Abstract
AbstractThe globin superfamily of vertebrate genes is a textbook example of how the interplay between local gene duplications, whole-genome duplications, and regulatory changes can facilitate the evolution of novel protein functions. Almost every vertebrate examined possesses copies of hemoglobin and myoglobin in their genomes, and both cytoglobin and neuroglobin are present in the vast majority of vertebrate genomes surveyed as well. The phylogenetic distribution of globin-E, globin-Y and globin-X (GbX), however, is more spotty, suggesting multiple independent gene losses. Globin-X is an enigmatic globin with a wide phyletic distribution that spans protostomes and deuterostomes. Unlike canonical globins such as hemoglobins and myoglobins, functional data suggest that GbX does not have a primary respiratory function. Instead, available evidence suggests that GbX may play a role in protecting cells from oxidative damage and in reducing nitrite and it is predicted to be bound to the cell membrane. Recently released genomes from key vertebrate taxa provide an excellent opportunity to address questions about the early stages of evolution of these genes in vertebrates. In the current study, we integrate bioinformatic, synteny and phylogenetic analyses to characterize the diversity of GbX genes in non-teleost ray-finned fishes, resolve relationships between the GbX genes of cartilaginous fish and the GbX genes of bony vertebrates, and demonstrate that the GbX genes of cyclostomes and gnathostomes have independent duplicative histories. Our study highlights the role that whole genome duplications (WGDs) have played in expanding the repertoire of genes in vertebrate genomes. Our results indicate that GbX paralogs have a remarkably high rate of retention following WGDs in comparison to other globin genes, and also provide an evolutionary framework for interpreting results of experiments that examine functional properties of GbX and patterns of tissue-specific expression. By identifying GbX genes products of different WGDs in the vertebrate tree of life, our results can guide the design of experimental work to explore whether gene duplicates that originate via WGDs have evolved novel functional properties or expression profiles relative to singleton or tandemly duplicated copies of GbX.
Publisher
Cold Spring Harbor Laboratory