Genome-wide analysis and characterization of HSP gene families (HSP20, HSP40, HSP60, HSP70, HSP90) in the yellow fever mosquito (Aedes aegypti) (Diptera: Culicidae)

The heat shock protein (HSP) gene families, present across prokaryotes to eukaryotes, play vital roles in growth, development, and heat resistance processes. While HSP proteins have been identified and characterized in various species, this study achieved the first genome-wide identification and characterization of HSP proteins in the Aedes aegypti genome. This study identified and assessed 80 potential HSP genes in Ae. aegypti. The phylogenetic relationships of HSP genes were investigated in Ae. aegypti, Anopheles stephensi, and Drosophila melanogaster. Additionally, the structural features, chromosomal locations, protein characteristics, 3D structure, protein-protein interactions, and microsatellites associated with HSP proteins were examined in Ae. aegypti. The phylogenetic analysis of HSP gene families revealed distinct intra-group relationships for each HSP group. Each family exhibited relatively conserved genetic structures and motif components. In the expression analysis of growth and development, high expression was observed in certain HSP20 and HSP70 genes, while others exhibited low expression. Notably, sex-dependent expression differences were observed, particularly in HSP20 genes. These findings, the relationships, evolution, and modification of HSP gene families are illuminated by these comprehensive findings, and a better understanding of the mechanisms underlying growth, development, and heat resistance in vector organisms is facilitated.

Automated summary

This study identified and characterized HSP proteins in the Aedes aegypti genome for the first time, revealing 80 potential HSP genes. Phylogenetic analysis showed distinct relationships within each HSP group, with conserved genetic structures and motifs. Expression analysis revealed high expression of certain HSP20 and HSP70 genes, with sex-dependent expression differences observed, particularly in HSP20 genes.