Full-length transcriptome sequences of ridgetail white prawn Exopalaemon carinicauda provide insight into gene expression dynamics during thermal stress

Abstract

Marine heat waves and extreme high temperature become more frequent and intense in these years, which affected the survival of aquaculture animals. The ridgetail white prawn Exopalaemon carinicauda is an important economic species in eastern China, which has remarkable thermal tolerance. However, there has been little study of its thermal-adaptation mechanisms due to the complex genetic structure and unknown genome. To better understand the molecular mechanisms of E. carinicauda to adapt to the changing temperature, a combination of Illumina-based short reads RNA-seq and single molecule real-time-based full-length transcriptome sequencing was used in this study. In total, 17,212 unigenes from high-quality transcripts of E. carinicauda were generated and 14,663 complete ORFs were detected with an average length of 1980 bp. In addition, the transcriptome profiles of E. carinicauda treated with 34 °C heat stress for 6 and 24 h were analyzed. These differentially expressed genes were primarily enriched in oxidation-reduction process (Gene Ontology enrichment, GO) and the pathways of starch and sucrose metabolism (Kyoto Encyclopedia of Genes and Genomes enrichment, KEGG) after 6 h thermal stress, which indicated that E. carinicauda was suffering the attack by reactive oxygen species. After 24 h thermal stress, these differentially expressed genes were enriched in the pathway of lysosome, glycine, serine and threonine metabolism, fatty acid metabolism (KEGG), which indicated the oxidative stress was decreased. Interestingly, 40 genes for hemocyanin were found to be downregulated after 6 h heat stress, which indicated that the immunocompetence of E. carinicauda decreased after short term thermal stress (6 h). After 24 h thermal stress, E. carinicauda showed transcriptional adaptation to high temperature by upregulating of 11 genes encoding molecular chaperones, including HSP40 and HSP90 which were firstly reported to be related to thermal stress in E. carinicauda. These results promote a better understanding of the thermal-adaptation mechanism of E. carinicauda.

Keywords: Differential expression genes; Exopalaemon carinicauda; Full-length transcriptome; Heat shock protein; Marine heat wave; Thermal adaptation.