Abstract

Aquaculture, as a rapidly growing industry, plays a significant role in global food production and economic development. However, various infectious diseases, particularly those caused by the gram-negative bacterium Aeromonas hydrophila, pose a critical threat to the sustainability and productivity of world-wide aquaculture operations. Investigating the molecular mechanisms of A. hydrophila infection can help to identify key targets for therapeutic interventions and vaccines, thereby reducing economic losses associated with disease outbreaks. Our present study focuses on wide-bodied sand loach (WBSL, Sinibotia reevesae), a captive-bred commercial fish, to explore detailed molecular effects of exogenous A. hydrophila infection. Firstly, a high-quality chromosome-level haplotype genome with a total length of 774 Mb and 49 chromosomes was assembled, providing valuable insights into its genetic components. Secondly, we isolated and characterized a newfound A. hydrophila F4S strain, examined pathological symptoms of WBSL after infection, and then investigated dynamic gene expressions. Our results revealed that the bacterial infection decreased metabolic activity, causing disruptions in cardiac function, cellular homeostasis, tissue damages, and impaired energy utilization. The immune system responds multifaceted, potentially impacting overall health and survival. In summary, our findings contribute to the understanding of the complicated interactions between WBSL and exogenous A. hydrophila, especially shed lights on the genetic complexity, immune responses, and potential impacts on fish health and survival. Furthermore, this study provides new insights into the mechanisms underlying A. hydrophila infection, and offers potential strategies to offload corresponding pathological effects, not only in WBSL but also in other aquaculture species.

Full Text
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