The rising bacterial infections threaten world aquaculture and wild fish populations, making it imperative to increase the understanding of the mechanisms of pathogenic virulence and resistance. This study applies comparative genomic analysis to 21 bacterial fish pathogens, using whole-genome sequences from public genomic resources and sophisticated bioinformatics tools for screening of virulence factors, mobile genetic elements, antibiotic resistance genes, anti-phage defense mechanisms and secretory systems. We have seen that the different pathogens depict a wide range of variability regarding virulence and resistance potential, which may be attributed to species-specific adaptation. Notably, Streptococcus agalactiae and Mycobacterium salmoniphilum were found to possess high offensive and defensive virulence potential, but at different regulative controls. We also found diverse secretion systems and intricate mechanisms for antibiotic resistance, which have provided very important insights into how pathogens adapt to their environments. By categorizing functional genes and finding anti-phage systems, our analysis has revealed new insights into the complex interactions among bacterial virulence, resistance, and host defense mechanisms. These findings not only shed new light on the bacterial pathogenesis process in aquaculture but also provide the bases for focused, therapeutically-based strategies and genomic surveillance programs able to improve disease management and sustainability in aquaculture environments.
Read full abstract