Diversifying Selection of the Tumor-Growth Promoter Angiogenin in Primate Evolution

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Molecular Biology and Evolution 19:438-445 (2002)
© 2002 Society for Molecular Biology and Evolution

Diversifying Selection of the Tumor-Growth Promoter Angiogenin in Primate Evolution

Jianzhi Zhang¹ and Helene F. Rosenberg

Laboratory of Host Defenses, National Institute of Allergy and Infectious Diseases, National Institutes of Health

Diversifying selection drives the rapid differentiation of genesequences and is one of the main forces behind adaptive evolution.Most genes known to be shaped by diversifying selection arethose involved in host-pathogen or male-female interactionscharacterized as molecular "arms races." Here we report theunexpected detection of diversifying selection in the evolutionof a tumor-growth promoter, angiogenin (ANG). A comparison among11 primate species demonstrates that ANG has a significantlyhigher rate of nucleotide substitution at nonsynonymous sitesthan at synonymous sites, a hallmark of positive selection actingat the molecular level. Furthermore, we observed significantcharge diversity at the molecular surface, suggesting the presenceof selective pressures in the microenvironment of ANG, includingits binding molecules. A population survey of ANG in chimpanzees,however, reveals no polymorphism, which may have resulted froma recent selective sweep of a charge-altering substitution inchimpanzee evolution. Functional assays of recombinant ANGsfrom the human and owl monkey indicate that primate ANGs retainangiogenic activity despite rapid evolution. Our study, togetherwith findings of similar selection in the primate breast cancersuppressor gene, BRCA1, reveals an intriguing phenomenon ofunusual selective pressures on, and adaptive evolution of, cancer-relatedgenes in primate evolution.

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