53 research outputs found
MitochondrialâDna Analyses And The Origin And Relative Age Of Parthenogenetic Lizards (Genus Cnemidophorus). Ii. C. Neomexicanus And The C. Tesselatus Complex
Peer Reviewedhttps://deepblue.lib.umich.edu/bitstream/2027.42/137490/1/evo02541.pd
MitochondrialâDna Analyses And The Origin And Relative Age Of Parthenogenetic Lizards (Genus Cnemidophorus). Iv. Nine SexlineatusâGroup Unisexuals
Peer Reviewedhttps://deepblue.lib.umich.edu/bitstream/2027.42/137512/1/evo02543.pd
Low levels of nucleotide diversity in Crocodylus moreletii and evidence of hybridization with C. acutus
Examinations of both population genetic structure and the processes that lead to such structure in crocodilians have been initiated in several species in response to a call by the IUCN Crocodile Specialist Group. A recent study used microsatellite markers to characterize Morelet\u27s crocodile (Crocodylus moreletii) populations in north-central Belize and presented evidence for isolation by distance. To further investigate this hypothesis, we sequenced a portion of the mitochondrial control region for representative animals after including samples from additional locales in Belize, Guatemala and Mexico. While there is limited evidence of subdivision involving other locales, we found that most of the differentiation among populations of C. moreletii can be attributed to animals collected from a single locale in Belize, Banana Bank Lagoon. Furthermore, mitochondrial DNA sequence analysis showed that animals from this and certain other locales display a haplotype characteristic of the American crocodile, C. acutus, rather than C. moreletii. We interpret this as evidence of hybridization between the two species and comment on how these new data have influenced our interpretation of previous findings. We also find very low levels of nucleotide diversity in C. moreletii haplotypes and provide evidence for a low rate of substitution in the crocodilian mitochondrial control region. Finally, the conservation implications of these findings are discussed
A New Horned Crocodile from the Plio-Pleistocene Hominid Sites at Olduvai Gorge, Tanzania
BACKGROUND: The fossil record reveals surprising crocodile diversity in the Neogene of Africa, but relationships with their living relatives and the biogeographic origins of the modern African crocodylian fauna are poorly understood. A Plio-Pleistocene crocodile from Olduvai Gorge, Tanzania, represents a new extinct species and shows that high crocodylian diversity in Africa persisted after the Miocene. It had prominent triangular "horns" over the ears and a relatively deep snout, these resemble those of the recently extinct Malagasy crocodile Voay robustus, but the new species lacks features found among osteolaemines and shares derived similarities with living species of Crocodylus. METHODOLOGY/PRINCIPAL FINDINGS: The holotype consists of a partial skull and skeleton and was collected on the surface between two tuffs dated to approximately 1.84 million years (Ma), in the same interval near the type localities for the hominids Homo habilis and Australopithecus boisei. It was compared with previously-collected material from Olduvai Gorge referable to the same species. Phylogenetic analysis places the new form within or adjacent to crown Crocodylus. CONCLUSIONS/SIGNIFICANCE: The new crocodile species was the largest predator encountered by our ancestors at Olduvai Gorge, as indicated by hominid specimens preserving crocodile bite marks from these sites. The new species also reinforces the emerging view of high crocodylian diversity throughout the Neogene, and it represents one of the few extinct species referable to crown genus Crocodylus
Insights into mammalian TE diversity through the curation of 248 genome assemblies
[INTRODUCTION] An estimated 160 million years have passed since the first placental mammals evolved. These eutherians are categorized into 19 orders consisting of nearly 4000 extant species, with ~70% being bats or rodents. Broad, in-depth, and comparative genomic studies across Eutheria have previously been unachievable because of the lack of genomic resources. The collaboration of the Zoonomia Consortium made available hundreds of high-quality genome assemblies for comparative analysis. Our focus within the consortium was to investigate the evolution of transposable elements (TEs) among placental mammals. Using these data, we identified previously known TEs, described previously unknown TEs, and analyzed the TE distribution among multiple taxonomic levels.[RATIONALE] The emergence of accurate and affordable sequencing technology has propelled efforts to sequence increasingly more nonmodel mammalian genomes in the past decade. Most of these efforts have traditionally focused on genic regions searching for patterns of selection or variation in gene regulation. The common trend of ignoring or trivializing TE annotation with newly published genomes has resulted in severe lag of TE analyses, leading to extensive undiscovered TE variation. This oversight has neglected an important source of evolution because the accumulation of TEs is attributable to drastic alterations in genome architecture, including insertions, deletions, duplications, translocations, and inversions. Our approach to the Zoonomia dataset was to provide future inquirers accurate and meticulous TE curations and to describe taxonomic variation among eutherians.[RESULTS] We annotated the TE content of 248 mammalian genome assemblies, which yielded a library of 25,676 consensus TE sequences, 8263 of which were previously unidentified TE sequences (available at https://dfam.org). We affirmed that the largest component of a typical mammalian genome is comprised of TEs (average 45.6%). Of the 248 assemblies, the lowest genomic percentage of TEs was found in the star-nosed mole (27.6%), and the largest percentage was seen in the aardvark (74.5%), whose increase in TE accumulation drove a corresponding increase in genome sizeâa correlation we observed across Eutheria. The overall genomic proportions of recently accumulated TEs were roughly similar across most mammals in the dataset, with a few notable exceptions (see the figure). Diversity of recently accumulated TEs is highest among multiple families of bats, mostly driven by substantial DNA transposon activity. Our data also exhibit an increase of recently accumulated DNA transposons among carnivore lineages over their herbivorous counterparts, which suggests that diet may play a role in determining the genomic content of TEs.[CONCLUSION] The copious TE data provided in this work emanated from the largest comprehensive TE curation effort to date. Considering the wide-ranging effects that TEs impose on genomic architecture, these data are an important resource for future inquiries into mammalian genomics and evolution and suggest avenues for continued study of these important yet understudied genomic denizens.This project was partially supported by NSF grant DEB 1838283 (D.D.M.-S. and D.A.R.), NSF grant IOS 2032006 (D.D.M.-S. and D.A.R.), National Institutes of Health (NIH) grant R01HG002939 (J.M.S., R.H., A.F.A.S., and J.Ros.), NIH grant U24HG010136 (J.M.S., R.H., A.F.A.S., and J.Ros.), NSF grant DEB 1838273 (L.M.D.), NSF grant DGE 1633299 (L.M.D.), NIH grant NHGRI R01HG008742 (Zoonomia Consortium), and a Swedish Research Council Distinguished Professor Award (Zoonomia Consortium).Peer reviewe
Sequencing three crocodilian genomes to illuminate the evolution of archosaurs and amniotes
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
Morphologic and allozymic analysis of microgeographic variation in the isopod Sphaeroma Quadridentatum
The intertidal marine isopod Sphaeroma quadridentatum was scored for polymorphisms of color, carapace pattern and enzyme systems. Samples were collected at six sites in Galveston County, Texas, during three collection periods: August, 1976; December, 1976 and February, 1977. Possible microgeographic variation and population subdivision were evaluated by spatial and temporal analysis. Data for the morphologic characters and one allozyme locus were analyzed using GH tests and a non-parametric analysis of variance. Also, allozyme frequencies were used to calculate genetic measures of subdivision. Spatial analysis revealed no significant deviations from homogeneity either morphologically or allozymically. Temporal variation was not distinguishable allozymically, however, morphological analysis revealed an increase of the red and grey color classes. This change may be related to seasonality, however further work is necessary to make any definitive statement.Biology and Biochemistry, Department o
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