fossil record tends to support an early Cenozoic origin of crown-group rodents. In contrast, most molecular studies place the origin and initial diversification of crown-Rodentia deep in the Cretaceous, although some molecular analyses have recovered estimated divergence times that are more compatible with the fossil record. Here we attempt to resolve this conflict by carrying out a molecular clock investigation based on a nine-gene sequence dataset and a novel set of seven fossil constraints, including two new rodent records (the earliest known representatives of Cardiocraniinae and Dipodinae). Our results indicate that rodents originated around 61.7-62.4 Ma, shortly after the Cretaceous/Paleogene (K/Pg) boundary, and diversified at the intraordinal level around 57.7-58.9 Ma. These estimates are broadly consistent with the paleontological record, but challenge previous molecular studies that place the origin and early diversification of rodents in the Cretaceous. This study demonstrates that, with reliable fossil constraints, the incompatibility between paleontological and molecular estimates of rodent divergence times can be eliminated using currently available tools and genetic markers. Similar conflicts between molecular and paleontological evidence bedevil attempts to establish the origination times of other placental groups. The example of the present study suggests that more reliable fossil calibration points may represent the key to resolving these controversies. [ABSTRACT FROM AUTHOR]
- Published
- 2012
- Full Text
- View/download PDF
28. Sauropod dinosaurs evolved moderately sized genomes unrelated to body size.
- Author
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Organ, Chris L.
- Subjects
- *
SAURISCHIA , *BIOLOGICAL evolution , *GENOMES , *BODY size , *LEAST squares , *REGRESSION analysis , *GENETIC models - Abstract
Sauropodomorph dinosaurs include the largest land animals to have ever lived, some reaching up to 10 times the mass of an African elephant. Despite their status defining the upper range for body size in land animals, it remains unknown whether sauropodomorphs evolved larger-sized genomes than non-avian theropods, their sister taxon, or whether a relationship exists between genome size and body size in dinosaurs, two questions critical for understanding broad patterns of genome evolution in dinosaurs. Here we report inferences of genome size for 10 sauropodomorph taxa. The estimates are derived from a Bayesian phylogenetic generalized least squares approach that generates posterior distributions of regression models relating genome size to osteocyte lacunae volume in extant tetrapods. We estimate that the average genome size of sauropodomorphs was 2.02 pg (range of species means: 1.77–2.21 pg), a value in the upper range of extant birds (mean = 1.42 pg, range: 0.97–2.16 pg) and near the average for extant non-avian reptiles (mean = 2.24 pg, range: 1.05–5.44 pg). The results suggest that the variation in size and architecture of genomes in extinct dinosaurs was lower than the variation found in mammals. A substantial difference in genome size separates the two major clades within dinosaurs, Ornithischia (large genomes) and Saurischia (moderate to small genomes). We find no relationship between body size and estimated genome size in extinct dinosaurs, which suggests that neutral forces did not dominate the evolution of genome size in this group. [ABSTRACT FROM AUTHOR]
- Published
- 2009
- Full Text
- View/download PDF
29. Palaeogenomics of pterosaurs and the evolution of small genome size in flying vertebrates.
- Author
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Organ, Chris L. and Shedlock, Andrew M.
- Subjects
GENOMES ,PTEROSAURIA ,FOSSIL reptiles ,BAYESIAN analysis ,EVOLUTIONARY paleobiology ,BODY size - Abstract
This article discusses a study which estimated the genome size for four species of pterosaurs and seven species of basal archosauromorphs using a Bayesian comparative approach. It also measured the osteocyte lacunae of these species using palaeohistological samples. Results showed that bats evolved smaller sized genomes than other mammals when controlled for phylogeny. According to the study's hypothesis, there is a relationship between cell size and genome size. Results of the estimates showed that pterosaur genome sizes are within the upper quartile of the avian range, while the basal archosauromorphs are close to the average living crocodylians. The study found no significant relationship between body size and genome size in tetrapods.
- Published
- 2009
- Full Text
- View/download PDF
30. Analysis of the African coelacanth genome sheds light on tetrapod evolution
- Author
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Amemiya, Chris T., Alföldi, Jessica, Lee, Alison P., Fan, Shaohua, Philippe, Hervé, MacCallum, Iain, Braasch, Ingo, Manousaki, Tereza, Schneider, Igor, Rohner, Nicolas, Organ, Chris, Chalopin, Domitille, Smith, Jeramiah J., Robinson, Mark, Dorrington, Rosemary A., Gerdol, Marco, Aken, Bronwen, Biscotti, Maria Assunta, Barucca, Marco, Baurain, Denis, Berlin, Aaron M., Blatch, Gregory L., Buonocore, Francesco, Burmester, Thorsten, Campbell, Michael S., Canapa, Adriana, Cannon, John P., Christoffels, Alan, De Moro, Gianluca, Edkins, Adrienne L., Fan, Lin, Fausto, Anna Maria, Feiner, Nathalie, Forconi, Mariko, Gamieldien, Junaid, Gnerre, Sante, Gnirke, Andreas, Goldstone, Jared V., Haerty, Wilfried, Hahn, Mark E., Hesse, Uljana, Hoffmann, Steve, Johnson, Jeremy, Karchner, Sibel I., Kuraku, Shigehiro, Lara, Marcia, Levin, Joshua Z., Litman, Gary W., Mauceli, Evan, Miyake, Tsutomu, Mueller, M. Gail, Nelson, David R., Nitsche, Anne, Olmo, Ettore, Ota, Tatsuya, Pallavicini, Alberto, Panji, Sumir, Picone, Barbara, Ponting, Chris P., Prohaska, Sonja J., Przybylski, Dariusz, Saha, Nil Ratan, Ravi, Vydianathan, Ribeiro, Filipe J., Sauka-Spengler, Tatjana, Scapigliati, Giuseppe, Searle, Stephen M. J., Sharpe, Ted, Simakov, Oleg, Stadler, Peter F., Stegeman, John J., Sumiyama, Kenta, Tabbaa, Diana, Tafer, Hakim, Turner-Maier, Jason, van Heusden, Peter, White, Simon, Williams, Louise, Yandell, Mark, Brinkmann, Henner, Volff, Jean-Nicolas, Tabin, Clifford J., Shubin, Neil, Schartl, Manfred, Jaffe, David, Postlethwait, John H., Venkatesh, Byrappa, Di Palma, Federica, Lander, Eric S., Meyer, Axel, and Lindblad-Toh, Kerstin
- Abstract
It was a zoological sensation when a living specimen of the coelacanth was first discovered in 1938, as this lineage of lobe-finned fish was thought to have gone extinct 70 million years ago. The modern coelacanth looks remarkably similar to many of its ancient relatives, and its evolutionary proximity to our own fish ancestors provides a glimpse of the fish that first walked on land. Here we report the genome sequence of the African coelacanth, Latimeria chalumnae. Through a phylogenomic analysis, we conclude that the lungfish, and not the coelacanth, is the closest living relative of tetrapods. Coelacanth protein-coding genes are significantly more slowly evolving than those of tetrapods, unlike other genomic features . Analyses of changes in genes and regulatory elements during the vertebrate adaptation to land highlight genes involved in immunity, nitrogen excretion and the development of fins, tail, ear, eye, brain, and olfaction. Functional assays of enhancers involved in the fin-to-limb transition and in the emergence of extra-embryonic tissues demonstrate the importance of the coelacanth genome as a blueprint for understanding tetrapod evolution.
- Published
- 2013
- Full Text
- View/download PDF
31. Molecular and Paleontological Evidence for a Post-Cretaceous Origin of Rodents
- Author
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Wu, Shaoyuan, Wu, Wenyu, Zhang, Fuchun, Ye, Jie, Ni, Xijun, Sun, Jimin, Edwards, Scott V., Meng, Jin, and Organ, Chris L.
- Subjects
Biology ,Evolutionary Biology ,Evolutionary Systematics ,Phylogenetics ,Paleontology ,Vertebrate Paleontology ,Zoology ,Animal Phylogenetics ,Mammalogy ,Earth Sciences - Abstract
The timing of the origin and diversification of rodents remains controversial, due to conflicting results from molecular clocks and paleontological data. The fossil record tends to support an early Cenozoic origin of crown-group rodents. In contrast, most molecular studies place the origin and initial diversification of crown-Rodentia deep in the Cretaceous, although some molecular analyses have recovered estimated divergence times that are more compatible with the fossil record. Here we attempt to resolve this conflict by carrying out a molecular clock investigation based on a nine-gene sequence dataset and a novel set of seven fossil constraints, including two new rodent records (the earliest known representatives of Cardiocraniinae and Dipodinae). Our results indicate that rodents originated around 61.7–62.4 Ma, shortly after the Cretaceous/Paleogene (K/Pg) boundary, and diversified at the intraordinal level around 57.7–58.9 Ma. These estimates are broadly consistent with the paleontological record, but challenge previous molecular studies that place the origin and early diversification of rodents in the Cretaceous. This study demonstrates that, with reliable fossil constraints, the incompatibility between paleontological and molecular estimates of rodent divergence times can be eliminated using currently available tools and genetic markers. Similar conflicts between molecular and paleontological evidence bedevil attempts to establish the origination times of other placental groups. The example of the present study suggests that more reliable fossil calibration points may represent the key to resolving these controversies., Organismic and Evolutionary Biology
- Published
- 2012
- Full Text
- View/download PDF
32. Phylogenetic Rate Shifts in Feeding Time During the Evolution of Homo
- Author
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Organ, Chris Lee, Nunn, Charles Lindsay, Machanda, Zarin Pearl, and Wrangham, Richard W.
- Subjects
phylogenetic comparative methods ,hominin ,anthropology - Abstract
Unique among animals, humans eat a diet rich in cooked and nonthermally processed food. The ancestors of modern humans who invented food processing (including cooking) gained critical advantages in survival and fitness through increased caloric intake. However, the time and manner in which food processing became biologically significant are uncertain. Here, we assess the inferred evolutionary consequences of food processing in the human lineage by applying a Bayesian phylogenetic outlier test to a comparative dataset of feeding time in humans and nonhuman primates. We find that modern humans spend an order of magnitude less time feeding than predicted by phylogeny and body mass (4.7% vs. predicted 48% of daily activity). This result suggests that a substantial evolutionary rate change in feeding time occurred along the human branch after the human–chimpanzee split. Along this same branch, Homo erectus shows a marked reduction in molar size that is followed by a gradual, although erratic, decline in H. sapiens. We show that reduction in molar size in early Homo (H. habilis and H. rudolfensis) is explicable by phylogeny and body size alone. By contrast, the change in molar size to H. erectus, H. neanderthalensis, and H. sapiens cannot be explained by the rate of craniodental and body size evolution. Together, our results indicate that the behaviorally driven adaptations of food processing (reduced feeding time and molar size) originated after the evolution of Homo but before or concurrent with the evolution of H. erectus, which was around 1.9 Mya., Human Evolutionary Biology, Organismic and Evolutionary Biology
- Published
- 2011
- Full Text
- View/download PDF
33. Publisher Correction: The tuatara genome reveals ancient features of amniote evolution.
- Author
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Gemmell, Neil J., Rutherford, Kim, Prost, Stefan, Tollis, Marc, Winter, David, Macey, J. Robert, Adelson, David L., Suh, Alexander, Bertozzi, Terry, Grau, José H., Organ, Chris, Gardner, Paul P., Muffato, Matthieu, Patricio, Mateus, Billis, Konstantinos, Martin, Fergal J., Flicek, Paul, Petersen, Bent, Kang, Lin, and Michalak, Pawel
- Abstract
An amendment to this paper has been published and can be accessed via a link at the top of the paper. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
34. Live birth in an archosauromorph reptile.
- Author
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Liu, Jun, Organ, Chris L., Benton, Michael J., Brandley, Matthew C., and Aitchison, Jonathan C.
- Published
- 2017
- Full Text
- View/download PDF
35. Early tetrapodomorph biogeography: Controlling for fossil record bias in macroevolutionary analyses.
- Author
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Gardner, Jacob D., Surya, Kevin, and Organ, Chris L.
- Subjects
- *
FOSSILS , *SOIL sampling , *BIOGEOGRAPHY , *REGRESSION analysis , *DATA analysis - Abstract
The fossil record provides direct empirical data for understanding macroevolutionary patterns and processes. Inherent biases in the fossil record are well known to confound analyses of this data. Sampling bias proxies have been used as covariates in regression models to test for such biases. Proxies, such as formation count, are associated with paleobiodiversity, but are insufficient for explaining species dispersal owing to a lack of geographic context. Here, we develop a sampling bias proxy that incorporates geographic information and test it with a case study on early tetrapodomorph biogeography. We use recently-developed Bayesian phylogeographic models and a new supertree of early tetrapodomorphs to estimate dispersal rates and ancestral habitat locations. We find strong evidence that geographic sampling bias explains supposed radiations in dispersal rate (potential adaptive radiations). Our study highlights the necessity of accounting for geographic sampling bias in macroevolutionary and phylogenetic analyses and provides an approach to test for its effect. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
36. Bony cranial ornamentation linked to rapid evolution of gigantic theropod dinosaurs.
- Author
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Gates, Terry A., Organ, Chris, and Zanno, Lindsay E.
- Published
- 2016
- Full Text
- View/download PDF
37. Early genome size increase in urodeles.
- Author
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Laurin, Michel, Canoville, Aurore, Struble, Mikayla, Organ, Chris, and de Buffrénil, Vivian
- Subjects
- *
FOSSIL salamanders , *METAMORPHOSIS , *OSTEOCYTES , *JURASSIC Period , *PALEOGENE - Abstract
Urodeles have the largest genomes among extant tetrapods, varying greatly between metamorphic and neotenic species, which have the smallest and the largest genomes of the group, respectively. The evolutionary tempo and mode of genome size expansion in urodeles are poorly documented, especially because genome size does not directly fossilize. Consequently, the ancestral state for genome size, and therefore, the polarity of its evolution in urodeles are uncertain. However, recent studies have demonstrated that osteocyte (lacuna) size is correlated with genome size. Below, we present histological data, on osteocyte lacuna size from one of the oldest known stem-urodeles, Marmorerpeton , from the Middle Jurassic (Bathonian, 166–168 Ma), as well as on five extant urodele species. Our analysis of these taxa, coupled with previously published data, suggests that stem-urodeles had already evolved large genomes, typical of extant urodeles by the Bathonian. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
38. The evolution and ecology of gigantism in terror birds (Aves, Phorusrhacidae).
- Author
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LaBarge TW, Gardner JD, and Organ CL
- Subjects
- Animals, Passeriformes physiology, Bayes Theorem, South America, Birds physiology, Biological Evolution, Phylogeny, Body Size
- Abstract
Terror birds (Aves, Phorusrhacidae) were large flightless apex predators in South America during the Cenozoic. Here, we estimate a new phylogeny for phorusrhacids using Bayesian inference. We demonstrate phylogenetic evidence for a monophyletic Patagornithinae and find significant support for a distinct crown group associated with the quintessential 'terror bird' characteristics. We use this phylogeny to analyse the evolution of body size and cursoriality. Our results reveal that size overlap was rare between co-occurring subfamilies, supporting the hypothesis that these traits were important for niche partitioning. We observe that gigantism evolved in a single clade, containing Phorusrhacinae and Physornithinae. The members of this lineage were consistently larger than all other phorusrhacids. Phorusrhacinae emerged following the extinction of Physornithinae, suggesting the ecological succession of the apex predator niche. The first known phorusrhacine, Phorusrhacos longissimus , was gigantic but significantly smaller and more cursorial than any physornithine. These traits likely evolved in response to the expansion of open environments. Following the Santacrucian SALMA, phorusrhacines increased in size, further converging on the morphology of Physornithinae. These findings suggest that the evolution and displacement of body size drove terror bird niche partitioning and competitive exclusion controlled phorusrhacid diversity.
- Published
- 2024
- Full Text
- View/download PDF
39. The coevolution of rostral keratin and tooth distribution in dinosaurs.
- Author
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Aguilar-Pedrayes I, Gardner JD, and Organ CL
- Subjects
- Animals, Phylogeny, Biological Evolution, Keratins, Fossils, Dinosaurs anatomy & histology, Tooth Loss, Tooth anatomy & histology
- Abstract
Teeth evolved early in vertebrate evolution, and their morphology reflects important specializations in diet and ecology among species. The toothless jaws (edentulism) in extant birds likely coevolved with beak keratin, which functionally replaced teeth. However, extinct dinosaurs lost teeth multiple times independently and exhibited great variation in toothrow distribution and rhamphotheca-like keratin structures. Here, we use rostral jawbone surface texture as a proxy for rostral keratin covering and phylogenetic comparative models to test for the influence of rostral keratin on toothrow distribution in Mesozoic dinosaurs. We find that the evolution of rostral keratin covering explains partial toothrow reduction but not jaw toothlessness. Toothrow reduction preceded the evolution of rostral keratin cover in theropods. Non-theropod dinosaurs evolved continuous toothrows despite evolving rostral keratin covers (e.g. some ornithischians and sauropodomorphs). We also show that rostral keratin covers did not significantly increase the evolutionary rate of tooth loss, which further delineates the antagonistic relationship between these structures. Our results suggest that the evolution of rostral keratin had a limited effect on suppressing tooth development. Independent changes in jaw development may have facilitated further tooth loss. Furthermore, the evolution of strong chemical digestion, a gizzard, and a dietary shift to omnivory or herbivory likely alleviated selective pressures for tooth development.
- Published
- 2024
- Full Text
- View/download PDF
40. The relationship between genome size and metabolic rate in extant vertebrates.
- Author
-
Gardner JD, Laurin M, and Organ CL
- Subjects
- Animals, Biological Evolution, Body Temperature Regulation genetics, Phylogeny, Basal Metabolism, Genome Size, Vertebrates genetics, Vertebrates metabolism
- Abstract
Genome size has long been hypothesized to affect the metabolic rate in various groups of animals. The mechanism behind this proposed association is the nucleotypic effect, in which large nucleus and cell sizes influence cellular metabolism through surface area-to-volume ratios. Here, we provide a review of the recent literature on the relationship between genome size and metabolic rate. We also conduct an analysis using phylogenetic comparative methods and a large sample of extant vertebrates. We find no evidence that the effect of genome size improves upon models in explaining metabolic rate variation. Not surprisingly, our results show a strong positive relationship between metabolic rate and body mass, as well as a substantial difference in metabolic rate between endothermic and ectothermic vertebrates, controlling for body mass. The presence of endothermy can also explain elevated rate shifts in metabolic rate whereas genome size cannot. We further find no evidence for a punctuated model of evolution for metabolic rate. Our results do not rule out the possibility that genome size affects cellular physiology in some tissues, but they are consistent with previous research suggesting little support for a direct functional connection between genome size and basal metabolic rate in extant vertebrates. This article is part of the theme issue 'Vertebrate palaeophysiology'.
- Published
- 2020
- Full Text
- View/download PDF
41. From dinosaurs to birds: a tail of evolution.
- Author
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Rashid DJ, Chapman SC, Larsson HC, Organ CL, Bebin AG, Merzdorf CS, Bradley R, and Horner JR
- Abstract
A particularly critical event in avian evolution was the transition from long- to short-tailed birds. Primitive bird tails underwent significant alteration, most notably reduction of the number of caudal vertebrae and fusion of the distal caudal vertebrae into an ossified pygostyle. These changes, among others, occurred over a very short evolutionary interval, which brings into focus the underlying mechanisms behind those changes. Despite the wealth of studies delving into avian evolution, virtually nothing is understood about the genetic and developmental events responsible for the emergence of short, fused tails. In this review, we summarize the current understanding of the signaling pathways and morphological events that contribute to tail extension and termination and examine how mutations affecting the genes that control these pathways might influence the evolution of the avian tail. To generate a list of candidate genes that may have been modulated in the transition to short-tailed birds, we analyzed a comprehensive set of mouse mutants. Interestingly, a prevalent pleiotropic effect of mutations that cause fused caudal vertebral bodies (as in the pygostyles of birds) is tail truncation. We identified 23 mutations in this class, and these were primarily restricted to genes involved in axial extension. At least half of the mutations that cause short, fused tails lie in the Notch/Wnt pathway of somite boundary formation or differentiation, leading to changes in somite number or size. Several of the mutations also cause additional bone fusions in the trunk skeleton, reminiscent of those observed in primitive and modern birds. All of our findings were correlated to the fossil record. An open question is whether the relatively sudden appearance of short-tailed birds in the fossil record could be accounted for, at least in part, by the pleiotropic effects generated by a relatively small number of mutational events.
- Published
- 2014
- Full Text
- View/download PDF
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