Genome-wide identification and immune response analysis of serine protease inhibitor genes in the blood clam Tegillarca granosa

A Novel Kunitz-Type Serine Protease Inhibitor (HcKuSPI) is Involved in Antibacterial Defense in Innate Immunity and Participates in Shell Formation of Hyriopsis cumingii

Serine protease inhibitors (SPIs) are abundantly reported for its inhibition against specific proteases involved in the immune responses, but SPI data related to calcareous shells are scarce. Previously, our research group has reported the proteome analysis of non-nucleated pearl powder, and a candidate matrix protein containing two Kunitz domains in the acid soluble fraction caught our attention. In the present study, the full-length cDNA sequence of HcKuSPI was obtained from Hyriopsis cumingii. HcKuSPI was specifically expressed in the mantle, with hybridization signals mainly concentrated to dorsal epithelial cells at the mantle edge and weak signals at the mantle pallium, suggesting HcKuSPI was involved in shell formation. HcKuSPI expression in the mantle was upregulated after Aeromonas hydrophila and Staphylococcus aureus challenge to extrapallial fluids (EPFs). A glutathione S transferase (GST)-HcKuSPI recombinant protein showed strong inhibitory activity against the proteases, trypsin and chymotrypsin. Moreover, HcKuSPI expression in an experimental group was significantly higher when compared with a control group during pellicle growth and crystal deposition in shell regeneration processes, while the organic shell framework of newborn prisms and nacre tablets was completely destroyed after HcKuSPI RNA interference (RNAi). Therefore, HcKuSPI secreted by the mantle may effectively neutralize excess proteases and bacterial proteases in the EPF during bacterial infection and could prevent matrix protein extracellular degradation by suppressing protease proteolytic activity, thereby ensuring a smooth shell biomineralization. In addition, GST-HcKuSPI was also crucial for crystal morphology regulation. These results have important implications for our understanding of the potential roles of SPIs during shell biomineralization.

Genome-wide identification and characteristic analysis of ETS gene family in blood clam Tegillarca granosa

BACKGROUND

ETS transcription factors, known as the E26 transformation-specific factors, assume a critical role in the regulation of various vital biological processes in animals, including cell differentiation, the cell cycle, and cell apoptosis. However, their characterization in mollusks is currently lacking.

RESULTS

The current study focused on a comprehensive analysis of the ETS genes in blood clam Tegillarca granosa and other mollusk genomes. Our phylogenetic analysis revealed the absence of the SPI and ETV subfamilies in mollusks compared to humans. Additionally, several ETS genes in mollusks were found to lack the PNT domain, potentially resulting in a diminished ability of ETS proteins to bind target genes. Interestingly, the bivalve ETS1 genes exhibited significantly high expression levels during the multicellular proliferation stage and in gill tissues. Furthermore, qRT-PCR results showed that Tg-ETS-14 (ETS1) is upregulated in the high total hemocyte counts (THC) population of T. granosa, suggesting it plays a significant role in stimulating hemocyte proliferation.

CONCLUSION

Our study significantly contributes to the comprehension of the evolutionary aspects concerning the ETS gene family, while also providing valuable insights into its role in fostering hemocyte proliferation across mollusks.

Genome-Wide Analysis of Family I84 Protease Inhibitor Genes in Three Bivalves Reveals Important Information About the Protein Family's Evolution

Family I84 serine protease inhibitors are believed to be mollusk specific proteins involved in host defense. The molecular evolution of the family, however, remains to be understood. In this study, the genes of Family I84 protease inhibitors in 3 bivalves, Crassostrea gigas, Crassostrea virginica and Tegillarca granosa, were analyzed at the genomic level. A total of 66 Family I84 genes (22 in C. gigas, 28 in C. virginica and 16 in T. granosa) were identified from the 3 species. They distributed unevenly in the genomes involving 4 chromosomes in C. gigas and 5 chromosomes in C. virginica and T. granosa and some genes were tandemly duplicated. Most genes had 3 exons with 12 genes having 4 exons and 1 gene having 2 exons. All genes but 1 from C. gigas and 1 from T. granosa encoded peptides with a signal sequence at the N-terminus, and the properties of the predicted mature molecules were similar. Four conserved motifs were identified in the 66 amino acid sequences. Collinear analysis revealed higher collinearity between the 2 oyster species in general genes and in Family I84 genes. Phylogenetic analysis of the 66 genes with those previously reported from 3 other bivalves and 1 gastropod showed that Family I84 protease inhibitor genes from the same species tended to be grouped together in terminal branches of the constructed Maximum likelihood tree, but most internal nodes were poorly supported by the bootstrap values. In addition, differences in expression patterns between the genes of a same species were observed in the developmental stages and tissues of C. gigas and T. granosa. Moreover, the co-expression of genes within Family I84 and Family I84 genes with non-Family I84 were also detected in C. gigas and T. granosa. These results suggested that Family I84 protease inhibitor genes evolved by active duplications and structural and functional diversifications after the speciation of related mollusks, and the diversified protease inhibitor family was likely multifunctional.