Mechanism of sturgeon intestinal inflammation induced by Yersinia ruckeri and the effect of florfenicol intervention.

The mechanism by which Y. ruckeri infection induces enteritis in Chinese sturgeon remains unclear, and the efficacy of drug prevention and control measures is not only poor but also plagued with numerous issues. We conducted transcriptomic and 16 S rRNA sequencing analyses to examine the differences in the intestinal tract of hybrid sturgeon before and after Y. ruckeri infection and florfenicol intervention. Our findings revealed that Y. ruckeri induced the expression of multiple inflammatory factors, including il1ß, il6, and various chemokines, as well as casp3, casp8, and multiple tumor necrosis factor family members, resulting in pathological injury to the body. Additionally, at the phylum level, the relative abundance of Firmicutes and Bacteroidota increased, while the abundance of Plesiomonas and Cetobacterium decreased at the genus level, altering the composition of the intestinal flora. Following florfenicol intervention, the expression of multiple apoptosis and inflammation-related genes was down-regulated, promoting tissue repair. However, the flora became further dysregulated, increasing the risk of infection. In conclusion, our analysis of the transcriptome and intestinal microbial composition demonstrated that Y. ruckeri induces intestinal pathological damage by triggering apoptosis and altering the composition of the intestinal microbiota. Florfenicol intervention can repair pathological damage, but it also exacerbates flora imbalance, leading to a higher risk of infection. These findings help elucidate the molecular mechanism of Y. ruckeri-induced enteritis in sturgeon and evaluate the therapeutic effect of drugs on intestinal inflammation in sturgeon.

Investigation of the effects of some phytochemicals on Yersinia ruckeri and antimicrobial resistance / Investigação dos efeitos de alguns fitoquímicos em Yersinia ruckeri e resistência antimicrobiana

Abstract In this study, it is aimed to investigate the effects of Moringa oleifera and Sorbus domestica plant extracts on bacterial disease agents Yersinia ruckeri in aquaculture. Morphological and biochemical properties of 2 different Y. ruckeri isolates were determined. Then, Real-Time PCR analysis and gene sequencing of the isolates were identified. Phytochemicals (M. oleifera and S. domestica) and antibiotics (Oxytetracycline (OX) and Enrofloxacin (ENR)) were used together in the antibiogram test of antibiotics compared to the effect status of antibiotics. Also, the effects of phytochemicals on Y. ruckeri growth was examined comparatively by spectrophotometrically measuring at 600 nm wavelength every 2 hours according to bacterial growth densities with 10 different groups formed on TSB medium. As a result of the study, it was observed that the isolates formed Gram negative, catalase positive, oxidase negative, mobile and typical Y. ruckeri colonies. After the biochemical tests performed with Microgen ID panel, 99.85% similarity was determined. The isolates overlap with the 16S rRNA gene region after sequence analysis, and 99% of the isolates were similar in phylogenetic analysis. After the antibiogram test, Oxytetracycline and Enrofloxacin antibiotics were resistant to Y. ruckeri but the effects of phytochemicals were less on solid medium (MHA). As a result of the measurements carried out in liquid medium (TSB), it was observed that phytochemicals such as M. oliefera and S. domestica inhibit the growth of bacteria by 40-50%. As the importance of antibiotic resistance is increasing day by day, we believe that these phytochemicals will give positive results in treatment instead of using antibiotics.

Resumo Neste estudo, objetiva-se investigar os efeitos dos extratos de plantas de Moringa oleifera e Sorbus domestica sobre agentes bacterianos Yersinia ruckeri na aquicultura. Foram determinadas as propriedades morfológicas e bioquímicas de 2 isolados diferentes de Y. ruckeri. Em seguida, a análise de PCR em tempo real e o seqüenciamento genético dos isolados foram identificados. Fitoquímicos (M. oleifera e S. domestica) e antibióticos (Oxitetraciclina e Enrofloxacina) foram usados ​​juntos no teste de antibiograma dos antibióticos em comparação com o status de efeito dos antibióticos. Além disso, os efeitos dos fitoquímicos no crescimento de Y. ruckeri foram examinados comparativamente por medição espectrofotométrica no comprimento de onda de 600 nm a cada 2 horas de acordo com as densidades de crescimento bacteriano com 10 grupos diferentes formados no meio TSB. Como resultado do estudo, observou-se que os isolados formaram colônias Gram-negativas, catalase-positivas, oxidase-negativas, móveis e típicas de Y. ruckeri. Após os testes bioquímicos realizados com o painel Microgen ID, foi determinada uma similaridade de 99,85%. Os isolados se sobrepõem à região do gene 16S rRNA após a análise da sequência e 99% dos isolados foram semelhantes na análise filogenética. Após o teste do antibiograma, os antibióticos Oxitetraciclina e Enrofloxacina foram resistentes a Y. ruckeri, mas os efeitos dos fitoquímicos foram menores no meio sólido (MHA). Como resultado das medições realizadas em meio líquido (TSB), observou-se que os fitoquímicos inibem o crescimento de bactérias em 40-50%. Como a importância da resistência aos antibióticos está aumentando dia a dia, acreditamos que as plantas que são mais alternativas e mais adequadas para o uso de antibióticos hoje em dia darão resultados positivos no tratamento.

Shotgun proteomic analysis of Yersinia ruckeri strains under normal and iron-limited conditions.

Yersinia ruckeri is the causative agent of enteric redmouth disease of fish that causes significant economic losses, particularly in salmonids. Bacterial pathogens differentially express proteins in the host during the infection process, and under certain environmental conditions. Iron is an essential nutrient for many cellular processes and is involved in host sensing and virulence regulation in many bacteria. Little is known about proteomics expression of Y. ruckeri in response to iron-limited conditions. Here, we present whole cell protein identification and quantification for two motile and two non-motile strains of Y. ruckeri cultured in vitro under iron-sufficient and iron-limited conditions, using a shotgun proteomic approach. Label-free, gel-free quantification was performed using a nanoLC-ESI and high resolution mass spectrometry. SWATH technology was used to distinguish between different strains and their responses to iron limitation. Sixty-one differentially expressed proteins were identified in four Y. ruckeri strains. These proteins were involved in processes including iron ion capture and transport, and enzymatic metabolism. The proteins were confirmed to be differentially expressed at the transcriptional level using quantitative real time PCR. Our study provides the first detailed proteome analysis of Y. ruckeri strains, which contributes to our understanding of virulence mechanisms of Y. ruckeri, and informs development of novel control methods for enteric redmouth disease.

In vitro cytotoxicity and multiplex PCR detection of virulence factors of Yersinia ruckeri isolated from rainbow trout in North West Germany.

The aim of this study was to investigate differences in presence and expression of virulence factors between biotype 1 and 2 strains of 82 Yersinia (Y.) ruckeri isolates, collected from North West Germany during the period of 2004-2012, and to analyze the cytotoxicity of these strains to different fish cell lines. The common virulence factor genes, such as yhlA and yhlB encoding for hemolysin YhlA, rucC and rupG encoding for ruckerbactin, yrp1 and yrpDEF for ABC exporter protein system, and two flagellar genes, including flgA for flagellar secretion chaperones and flhA for flagellar secretion apparatus, were found present in both biotype 1 and 2 isolates of Y. ruckeri collected from North West Germany using multiplex PCR. mRNA expression of these genes was compared between the two biotypes of Y. ruckeri. There was no significant diversity (p > 0.05) in the expression of these genes between biotype 1 and 2 strains. 27 Y. ruckeri isolates from different typing groups were analysed in cytotoxicity tests to common carp brain (CCB), epithelioma papulosum cyprini (EPC), fathead minnow epithelial (FHM) and rainbow trout gonad-2 (RTG-2) cells, respectively. In vitro cytotoxicity of the isolates to CCB, EPC and FHM was higher than that to RTG-2 (p < 0.05). At 15 degrees C the maximum cytotoxicity to FHM and EPC was higher in non-motile strains than in motile stains after an incubation of 24 h (p < 0.05), however, after 48 h, there was no significant difference (p > 0.05) of cytotoxicity between those two biotypes. Our results suggest that biotype 2 strains from North West Germany are homogenous with biotype 1 strains on the basis of genetic virulence factor genes. At lower temperature non-motile Y. ruckeri isolates were found more active than motile strains, which could explain why in winter non-motile strains were found more often responsible for ERM outbreaks than motile strains.

Yersiniosis in Atlantic cod, Gadus morhua (L.), characterization of the infective strain and host reactions.

A disease outbreak in farmed Atlantic cod caused by Yersinia ruckeri is reported. Mortality started following vaccination of cod reared in two tanks (A and B). The accumulated mortality reached 1.9% in A and 4.8% in B in the following 30 days when treatment with oxytetracycline was applied. Biochemical and molecular analysis of Y. ruckeri isolates from the cod and other fish species from fresh and marine waters in Iceland revealed a high salinity-tolerant subgroup of Y. ruckeri serotype O1. Infected fish showed clinical signs comparable with those of Y. ruckeri -infected salmonids, with the exception of granuloma formations in infected cod tissues, which is a known response of cod to bacterial infections. Immunohistological examination showed Y. ruckeri antigens in the core of granulomas and the involvement of immune parameters that indicates a strong association between complement and lysozyme killing of bacteria. Experimental infection of cod with a cod isolate induced disease, and the calculated LD50 was 1.7 × 10(4) CFU per fish. The results suggest that yersiniosis can be spread between populations of freshwater and marine fish. Treatment of infected cod with antibiotic did not eliminate the infection, which can be explained by the immune response of cod producing prolonged granulomatous infection.

In vivo monitoring of Yersinia ruckeri in fish tissues: progression and virulence gene expression.

In this study, the utilization of bioluminescence imaging (BLI) allowed us to define the progression of Yersinia ruckeri during the infection of rainbow trout. A luminescent Y. ruckeri 150 strain was engineered using the pCS26-Pac plasmid containing the lux operon from Photorhabdus luminescens. Two different models of infection of rainbow trout were defined depending on the route in which bacteria were administered, being the gut the major organ affected following bath immersion. This indicates that this organ is important for bacterial dissemination inside the fish and the establishment of the infection. Moreover, the expression of three previously selected operons by in vivo expression technology (IVET) was analysed, the yhlBA involved in the production of a haemolysin, the cdsAB related to the uptake of cysteine and the yctCBA implicated in citrate uptake. Apart from these factors, the expression of yrp1 encoding a serralysin metalloprotease involved in pathogenesis was also analysed. The results indicated that all of the assayed promoters were expressed during infection of rainbow trout. In addition to these findings, the methodology described in this work constitutes a useful model for studying the infection process in other fish pathogenic bacteria.

The fish pathogen Yersinia ruckeri produces holomycin and uses an RNA methyltransferase for self-resistance.

Holomycin and its derivatives belong to a class of broad-spectrum antibacterial natural products containing a rare dithiolopyrrolone heterobicyclic scaffold. The antibacterial mechanism of dithiolopyrrolone compounds has been attributed to the inhibition of bacterial RNA polymerase activities, although the exact mode of action has not been established in vitro. Some dithiopyrrolone derivatives display potent anticancer activities. Recently the biosynthetic gene cluster of holomycin has been identified and characterized in Streptomyces clavuligerus. Here we report that the fish pathogen Yersinia ruckeri is a holomycin producer, as evidenced through genome mining, chemical isolation, and structural elucidation as well as genetic manipulation. We also identified a unique regulatory gene hom15 at one end of the gene cluster encoding a cold-shock-like protein that likely regulates the production of holomycin in low cultivation temperatures. Inactivation of hom15 resulted in a significant loss of holomycin production. Finally, gene disruption of an RNA methyltransferase gene hom12 resulted in the sensitivity of the mutant toward holomycin. A complementation experiment of hom12 restored the resistance against holomycin. Although the wild-type Escherichia coli BL21(DE3) Gold is susceptible to holomycin, the mutant harboring hom12 showed tolerance toward holomycin. High resolution liquid chromatography (LC)-ESI/MS analysis of digested RNA fragments demonstrated that the wild-type Y. ruckeri and E. coli harboring hom12 contain a methylated RNA fragment, whereas the mutated Y. ruckeri and the wild-type E. coli only contain normal non-methylated RNA fragments. Taken together, our results strongly suggest that this putative RNA methyltransferase Hom12 is the self-resistance protein that methylates the RNA of Y. ruckeri to reduce the cytotoxic effect of holomycin during holomycin production.

A polyphasic approach to study the intraspecific diversity of Yersinia ruckeri strains isolated from recent outbreaks in salmonid culture.

A polyphasic analysis was carried out on Yersinia ruckeri strains isolated from recently outbreaks in vaccinated fish using a combination of different phenotypic and molecular typing methods in order to study their variability and epidemiological relationships. Eighty strains were subjected to biotyping with conventional tests and API 20E system, serotyping, outer membrane protein (OMP) and lipopolysaccharide (LPS) profiling, and genetic fingerprinting by ERIC-PCR and REP-PCR techniques. The strains showed a high diversity, as evidenced by the formation of different phenotypic groups mainly related to the serotypes, LPS and OMP profiles. The diversity among all isolates, calculated as Simpson's diversity index (Di), varied between 0.35 (REP-PCR) and 0.70 (OMP). The most discriminative values (Di value ≥0.86) were obtained from any combination of three methods including biotype, serotype, API 20E profile, LPS or OMP. With the combination of all typing methods used a Di value of 0.90 was obtained. Association between different groups to the host species was evidenced. Furthermore, it seems that strains with similar characteristics are associated with recent outbreaks occurred in vaccinated fish in certain geographical areas. Our results emphasize the usefulness of using a combination of several different typing methods for epidemiological and bacterial diversity studies.

A novel cdsAB operon is involved in the uptake of L-cysteine and participates in the pathogenesis of Yersinia ruckeri.

Application of in vivo expression technology (IVET) to Yersinia ruckeri, an important fish pathogen, allowed the identification of two adjacent genes that represent a novel bacterial system involved in the uptake and degradation of l-cysteine. Analysis of the translational products of both genes showed permease domains (open reading frame 1 [ORF1]) and amino acid position identities (ORF2) with the l-cysteine desulfidase from Methanocaldococcus jannaschii, a new type of enzyme involved in the breakdown of l-cysteine. The operon was named cdsAB (cysteine desulfidase) and is found widely in anaerobic and facultative bacteria. cdsAB promoter analysis using lacZY gene fusion showed highest induction in the presence of l-cysteine. Two cdsA and cdsB mutant strains were generated. The limited toxic effect and the low utilization of l-cysteine observed in the cdsA mutant, together with radiolabeled experiments, strongly suggested that CdsA is an l-cysteine permease. Fifty percent lethal dose (LD(50)) and competence index experiments showed that both the cdsA and cdsB loci were involved in the pathogenesis of the bacteria. In conclusion, this study has shown for the first time in bacteria the existence of an l-cysteine uptake system that together with an additional l-cysteine desulfidase-encoding gene constitutes a novel operon involved in bacterial virulence.

The UvrY response regulator of the BarA-UvrY two-component system contributes to Yersinia ruckeri infection of rainbow trout (Oncorhynchus mykiss).

To identify virulence-associated genes of a fish pathogen Yersinia ruckeri, we screened a total of 1056 mini-Tn5-Km2 signature-tagged mutants in rainbow trout by immersion challenge. Of 1056, 25 mutants were found survival-defective as they could not be re-isolated from fish kidney 7 days after infection. Mutated gene in F2-4 mutant, one of the 25 mutants, was homologous to uvrY that encodes UvrY response regulator of BarA-UvrY two-component system (TCS). Mutant F2-4 was significantly more sensitive (P < 0.05) to H2O2-mediated killing and was less able to infect Epithelioma papulosum cyprini cells. However, UvrY mutation did not affect survival of F2-4 mutant in the presence of non-immune fish serum and its ability to grow under iron starvation. In a time-course co-infection, mutant F2-4 had lower bacterial loads on day 1 itself, and by day 5 there was nearly a 1,000-fold difference in infection levels of the parent and mutant strains. The barA homolog of Y. ruckeri was PCR-amplified and sequence analyses identified four domains that were characteristic of hybrid histidine kinases. To conclude, the BarA-UvrY TCS contributes to the pathogenesis of Y. ruckeri in its natural host rainbow trout, possibly by regulating invasion of epithelial cells and sensitivity to oxidative stress induced by immune cells.

The iron- and temperature-regulated haemolysin YhlA is a virulence factor of Yersinia ruckeri.

Yersinia ruckeri causes the enteric redmouth disease or yersiniosis, an important systemic fish infection. In an attempt to dissect the virulence mechanisms of this bacterium, a gene encoding a putative protein involved in the secretion/activation of a haemolysin (yhlB), which had been previously identified by in vivo expression technology, was further analysed. The gene yhlB precedes another ORF (yhlA) encoding a Serratia-type haemolysin. Other toxins belonging to this group have been identified in genomic analyses of human-pathogenic yersiniae, although their role and importance in pathogenicity have not been defined yet. In spite of its being an in vivo-induced gene, the expression of yhlA can be induced under certain in vitro conditions similar to those encountered in the host, as deduced from the results obtained by using a yhlB : : lacZY fusion. Thus, higher levels of expression were obtained at 18 degrees C, the temperature of occurrence of disease outbreaks, than at 28 degrees C, the optimal growth temperature. The expression of the haemolysin also increased under iron-starvation conditions. This confirmed the decisive role of iron and temperature as environmental cues that regulate and coordinate the expression of genes encoding extracellular factors involved in the virulence of Y. ruckeri. LD(50) and cell culture experiments, using yhlB and yhlA insertional mutant strains, demonstrated the participation of the haemolysin in the virulence of Y. ruckeri and also its cytolytic properties against the BF-2 fish cell line. Finally, a screening for the production of haemolytic activity and the presence of yhlB and yhlA genes in 12 Y. ruckeri strains proved once more the genetic homogeneity of this species, since all possessed both haemolytic activity and the yhlB and yhlA genes.

First report of Yersinia ruckeri biotype 2 in the USA.

A polyphasic characterization of atypical isolates of Yersinia ruckeri (causative agent of enteric redmouth disease in trout) obtained from hatchery-reared brown trout Salmo trutta in South Carolina was performed. The Y. ruckeri isolates were biochemically and genetically distinct from reference cultures, including the type strain, but were unequivocally ascribed to the species Y. ruckeri, based on API 20E, VITEK, fatty acid methyl ester profiles, and 16S rRNA gene sequencing analysis. These isolates were nonmotile and unable to hydrolyze Tween 20/80 and were therefore classified as Y. ruckeri biotype 2. Genetic fingerprint typing of the isolates via enterobacterial repetitive intergenic consensus (amplified by polymerase chain reaction) and fragment length polymorphism showed biotype 2 as a homogeneous group distinguishable from other Y. ruckeri isolates. This is the first report of Y. ruckeri biotype 2 in the USA.