Expression and genomic organization of zonadhesin-like genes in three species of fish give insight into the evolutionary history of a mosaic protein.

BACKGROUND: The mosaic sperm protein zonadhesin (ZAN) has been characterized in mammals and is implicated in species-specific egg-sperm binding interactions. The genomic structure and testes-specific expression of zonadhesin is known for many mammalian species. All zonadhesin genes characterized to date consist of meprin A5 antigen receptor tyrosine phosphatase mu (MAM) domains, mucin tandem repeats, and von Willebrand (VWD) adhesion domains. Here we investigate the genomic structure and expression of zonadhesin-like genes in three species of fish. RESULTS: The cDNA and corresponding genomic locus of a zonadhesin-like gene (zlg) in Atlantic salmon (Salmo salar) were sequenced. Zlg is similar in adhesion domain content to mammalian zonadhesin; however, the domain order is altered. Analysis of puffer fish (Takifugu rubripes) and zebrafish (Danio rerio) sequence data identified zonadhesin (zan) genes that share the same domain order, content, and a conserved syntenic relationship with mammalian zonadhesin. A zonadhesin-like gene in D. rerio was also identified. Unlike mammalian zonadhesin, D. rerio zan and S. salar zlg were expressed in the gut and not in the testes. CONCLUSION: We characterized likely orthologs of zonadhesin in both T. rubripes and D. rerio and uncovered zonadhesin-like genes in S. salar and D. rerio. Each of these genes contains MAM, mucin, and VWD domains. While these domains are associated with several proteins that show prominent gut expression, their combination is unique to zonadhesin and zonadhesin-like genes in vertebrates. The expression patterns of fish zonadhesin and zonadhesin-like genes suggest that the reproductive role of zonadhesin evolved later in the mammalian lineage.

Midline serotonergic neurones contribute to widespread synchronized activity in embryonic mouse hindbrain.

Spontaneous, synchronous activity occurs in motor neurones of the embryonic mouse hindbrain at the stage when rhombomeric segmentation disappears (embryonic day 11.5). The mechanisms generating and synchronizing the activity, however, and the extent to which it is widespread in the hindbrain, are unknown. We show here that spontaneous activity is initiated in the midline of the hindbrain, and propagates laterally to encompass virtually the entire hindbrain synchronously and bilaterally. Separation of the midline region from lateral regions abolishes or slows activity laterally, but not medially. The early differentiating neurones of the midline raphe system are present in the rostral midline and express serotonin at E11.5. Their axons ramify extensively in the marginal zone, cross the midline, and extend at the midline both rostrally into the midbrain and caudally towards the caudal hindbrain. Blockers of serotonin receptors, specifically the 5-HT(2A) receptor, abolish synchronous activity in the hindbrain, while blockers of other neurotransmitter systems, including GABA and glutamate, do not. In addition, the 5-HT(2A) receptor is expressed in the marginal regions in the entire medial-to-lateral extent of the hindbrain and in the midline commissural region. Thus, the serotonergic neurones of the developing midline raphe system may play a role in initiating and propagating spontaneous synchronous activity throughout the hindbrain.