Your search keyword '"Lawrence I. Grossman"' showing total 3 results

1. Dolphin genome provides evidence for adaptive evolution of nervous system genes and a molecular rate slowdown.

Author

Michael R., McGowen, Lawrence I., Grossman, and Derek E., Wildman

Subjects

GENOMES, DOLPHINS, FISH genetics, APPROXIMATION theory, PRIMATES, CETACEA

Abstract

Cetaceans (dolphins and whales) have undergone a radical transformation from the original mammalian bodyplan. In addition, some cetaceans have evolved large brains and complex cognitive capacities. We compared approximately 10 000 protein-coding genes culled from the bottlenose dolphin genome with nine other genomes to reveal molecular correlates of the remarkable phenotypic features of these aquatic mammals. Evolutionary analyses demonstrated that the overall synonymous substitution rate in dolphins has slowed compared with other studied mammals, and is within the range of primates and elephants. We also discovered 228 genes potentially under positive selection (dN/dS > 1) in the dolphin lineage. Twenty-seven of these genes are associated with the nervous system, including those related to human intellectual disabilities, synaptic plasticity and sleep. In addition, genes expressed in the mitochondrion have a significantly higher mean dN/dS ratio in the dolphin lineage than others examined, indicating evolution in energy metabolism. We encountered selection in other genes potentially related to cetacean adaptations such as glucose and lipid metabolism, dermal and lung development, and the cardiovascular system. This study underlines the parallel molecular trajectory of cetaceans with other mammalian groups possessing large brains. [ABSTRACT FROM AUTHOR]

Published

2012

2. Rapid Nonsynonymous Evolution of the Iron-Sulfur Protein in Anthropoid Primates.

Author

Jeffrey W. Doan, Timothy R. Schmidt, Derek E. Wildman, Morris Goodman, Mark L. Weiss, and Lawrence I. Grossman

Abstract

Abstract Cytochrome c (CYC) and 9 of the 13 subunits of cytochrome c oxidase (complex IV; COX) were previously shown to have accelerated rates of nonsynonymous substitution in anthropoid primates. Cytochrome b, the mtDNA encoded subunit of ubiquinol-cytochrome c reductase (complex III), also showed an accelerated nonsynonymous substitution rate in anthropoid primates but rate information about the nuclear encoded subunits of complex III has been lacking.We now report that phylogenetic and relative rates analysis of a nuclear encoded catalytically active subunit of complex III, the ironsulfur protein (ISP), shows an accelerated rate of amino acid replacement similar to cytochrome b. Because both ISP and subunit 9, whose function is not directly related to electron transport, are produced by cleavage into two subunits of the initial translation product of a single gene, it is probable that these two subunits of complex III have essentially identical underlying rates of mutation. Nevertheless, we find that the catalytically active ISP has an accelerated rate of amino acid replacement in anthropoid primates whereas the catalytically inactive subunit 9 does not. [ABSTRACT FROM AUTHOR]

Published

2005

3. Cytochrome c oxidase of mammals contains a testes-specific isoform of subunit VIb—the counterpart to testes-specific cytochrome c? (The cDNA sequence data in this paper have been submitted to GenBank under the accession numbers: AY152398 (human VIb-2), AY152401 (bull VIb-2), AY152399 (rat VIb-2) and AY152400 (mouse VIb).)

Author

Maik Hüttemann, Saied Jaradat, and Lawrence I. Grossman

Published

2003