Current risks of microbial infections in fish and their prevention methods: A review

Dayana Senthamarai, Murugeswaran; Rajan, Muthuswami Ruby; Bharathi, Palanichamy Vidhya

doi:10.1016/j.micpath.2023.106400

Cited by 11 publications

(4 citation statements)

References 64 publications

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“…As most of the effect sizes for bacteria were calculated from aquatic hosts, our results suggest that bacterial pathogens might pose significant greater risk under warming, to aquatic hosts such as fishes. Increased disease outbreaks for aquatic animals, especially fishes, has been an overwhelming issue for the aquaculture industry, causing considerable economic damage and threats to human health [45]. Bacterial diseases are common in aquaculture, we suggest that future disease management should also consider the aggravating effects of warming on the severity of epidemics.…”

Section: Resultsmentioning

confidence: 99%

Warming-induced excess deaths of infected animals depend on pathogen kingdom and evolutionary history

Li,

Guttmann,

Drew

et al. 2024

Preprint

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Climate change is causing extreme heating events. Simultaneously, climate change and human activities are leading to more prolonged and intense infectious disease outbreaks. The extent to which warming and infection may together impact host species persistence is, however, unclear. Using a meta-analysis of >190 effect sizes representing 101 ectothermic animal host-pathogen systems, we provide broad evidence that experimentally increased temperatures drove higher pathogen virulence, specifically pathogen-induced host mortality. Such pattern was mainly driven by excess host death caused by bacterial infections combined with warming, particularly if the pathogenic bacteria were naturally established within the host species, though novel infections without known host-pathogen evolutionary history were more lethal at lower temperatures. Importantly, larger temperature increases were associated with more host deaths hinting at the escalating threat for animal species as the world continues to warm. We found that the virulence of fungal pathogens increased only when temperatures were shifted upwards towards their thermal optimum. The magnitude of these effects was not impacted by host life-stage, immune complexity, or variable experimental protocols. Overall, our findings reveal distinct patterns of pathogen virulence change under warmer temperatures, suggesting that the impact of global warming on infectious disease outcomes would depend on pathogen traits (taxonomic kingdom, thermal tolerance) and host-pathogen evolutionary history.

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Section: Resultsmentioning

confidence: 99%

Warming-induced excess deaths of infected animals depend on pathogen kingdom and evolutionary history

Li,

Guttmann,

Drew

et al. 2024

Preprint

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“…They can be used to prevent bacterial infections in fish and other aquatic animals. At present, bacterial vaccines such as those targeting A. salmonicida, V. anguillarum, and Y. ruckeri are being utilized, with preparations underway for the vaccination against viral diseases [137]. They can be administered through injection or through the feed.…”

Section: Alternatives To Antimicrobial Treatment In Aquaculturementioning

confidence: 99%

“…By using alternatives to antimicrobials, aquaculture producers can help to reduce the risk of AMR and promote the health of fish and other aquatic animals. It is recommended to plan strategies for AMR prevention and control in accordance with internationally recognized frameworks and locally available solutions [137] and use these alternatives to prevent the occurrence of aquatic animals` illnesses and reduce the use of antimicrobials.…”

Section: Alternatives To Antimicrobial Treatment In Aquaculturementioning

confidence: 99%

Antimicrobial Resistance in Aquaculture: Risk Mitigation within One Health Context

Milijasevic,

Veskovic-Moracanin,

Babic Milijasevic

et al. 2024

Preprint

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The application of antimicrobials in aquaculture primarily aims to prevent and treat bacterial infections in fish. Inappropriate use of antimicrobials in fish farming may result in the emergence of zoonotic antibiotic-resistant bacteria and subsequent transmission of resistant strains to humans via food consumption. From recently, AMR emerged as a significant public health concern in the aquaculture ecosystem and fisheries. The aquatic environment serves as a potential reservoir for resistant bacteria, with aquaculture practices providing an ideal breeding ground for AMR due to the excessive use of antimicrobials to prevent and treat diseases. The mutual inter-connection of intensive fish farming systems with terrestrial environments, food processing industry and human population creates pathways for the transmission of resistant bacteria, exacerbating the problem further. One Health concept, which recognizes the interconnectedness of human, animal and environmental health, enables a holistic approach to address the challenges posed by AMR. By understanding the evolution of such approach, the future of aquaculture, being the important source of a global animal protein supply, can be safeguarded. Risk mitigation strategies for AMR should be based on One Health concept to contribute to sustainable aquaculture practices that protect human and animal health, ensure food safety and protection of environment.

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“…A key aspect of infectious diseases in fish farming is which preventive approaches should be prioritized to effectively block the emergence of disease outbreaks and the emergence of new pathogens or pathogen genotypes with high virulence (or with no crossprotection of available vaccines). Due to the wide range of infectious agents (different types of bacteria/genotypes, viruses, fungi, and protozoa), there are many knowledge gaps to be filled, such as import barriers between countries or production regions of live fish [16], the standardization of diagnosis methods that can detect fish in chronic stage of infection (or asymptomatic carriers), the monitoring of wild fish as sentinel animals/reservoirs to understand the risk of new emerging pathogens in farmed fish, especially in large water reservoirs located between the borders of countries with different stringency of sanitary programs [17], pathogenesis studies to better understand which tissues show high risk factors in fish imported as food, biosecurity plans within each country and fish farms, including basic protocols for fingerling or juvenile supplier, environmental and feed quality, cleaning and disinfection protocols, and new well-tested immunoprophylaxis products (commercial and/or autogenous vaccines) [18][19][20].…”

mentioning

confidence: 99%

Fish Pathogens: Infection and Biological Control

da Costa,

de Carvalho Azevedo

et al. 2023

Fishes

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Current risks of microbial infections in fish and their prevention methods: A review

Cited by 11 publications

References 64 publications

Warming-induced excess deaths of infected animals depend on pathogen kingdom and evolutionary history

Warming-induced excess deaths of infected animals depend on pathogen kingdom and evolutionary history

Antimicrobial Resistance in Aquaculture: Risk Mitigation within One Health Context

Fish Pathogens: Infection and Biological Control

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