Gene Expression Intensity Shapes Evolutionary Rates of the Proteins Encoded by the Vertebrate Genome

doi:10.1534/genetics.104.028944

Genetics, Vol. 168, 373-381, September 2004, Copyright © 2004
doi:10.1534/genetics.104.028944

Gene Expression Intensity Shapes Evolutionary Rates of the Proteins Encoded by the Vertebrate Genome

Sankar Subramanian and Sudhir Kumar¹

Center for Evolutionary Functional Genomics, The Biodesign Institute and School of Life Sciences, Arizona State University, Tempe, Arizona 85287-4501

^¹ Corresponding author: Life Sciences A-351, Arizona State University, Tempe, AZ 85287-4501.
E-mail: s.kumar{at}asu.edu

Natural selection leaves its footprints on protein-coding sequencesby modulating their silent and replacement evolutionary rates.In highly expressed genes in invertebrates, these footprintsare seen in the higher codon usage bias and lower synonymousdivergence. In mammals, the highly expressed genes have a shortergene length in the genome and the breadth of expression is knownto constrain the rate of protein evolution. Here we have examinedhow the rates of evolution of proteins encoded by the vertebrategenomes are modulated by the amount (intensity) of gene expression.To understand how natural selection operates on proteins thatappear to have arisen in earlier and later phases of animalevolution, we have contrasted patterns of mouse proteins thathave homologs in invertebrate and protist genomes (Precambriangenes) with those that do not have such detectable homologs(vertebrate-specific genes). We find that the intensity of geneexpression relates inversely to the rate of protein sequenceevolution on a genomic scale. The most highly expressed genesactually show the lowest total number of substitutions per polypeptide,consistent with cumulative effects of purifying selection onindividual amino acid replacements. Precambrian genes exhibita more pronounced difference in protein evolutionary rates (upto three times) between the genes with high and low expressionlevels as compared to the vertebrate-specific genes, which appearsto be due to the narrower breadth of expression of the vertebrate-specificgenes. These results provide insights into the differentialrelationship and effect of the increasing complexity of animalbody form on evolutionary rates of proteins.

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Gene Expression Intensity Shapes Evolutionary Rates of the Proteins Encoded by the Vertebrate Genome

Sankar Subramanian and Sudhir Kumar1

Sankar Subramanian and Sudhir Kumar¹

				M. M. Alba and J. Castresana Inverse Relationship Between Evolutionary Rate and Age of Mammalian Genes Mol. Biol. Evol., March 1, 2005; 22(3): 598 - 606. [Abstract] [Full Text] [PDF]