A study of the aetiology and control of rainbow trout gastroenteritis

Gonzalez, Jorge Del Pozo

January 2009

Disease has been identified as a major problem in the aquaculture industry for the welfare of the fish stocked as well as for its economic impact. The number of diseases affecting cultured fish has increased significantly during recent years with the emergence of several conditions that have added to the overall impact of disease on the industry. Frequently, a lack of scientific knowledge about these diseases is compounded by an absence of effective treatment and control strategies. This has been the case with rainbow trout gastroenteritis (RTGE), an emerging disease of rainbow trout (Oncorhynchus mykiss Walbaum). This study investigated several aspects related to its aetiology and control. A retrospective survey of UK rainbow trout farmers was undertaken to ascertain the extent and severity of RTGE in the UK as well as to identify RTGE risk factors at the site level. Participants in this study accounted for over 85% of UK rainbow trout production in 2004. It was found that the total number of RTGE-affected sites had risen from 2 in the year 2000 to 7 in 2005. The disease was only reported from sites producing more than 200 tonnes of trout/year for the table market. Analysis of risk factors associated with RTGE at the site level showed that this syndrome was associated with large tonnage and rapid production of rainbow trout for the table market. The data collected during this study enabled the identification of those sites that were most likely to present with RTGE the following year and this information was used to study the epidemiology of RTGE at the unit level. A prospective longitudinal study was undertaken in 12 RTGE-affected UK sites. It described in detail the impact, presentation, current control strategies and spread pattern of RTGE within affected UK sites. The risk factors associated with RTGE presence and severity were also investigated. Data were collected for each productive unit (i.e. cage, pond, raceway or tank) on the mortalities, fish origin, site management and environmental factors. RTGE was identified using a case definition based on gross pathological lesions. Analysis of these data revealed that RTGE behaved in an infectious manner. This conclusion was supported by the presence of a pattern typical of a propagating epidemic within affected units. Also, the risk of an unaffected unit becoming RTGE positive was increased if it had received fish from or was contiguous to a RTGE-affected unit. The presentation also suggested an incubation period of 20-25 days. Risk factor analysis identified management and environmental risk factors for RTGE, including high feed input and stressful events, which could be used to generate a list of control strategies. A study of the histopathological and ultrastructural presentation of RTGE was conducted. The location of segmented filamentous bacteria (SFB) and pathological changes found in affected fish were examined. Pyloric caeca were the digestive organ where SFB were found more frequently and in higher numbers, suggesting that this was the best location to detect SFB in RTGE-affected trout. Scanning and transmission electron microscopy revealed a previously undescribed interaction of SFB with the mucosa of distal intestine and pyloric caeca and this included the presence of attachment sites and SFB engulfment by enterocytes, as previously described in other host species. The SFB were not always adjacent to the pathological changes observed in the digestive tract of RTGE-affected trout. Such changes included cytoskeletal damage and osmotic imbalance of enterocytes, with frequent detachment. These observations suggested that if SFB are indeed the cause of RTGE their pathogenesis must involve the production of extracellular products. Analysis of the gross presentation and blood biochemistry in RTGE-affected fish was used to examine the patho-physiologic mechanisms of RTGE. To enable identification of positive RTGE cases for this study, a case definition was created from the information available on RTGE gross presentation in the literature. This case definition was assessed in a sample including 152 fish cases and 152 fish controls from 11 RTGE-affected UK sites, matched by unit of origin. The analysis of these fish using bacteriology, packed cell volume (PCV) and histopathology revealed that RTGE occurred simultaneously with other parasitic and bacterial diseases in a percentage of fish identified with this case definition. With the information gained after analysing the gross presentation, RTGE-affected fish without concurrent disease were selected for the study of the pathogenesis, which included blood biochemical analyses. These analyses revealed a severe osmotic imbalance, and a reduced albumin/globulin ratio suggesting selective loss of albumin, typical for a protein losing enteropathy. The role of the SFB “Candidatus arthromitus” in the aetiology of RTGE was assessed using a newly developed “C. arthromitus”-specific polymerase chain reaction assay (PCR) in conjunction with histological detection. This technique was applied to eight different groups of trout, including an RTGE-affected group and seven negative control groups. This analysis was conducted on DNA extracted from paraffin wax-embedded tissues as well as fresh intestinal contents. The results revealed the presence of “C. arthromitus” DNA in apparently healthy fish from sites where RTGE had never been reported. Additionally, SFB were observed histologically in two trout from an RTGE-free hatchery. These findings do not permit the exclusion of “C. arthromitus” as the aetiological agent for RTGE, although they suggest that the presence of these organisms in the digestive system of healthy trout is not sufficient to cause clinical disease, and therefore other factors are necessary. In conclusion, this study has used a multidisciplinary approach to the study of RTGE which has generated scientific information related to the epidemiology, pathogenesis and aetiology of this syndrome. The results of this project have suggested priority areas where further work is required, including experimental transmission of RTGE, field assessment of the control strategies proposed and further investigation into the aetiology of RTGE.

636.089

Aerobic Uptake of Cholesterol by Ergosterol Auxotrophic Strains in Candida glabrata & Random and Site-Directed Mutagenesis of ERG25 in Saccharomyces cerevisiae

Whybrew, Jennafer Marie

27 September 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Candida albicans and Candida glabrata are opportunistic human pathogens that are the leading cause of fungal infections, which are increasingly becoming the leading cause of sepsis in immunosuppressed individuals. C. glabrata in particular has become a significant concern due to the increase in clinical isolates that demonstrate resistance to triazole antifungal drugs, the most prevalent treatment for such infections. Triazole drugs target the ERG11 gene product and prevent C-14 demethylation of the first sterol intermediate, lanosterol, preventing the production of the pathways end product ergosterol. Ergosterol is required by yeast for cell membrane fluidity and cell signaling. Furthermore, C. glabrata, and not C. albicans, has been reported to utilize cholesterol as a supplement for growth. Although drug resistance is known to be caused by an increase in expression of drug efflux pumps, we hypothesize a second mechanism: that the overuse of triazole drugs has lead to the increase of resistance by C. glabrata through a 2-step process: 1) the accumulation of ergosterol auxotrophic mutations and 2) mutants able to take up exogenous cholesterol anaerobically in the body acquire a second mutation allowing uptake of cholesterol aerobically. Two groups of sterol auxotrophic C. glabrata clinical isolates have been reported to take up sterol aerobically but do not produce a sterol precursor. Sterol auxotrophs have been created in C. glabrata by disrupting different essential genes (ERG1, ERG7, ERG11, ERG25, and ERG27) in the ergosterol pathway to assess which ergosterol mutants will take up sterols aerobically. Random and site-directed mutagenesis was also completed in ERG25 of Saccharmoyces cerevisiae. The ERG25 gene encodes a sterol C-4 methyloxidase essential for sterol biosynthesis in plants, animals, and yeast. This gene functions in turn with ERG26, a sterol C-3 dehydrogenase, and ERG27, a sterol C-3 keto reductase, to remove two methyl groups at the C-4 position on the sterol A ring. In S. cerevisiae, ERG25 has four putative histidine clusters, which bind non-heme iron and a C-terminal KKXX motif, which is a Golgi to ER retrieval motif. We have conducted site-directed and random mutagenesis in the S. cerevisiae wild-type strain SCY876. Site-Directed mutagenesis focused on the four histidine clusters, the KKXX C-terminal motif and other conserved amino acids among various plant, animal, and fungal species. Random mutagenesis was completed with a procedure known as gap repair and was used in an effort to find novel changes in enzyme function outside of the parameters utilized for site-directed mutagenesis. The four putative histidine clusters are expected to be essential for gene function by acting as non-heme iron binding ligands bringing in the oxygen required for the oxidation-reduction in the C-4 demethylation reaction.

Ergosterol, Candida glabrata, ERG25

Septicemia

Candida albicans

Opportunistic infections

Pathogenic fungi -- Molecular aspects

Histology, Pathological

Mycoses

Immunosuppression -- Molecular aspects

Microorganisms -- Effect of drugs on

Ergosterol

Cholesterol -- Metabolism

Anaerobic fungi

Triazoles

Saccharomyces cerevisiae

Mutagenesis