Embryonic expression and evolution of duplicated E-protein genes in Xenopus laevis: parallels with ancestral E-protein genes.

E-proteins comprise a subfamily of helix-loop-helix transcription factors that have been identified in arthropods and several chordate taxa. In mammals, there are three classes of E-protein genes (E2A, E2-2, and HEB) that encode related, and often interchangeable, gene products. We have determined that the clawed frog Xenopus laevis contains twice the number of transcriptionally active E-protein genes when compared with other vertebrate species. Based upon genomic Southern blots and nucleotide sequence comparisons, it is likely that the additional X. laevis genes arose from tetraploidization. During embryogenesis, XE2A (homologue of mammalian E2A) transcripts were broadly expressed in anterior and posterior regions of the embryo while homologues of E2-2 (XE2.2) and HEB (XE1.2) appeared in vertebrate-specific structures including the pineal gland, olfactory bulb, and brachial arches. A phylogenetic analysis of these genes and other known metazoan E-proteins suggests that there were two periods of marked E-protein gene expansion; one that predated the radiation of vertebrates, and the other that coincided with Xenopus tetraploidization. Both of these periods were characterized by the rapid evolution of E2-2 and HEB-class genes, but not of E2A. We propose that the former genes acquired new or specialized roles during early chordate evolution and also more recently in Xenopus, as reflected by the stereotypic expression patterns of these genes during X. laevis development.