Abstract
Globally, parasites are increasingly being recognized as catastrophic agents in both aquaculture sector and in the wild aquatic habitats leading to an estimated annual loss between 1.05 billion and 9.58 billion USD. The currently available therapeutic and control measures are accompanied by many limitations. Hence, vaccines are recommended as the “only green and effective solution” to address these concerns and protect fish from pathogens. However, vaccine development warrants a better understanding of host–parasite interaction and parasite biology. Currently, only one commercial parasite vaccine is available against the ectoparasite sea lice. Additionally, only a few trials have reported potential vaccine candidates against endoparasites. Transcriptome, genome, and proteomic data at present are available only for a limited number of aquatic parasites. Omics-based interventions can be significant in the identification of suitable vaccine candidates, finally leading to the development of multivalent vaccines for significant protection against parasitic infections in fish. The present review highlights the progress in the immunobiology of pathogenic parasites and the prospects of vaccine development. Finally, an approach for developing a multivalent vaccine for parasitic diseases is presented. Data sources to prepare this review included Pubmed, google scholar, official reports, and websites.
Highlights
Aquaculture continues to be one of the rapid food-producing sectors worldwide.According to an estimate, the latest global aquaculture production was 82 million tons and valued at 250 billion United States dollars (USD) in 2018 [1]
Some progress has been made in understanding the immune response in fish against parasitic diseases
Studies on the immune response generated by parasites during infection and postimmunization, report the involvement of toll-like receptors (TLRs), phagocytes, complement proteins, melanomacrophage centers, proteases, and cytokines
Summary
Aquaculture continues to be one of the rapid food-producing sectors worldwide. According to an estimate, the latest global aquaculture production was 82 million tons and valued at 250 billion USD in 2018 [1]. A study highlighted the use of urea and light-based traps for controlling the infection by Cryptocaryon irritans and Neobenedenia girellae in aquaculture [15]. The genomic analysis provides abundant information on individual genes, chromosomes, their organization, genetic variants of diseases as well as evolutionary relationships with other phyla and parasites. Genomics does not provide information on aspects such as gene expression, function and regulation, and structure and characteristics of encoded proteins [20]. These limitations have resulted in the advent of the post-genomic era primarily dominated by transcriptomics and proteomics.
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