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Title

Disruption of gut integrity and permeability contributes to enteritis in a fish-parasite model: a story told from serum metabolomics

AuthorsSitjà-Bobadilla, Ariadna CSIC ORCID ; Gil-Solsona, Ruben; Estensoro, Itziar CSIC ORCID; Piazzon de Haro, María Carla ; Martos-Sitcha, Juan Antonio CSIC ORCID; Picard-Sánchez, Amparo; Fuentes, Juan; Sancho, Juan Vicente; Calduch-Giner, Josep A. CSIC ORCID; Hernández, F.; Pérez-Sánchez, Jaume CSIC ORCID
KeywordsMyxozoa
Enteromyxum leei
Gilthead sea bream
Teleostei
Aquaculture
Pathophysiology
Tight junctions
Gut barrier
Electrophysiology
Metabolomics
Issue Date16-Oct-2019
PublisherBioMed Central
CitationParasites & Vectors 12(1): 486 (2019)
Abstract[Background]:In the animal production sector, enteritis is responsible for serious economic losses, and intestinal parasitism is a major stress factor leading to malnutrition and lowered performance and animal production efficiency. The effect of enteric parasites on the gut function of teleost fish, which represent the most ancient bony vertebrates, is far from being understood. The intestinal myxozoan parasite Enteromyxum leei dwells between gut epithelial cells and causes severe enteritis in gilthead sea bream (Sparus aurata), anorexia, cachexia, growth impairment, reduced marketability and increased mortality.
[Methods]: This study aimed to outline the gut failure in this fish-parasite model using a multifaceted approach and to find and validate non-lethal serum markers of gut barrier dysfunction. Intestinal integrity was studied in parasitized and non-parasitized fish by immunohistochemistry with specific markers for cellular adhesion (E-cadherin) and tight junctions (Tjp1 and Cldn3) and by functional studies of permeability (oral administration of FITC-dextran) and electrophysiology (Ussing chambers). Serum samples from parasitized and non-parasitized fish were analyzed using non-targeted metabolomics and some significantly altered metabolites were selected to be validated using commercial kits.
[Results]: The immunodetection of Tjp1 and Cldn3 was significantly lower in the intestine of parasitized fish, while no strong differences were found in E-cadherin. Parasitized fish showed a significant increase in paracellular uptake measured by FITC-dextran detection in serum. Electrophysiology showed a decrease in transepithelial resistance in infected animals, which showed a diarrheic profile. Serum metabolomics revealed 3702 ions, from which the differential expression of 20 identified compounds significantly separated control from infected groups in multivariate analyses. Of these compounds, serum inosine (decreased) and creatine (increased) were identified as relevant and validated with commercial kits.
[Conclusions]: The results demonstrate the disruption of tight junctions and the loss of gut barrier function, a metabolomic profile of absorption dysfunction and anorexia, which further outline the pathophysiological effects of E. leei.
Description© The Author(s).
Publisher version (URL)https://doi.org/10.1186/s13071-019-3746-7
URIhttp://hdl.handle.net/10261/192946
DOI10.1186/s13071-019-3746-7
E-ISSN1756-3305
Appears in Collections:(IATS) Artículos

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