Abstract
UDP-glucuronosyltransferases (Ugts) are a supergene family of phase II drug-metabolizing enzymes that catalyze the conjugation of numerous hydrophobic small molecules with the UDP-glucuronic acid, converting them into hydrophilic molecules. Here, we report the identification and cloning of the complete zebrafish Ugt gene repertoire. We found that the zebrafish genome contains 45 Ugt genes that can be divided into three families: Ugt1, Ugt2, and Ugt5. Both Ugt1 and Ugt2 have two unlinked clusters: a and b. The Ugt1a, Ugt1b, Ugt2a, and Ugt2b clusters each contain variable and constant regions, similar to that of the protocadherin (Pcdh), immunoglobulin (Ig), and T-cell receptor (Tcr) clusters. Cloning the full-length coding sequences confirmed that each of the variable exons is separately spliced to the set of constant exons within each zebrafish Ugt cluster. Comparative analyses showed that both a and b clusters of the zebrafish Ugt1 and Ugt2 genes have orthologs in other teleosts, suggesting that they may be resulted from the “fish-specific” whole-genome duplication event. The Ugt5 genes are a novel family of Ugt genes that exist in teleosts and amphibians. Their entire open reading frames are encoded by single large exons. The zebrafish Ugt1, Ugt2, and Ugt5 genes can generate additional transcript diversity through alternative splicing. Based on phylogenetic analyses, we propose that the ancestral tetrapod and teleost Ugt1 clusters contained multiple Ugt1 paralogs. After speciation, these ancestral Ugt1 clusters underwent lineage-specific gene loss and duplication. The ancestral vertebrate Ugt2 cluster also underwent lineage-specific duplication. The intronless Ugt5 open reading frames may be derived from retrotransposition followed by gene duplication. They have been expanded dramatically in teleosts and have become the most abundant Ugt family in these lineages. These findings have interesting implications regarding the molecular evolution of genes with diversified variable exons in vertebrates.
Highlights
Natural selection plays an essential role in the evolution of vertebrate genomes
We identified 45 zebrafish Ugt genes through a combination of iterative BLAST searches of genomic sequences with comprehensive cloning of Ugt cDNA sequences (Tables S1 and S2)
These genes constitute the complete repertoire of zebrafish Ugt genes (Fig. 1)
Summary
Natural selection plays an essential role in the evolution of vertebrate genomes. At the molecular level, DNA duplication provides important genetic materials upon which Darwinian positive selection can act. Vertebrate genomes contain a unique set of gene clusters that are organized into variable and constant regions. These gene clusters include the immunoglobulin (Ig), Tcell receptor (Tcr), Protocadherin (Pcdh), and UDP-glucuronosyltransferase (Ugt) genes [1]. Their variable region contains a tandem array of highly similar exons which are of about the same length. Each of the variable exons is combined with a single set of downstream constant exons to generate enormous molecular diversity required for the survival of the organisms. Alternative splicing, gene conversion, and adaptive selection of the Pcdh clusters generate enormous diversity for the construction of trillions of specific neuronal connectivity in the central nervous system [4,5,6,7]
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