Alcohol dehydrogenase isozymes in the clawed frog, Xenopus laevis

The Xenopus alcohol dehydrogenase gene family: characterization and comparative analysis incorporating amphibian and reptilian genomes

Background

The alcohol dehydrogenase (ADH) gene family uniquely illustrates the concept of enzymogenesis. In vertebrates, tandem duplications gave rise to a multiplicity of forms that have been classified in eight enzyme classes, according to primary structure and function. Some of these classes appear to be exclusive of particular organisms, such as the frog ADH8, a unique NADP⁺-dependent ADH enzyme. This work describes the ADH system of Xenopus, as a model organism, and explores the first amphibian and reptilian genomes released in order to contribute towards a better knowledge of the vertebrate ADH gene family.

Results

Xenopus cDNA and genomic sequences along with expressed sequence tags (ESTs) were used in phylogenetic analyses and structure-function correlations of amphibian ADHs. Novel ADH sequences identified in the genomes of Anolis carolinensis (anole lizard) and Pelodiscus sinensis (turtle) were also included in these studies. Tissue and stage-specific libraries provided expression data, which has been supported by mRNA detection in Xenopus laevis tissues and regulatory elements in promoter regions. Exon-intron boundaries, position and orientation of ADH genes were deduced from the amphibian and reptilian genome assemblies, thus revealing syntenic regions and gene rearrangements with respect to the human genome. Our results reveal the high complexity of the ADH system in amphibians, with eleven genes, coding for seven enzyme classes in Xenopus tropicalis. Frogs possess the amphibian-specific ADH8 and the novel ADH1-derived forms ADH9 and ADH10. In addition, they exhibit ADH1, ADH2, ADH3 and ADH7, also present in reptiles and birds. Class-specific signatures have been assigned to ADH7, and ancestral ADH2 is predicted to be a mixed-class as the ostrich enzyme, structurally close to mammalian ADH2 but with class-I kinetic properties. Remarkably, many ADH1 and ADH7 forms are observed in the lizard, probably due to lineage-specific duplications. ADH4 is not present in amphibians and reptiles.

Conclusions

The study of the ancient forms of ADH2 and ADH7 sheds new light on the evolution of the vertebrate ADH system, whereas the special features showed by the novel forms point to the acquisition of new functions following the ADH gene family expansion which occurred in amphibians.

Alcohol dehydrogenases in Xenopus development: conserved expression of ADH1 and ADH4 in epithelial retinoid target tissues

Mammalian alcohol dehydrogenases ADH1 (class I ADH) and ADH4 (class IV ADH) function as retinol dehydrogenases contributing to the synthesis of retinoic acid, the active form of vitamin A involved in growth and development. Xenopus laevis ADH1 and ADH4 genes were isolated using polymerase chain reaction primers corresponding to conserved motifs of vertebrate ADHs. The predicted amino acid sequence of Xenopus ADH1 was clearly found to be an ortholog of ADH1 from the related amphibian Rana perezi. Phylogenetic tree analysis of the Xenopus ADH4 sequence suggested this enzyme is likely to be an ADH4 ortholog, and this classification was more confidently made when based also on the unique expression patterns of Xenopus ADH1 and ADH4 in several retinoid-responsive epithelial tissues. Northern blot analysis of Xenopus adult tissues indicated nonoverlapping patterns of ADH expression, with ADH1 mRNA found in small intestine, large intestine, liver, and mesonephros and ADH4 mRNA found in esophagus, stomach, and skin. These nonoverlapping tissue-specific patterns are identical to those previously observed for mouse ADH1 and ADH4, thus providing further evidence that Xenopus ADH1 and ADH4 are orthologs of mouse ADH1 and ADH4, respectively. During Xenopus embryonic development ADH1 mRNA was first detectable by Northern blot analysis at stage 35, whereas ADH4 mRNA was undetectable through stage 47. Whole-mount in situ hybridization indicated that ADH1 expression was first localized in the pronephros during Xenopus embryogenesis, thus conserved with mouse embryonic ADH1 which is first expressed in the mesonephros. ADH4 expression was not detected in Xenopus embryos by whole-mount in situ hybridization but was localized to the gastric mucosa of the adult stomach, a property shared by mouse ADH4. Conserved expression of ADH1 and ADH4 in retinoid-responsive epithelial tissues of amphibians and mammals argue that these enzymes may perform essential retinoid signaling functions during development of the pronephros, mesonephros, liver, and lower digestive tract in the case of ADH1 and in the skin and upper digestive tract in the case of ADH4.