Dynamic Changes in Pigmentation-Related Gene Expression During Morphogenesis in Plectropomus Leopardus Revealed by Comparative Transcriptome Analysis

Plectropomus leopardus is a valuable marine aquaculture fish, prized by consumers for its high nutritional value and gorgeous appearance. The economic significance of this species is largely influenced by its body color, prompting researchers to become increasingly interested in understanding the mechanisms behind its color formation. However, previous studies have mainly focused on the molecular mechanisms of body color formation during the adult stage of this species. In this study, it was observed that the body color of P. leopardus undergoes four distinct stages during early morphogenesis: transparent (PT), red (PR), red with spots (PRS), and brown with spots (PBS). The L*a*b* values of skin at each stage differ significantly. The number and distribution of erythrophores and melanophores play a crucial role in determining the body colors of P. leopardus. Transcriptome analysis of the skin at these stages revealed multiple differentially expressed genes (DEGs) and signaling pathways related to pigmentation. These pigmentation-related DEGs can be categorized into carotenoid metabolism-related genes (e.g., scarb1, ldlr, plin2, apod, ttc39b, etc), melanin synthesis-related genes (e.g., tyr, tyrp1, dct, pmel, slc7a11, etc), and genes related to pigment cell development (pnp, ednrb, csf1r1, sox10, bnc2). GO and KEGG enrichment analysis indicated that processes like melanin synthesis (e.g., wnt signal pathway, melanogenesis, tyrosine metabolism, etc.), lipid metabolism (e.g., cholesterol metabolism, linoleic acid metabolism, arachidonic metabolism, fatty acid biosynthesis, etc.), and pigment cell development (e.g., pigment cell differentiation, cell development, etc.) are likely involved in the body color formation in P. leopardus. Finally, we proposed a hypothesis regarding carotenoid metabolism in erythrophores and melanin synthesis in melanophores of P. leopardus skin, drawing from existing research reports and transcriptome data. Overall, this study provides a new perspective on the molecular regulatory mechanisms of body color formation in P. leopardus, laying a theoretical foundation for molecular-assisted breeding of body color traits in this species.