Molecular Analysis of Bacterial Communities and Detection of Potential Pathogens in a Recirculating Aquaculture System for Scophthalmus maximus and Solea senegalensis

Patrícia Martins,Ricardo Calado,Victor Quintino,Ana C C Pires,Daniel F R Cleary,Ana Maria Rodrigues,Newton C M Gomes,Pikul Jiravanichpaisal

doi:10.1371/journal.pone.0080847

Patrícia Martins, Ricardo Calado + Show 6 more

Open Access

https://doi.org/10.1371/journal.pone.0080847

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Journal: PLoS ONE	Publication Date: Nov 21, 2013
Citations: 154	License type: CC BY 3.0

Affiliation: University of Aveiro

Abstract

The present study combined a DGGE and barcoded 16S rRNA pyrosequencing approach to assess bacterial composition in the water of a recirculating aquaculture system (RAS) with a shallow raceway system (SRS) for turbot (Scophthalmus maximus) and sole (Solea senegalensis). Barcoded pyrosequencing results were also used to determine the potential pathogen load in the RAS studied. Samples were collected from the water supply pipeline (Sup), fish production tanks (Pro), sedimentation filter (Sed), biofilter tank (Bio), and protein skimmer (Ozo; also used as an ozone reaction chamber) of twin RAS operating in parallel (one for each fish species). Our results revealed pronounced differences in bacterial community composition between turbot and sole RAS, suggesting that in the systems studied there is a strong species-specific effect on water bacterial communities. Proteobacteria was the most abundant phylum in the water supply and all RAS compartments. Other important taxonomic groups included the phylum Bacteriodetes. The saltwater supplied displayed a markedly lower richness and appeared to have very little influence on bacterial composition. The following potentially pathogenic species were detected: Photobacterium damselae in turbot (all compartments), Tenacibaculum discolor in turbot and sole (all compartments), Tenacibaculum soleae in turbot (all compartments) and sole (Pro, Sed and Bio), and Serratia marcescens in turbot (Sup, Sed, Bio and Ozo) and sole (only Sed) RAS. Despite the presence of these pathogens, no symptomatic fish were observed. Although we were able to identify potential pathogens, this approach should be employed with caution when monitoring aquaculture systems, as the required phylogenetic resolution for reliable identification of pathogens may not always be possible to achieve when employing 16S rRNA gene fragments.

Highlights

The growing worldwide demand for fish has prompted research towards intensive aquaculture
Ammonia, nitrites and nitrates were present in lower concentrations in water samples collected from the recirculating aquaculture systems (RAS) employed for sole production
In order to gain a better insight on how the bacterial communities differed between the two fish RAS and among the different compartments of each RAS, a new principal coordinates analysis (PCO) was performed (Figure 2B) excluding the samples from water supply

Summary

Introduction

The growing worldwide demand for fish has prompted research towards intensive aquaculture Innovative technologies, such as recirculating aquaculture systems (RAS) and shallow raceway systems (SRS) [1], have been developed to improve the efficiency and sustainability of intensive aquaculture practices. An in-depth analysis of these microbial communities will provide quantitative and qualitative outputs that should allow us to obtain a comprehensive definition of the 'standard' microbiome of a RAS. In turn this information can improve our ability to understand and control the microbial quality of production systems and reduce the risks associated with disease outbreak

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Conclusion