Your search keyword '"Chris L. Organ"' showing total 2 results

1. Palaeogenomics of pterosaurs and the evolution of small genome size in flying vertebrates

Author

Chris L. Organ and Andrew M. Shedlock

Subjects

Origin of avian flight, Phylogenetic inertia, Genome, Genetic Drift, Reptiles, Zoology, Close relatives, Biology, Extinction, Biological, Biological Evolution, Agricultural and Biological Sciences (miscellaneous), Cell size, Birds, Genetic drift, Phylogenetics, Chiroptera, Vertebrates, Animals, General Agricultural and Biological Sciences, Genome size, Phylogeny, Research Article

Abstract

The two living groups of flying vertebrates, birds and bats, both have constricted genome sizes compared with their close relatives. But nothing is known about the genomic characteristics of pterosaurs, which took to the air over 70 Myr before birds and were the first group of vertebrates to evolve powered flight. Here, we estimate genome size for four species of pterosaurs and seven species of basal archosauromorphs using a Bayesian comparative approach. Our results suggest that small genomes commonly associated with flight in bats and birds also evolved in pterosaurs, and that the rate of genome-size evolution is proportional to genome size within amniotes, with the fastest rates occurring in lineages with the largest genomes. We examine the role that drift may have played in the evolution of genome size within tetrapods by testing for correlated evolution between genome size and body size, but find no support for this hypothesis. By contrast, we find evidence suggesting that a combination of adaptation and phylogenetic inertia best explains the correlated evolution of flight and genome-size contraction. These results suggest that small genome/cell size evolved prior to or concurrently with flight in pterosaurs. We predict that, similar to the pattern seen in theropod dinosaurs, genome-size contraction preceded flight in pterosaurs and bats.

Published

2008

2. Molecular evolution of Dmrt1 accompanies change of sex-determining mechanisms in reptilia

Author

Jennifer A. Marshall Graves, Kim Rutherford, John B. Iverson, Nicole Valenzuela, Robert Literman, Neil J. Gemmell, Denis O’Meally, Tariq Ezaz, Rami Stiglec, Chris L. Organ, Daniel E. Janes, Arthur Georges, Scott V. Edwards, Jeffrey W. Tamplin, and Stephen D. Sarre

Subjects

chemistry.chemical_classification, Genetics, Ancestral reconstruction, Male, Sexual differentiation, Evolutionary Developmental Biology, Reptiles, Biology, Sex Determination Processes, Agricultural and Biological Sciences (miscellaneous), Amino acid, Evolution, Molecular, Exon, chemistry, Molecular evolution, Evolutionary biology, Genotype, Animals, Female, General Agricultural and Biological Sciences, Transcription factor, Gene, Transcription Factors

Abstract

In reptiles, sex-determining mechanisms have evolved repeatedly and reversibly between genotypic and temperature-dependent sex determination. The gene Dmrt1 directs male determination in chicken (and presumably other birds), and regulates sex differentiation in animals as distantly related as fruit flies, nematodes and humans. Here, we show a consistent molecular difference in Dmrt1 between reptiles with genotypic and temperature-dependent sex determination. Among 34 non-avian reptiles, a convergently evolved pair of amino acids encoded by sequence within exon 2 near the DM-binding domain of Dmrt1 distinguishes species with either type of sex determination. We suggest that this amino acid shift accompanied the evolution of genotypic sex determination from an ancestral condition of temperature-dependent sex determination at least three times among reptiles, as evident in turtles, birds and squamates. This novel hypothesis describes the evolution of sex-determining mechanisms as turnover events accompanied by one or two small mutations.

Published

2014