Dynamic Gill and Mucous Microbiomes Track an Amoebic Gill Disease Episode in Farmed Atlantic Salmon

Birlanga, Victor Blasco; McCormack, Grace P.; Ijaz, Umer Zeeshan; McCarthy, Eugene J.; Smith, Cindy J.; Collins, Gavin

doi:10.21203/rs.3.rs-29747/v1

Cited by 2 publications

(1 citation statement)

References 35 publications

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“…The physical action of the polycarbonate filter likely helps to dislodge resident bacteria while maintaining the gill structure below. Sonification has been suggested by Birlanga et al ( 34 ) to assist with this delicate balance; however, the simplicity of using a filter membrane provides several benefits regarding welfare and repeatability. Importantly, results appeared to be robust between the aquatic environments of freshwater (i.e., rainbow trout), brackish water (i.e., gray mullet and tilapia), and salt water (Atlantic salmon), in both cold (rainbow trout and Atlantic salmon) and hot (gray mullet and tilapia) environments, as seen via the clustering-of-samples technique using PCoA.…”

Section: Discussionmentioning

confidence: 99%

Optimization of Low-Biomass Sample Collection and Quantitative PCR-Based Titration Impact 16S rRNA Microbiome Resolution

et al. 2022

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The interaction between the fish gill and surrounding bacteria-rich water provides an intriguing model for examining the interaction between the fish, free-floating bacteria, and the bacterial microbiome on the gill surface. Samples that are inherently low in bacteria, or that have components that inhibit the ability to produce libraries that identify the components of microbial communities, present significant challenges.

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Section: Discussionmentioning

confidence: 99%

Optimization of Low-Biomass Sample Collection and Quantitative PCR-Based Titration Impact 16S rRNA Microbiome Resolution

et al. 2022

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Hatchery type influences the gill microbiome of Atlantic farmed salmon (Salmo salar) after transfer to sea

Katchkin-Stewart,

Boerlage,

Barr

et al. 2024

Preprint

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Background Salmon aquaculture involves freshwater and seawater phases. Recently there has been an increase in multifactorial gill health challenges during the seawater phase which has led to an urgent need to understand the gill microbiome. There is a lack of understanding on what drives the composition of the gill microbiome, and the influence the freshwater stage has on its long-term composition. We characterise the gill microbiome from seven cohorts of Atlantic salmon raised in six different freshwater operational systems - recirculating aquaculture system (RAS), flowthrough (FT) and loch-based system, prior to and after transfer to seven seawater farms, over two different input seasons, S0 (2018) and S1 (2019). Results Using the V1-V2 region of the 16S rRNA gene, we produced amplicon libraries absent of host contamination. We show that hatchery system influenced the gill microbiome (PERMAOVA R2 = 0.226, P < 0.001). Loch and FT systems were more similar to each other than the three RAS systems, which clustered together. On transfer to sea, the gill microbiomes of all fish changed and became more similar irrespective of initial hatchery system, seawater farm location or season of input. Even though the gill microbiome among seawater farm locations was different between locations (PERMAOVA R2 = 0.528, P < 0.001), a clustering of the gill microbiomes by hatchery system of origin was still observed soon after transfer (PERMAOVA R = 0.164, P < 0.001). Core microbiomes were found between all salmon, hatcheries and seawater groups at a genus level, and at ASV level among FT and loch systems; and again among all seawater farms. The gill microbiome and surrounding water at each hatchery had more shared ASVs than seawater farms. Conclusion We show that hatchery system, loch, FT or RAS, significantly impacts the gill microbiome. On transfer to sea, the microbiomes change and become more similar. After transfer, the individual sites to which the fish are transferred become a significant driver, while a signature from the hatchery operation system remains. Future gill disease mitigation methods that target enhancing the gill microbiome may be most effective in the freshwater stage, as there were more shared ASVs between water and gill at hatchery, compared to at sea.

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Dynamic Gill and Mucous Microbiomes Track an Amoebic Gill Disease Episode in Farmed Atlantic Salmon

Cited by 2 publications

References 35 publications

Optimization of Low-Biomass Sample Collection and Quantitative PCR-Based Titration Impact 16S rRNA Microbiome Resolution

Optimization of Low-Biomass Sample Collection and Quantitative PCR-Based Titration Impact 16S rRNA Microbiome Resolution

Hatchery type influences the gill microbiome of Atlantic farmed salmon (Salmo salar) after transfer to sea

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