Molecular Evolution of the Nontandemly Repeated Genes of the Histone 3 Multigene Family

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Molecular Biology and Evolution 19:68-75 (2002)
© 2002 Society for Molecular Biology and Evolution

Molecular Evolution of the Nontandemly Repeated Genes of the Histone 3 Multigene Family

Alejandro P. Rooney, Helen Piontkivska and Masatoshi Nei

Department of Biological Sciences, Mississippi State University, Mississippi State;
Institute of Molecular Evolutionary Genetics and Department of Biology, The Pennsylvania State University, University Park

In some species, histone gene clusters consist of tandem arraysof each type of histone gene, whereas in other species the genesmay be clustered but not arranged in tandem. In certain species,however, histone genes are found scattered across several differentchromosomes. This study examines the evolution of histone 3(H3) genes that are not arranged in large clusters of tandemrepeats. Although H3 amino acid sequences are highly conservedboth within and between species, we found that the nucleotidesequence divergence at synonymous sites is high, indicatingthat purifying selection is the major force for maintainingH3 amino acid sequence homogeneity over long-term evolution.In cases where synonymous-site divergence was low, recent geneduplication appeared to be a better explanation than gene conversion.These results, and other observations on gene inactivation,organization, and phylogeny, indicated that these H3 genes evolveaccording to a birth-and-death process under strong purifyingselection. Thus, we found little evidence to support previousclaims that all H3 proteins, regardless of their genome organization,undergo concerted evolution. Further analyses of the structureof H3 proteins revealed that the histones of higher eukaryotesmight have evolved from a replication-independent–likeH3 gene.

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