Molecular Evolutionary Analysis of the HCRTR Gene Family in Vertebrates.

Hypocretin system is composed of hypocretins (hcrts) and their receptors (hcrtrs), which has multiple vital functions. Hypocretins work via hypocretin receptors and it is reported that functional differentiation occurred in hcrtrs. It is necessary to figure out the evolution process of hypocretin receptors. In our study, we adopt a comprehensive approach and various bioinformatics tools to analyse the evolution process of HCRTR gene family. It turns out that the second round of whole genome duplication in early vertebrate ancestry and the independent round in fish ancestry may contribute to the diversity of HCRTR gene family. HCRTR1 of fishes and mammals are not the same receptor, which means that there are three members in the family. HCRTR2 is proved to be the most ancient one in HCRTR gene family. After duplication events, the structure of HCRTR1 diverged from HCRTR2 owing to relaxed selective pressure. Negative selection is the predominant evolutionary force acting on the HCRTR gene family but HCRTR1 of mammals is found to be subjected to positive selection. Our study gains insight into the molecular evolution process of HCRTR gene family, which contributes to the further study of the system.

Transcriptome reveals B lymphocyte apoptosis in duck embryonic bursa of Fabricius mediated by mitochondrial and Fas signaling pathways.

As a central immune organ unique to birds, the bursa of Fabricius (BF) provides a proper microenvironment for B-cell development. The bursal B-cells undergo rapid proliferation and differentiation at the embryonic stages, but 95% of them undergo apoptosis after hatching. Few studies have focused on the cause of bursal B-cells apoptosis at the embryonic stages in birds. To explore the cause, we compared the transcriptional profiles of three characteristic embryonic stages in duck, including embryonic day 14 (ED14), 22 (ED22) and 1 day after hatching (D1). Our results showed that the apoptotic B-cells were first observed at ED22 while there were no apoptotic B-cells at ED14. By performing enrichment analysis for DEGs and qRT-PCR, our results demonstrated that both mitochondrial and Fas signaling pathways mediated bursal B-cell apoptosis during the duck embryonic development. Further, protein-protein interactions (PPIs) and KEGG enrichment analysis together showed that BMP4, FoxO1 and IGF-1 may regulate bursal B-cells apoptosis. In addition, the DEGs showed two stage-specific expression patterns. By analyzing the genes of two expression patterns, the results indicated that B-cell false differentiation may be one of the reasons of apoptosis in the duck embryonic BF. Overall, these data demonstrated that from ED14-ED22, apoptosis of bursal B-cells was mediated by mitochondrial and Fas signaling pathways and could be regulated by BMP4, FoxO1 and IGF-1 in duck. One of the primary causes of bursal B-cell apoptosis may be false differentiation in B-cells.