Molecular Biology and Evolution 17:278-283 (2000)
© 2000 Society for Molecular Biology and Evolution
Articles |
An Unusual Form of Purifying Selection in a Sperm Protein
Institute of Molecular Evolutionary Genetics and Department of Biology, Pennsylvania State University
Protamines are small, highly basic DNA-binding proteins found in the sperm of animals. Interestingly, the proportion of arginine residues in one type of protamine, protamine P1, is about 50% in mammals. Upon closer examination, it was found that both the total number of amino acids and the positions of arginine residues have changed considerably during the course of mammalian evolution. This evolutionary pattern suggests that protamine P1 is under an unusual form of purifying selection, in which the high proportion of arginine residues is maintained but the positions may vary. In this case, we would expect that the rate of nonsynonymous substitution is not particularly low compared with that of synonymous substitution, despite purifying selection. We would also expect that the selection for a high arginine content results in a high frequency of the nucleotide G in the coding region of this gene, because all six arginine codons contain at least one G. These expectations were confirmed in our study of mammalian protamine genes. Analysis of nonmammalian vertebrate genes also showed essentially the same patterns of evolutionary changes, suggesting that this unusual form of purifying selection has been active since the origin of bony vertebrates. The protamine gene of an insect species shows similar patterns, although its purifying selection is less intense. These observations suggest that arginine-rich selection is a general feature of protamine evolution. The driving force for arginine-rich selection appears to be the DNA-binding function of protamine P1 and an interaction with a protein kinase in the fertilized egg.
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