Potential virulence factors of Nocardia seriolae AHLQ20-01 based on whole-genome analysis and its pathogenicity to largemouth bass (Micropterus salmoides).

Nocardia seriolae is a major causative agent of fish nocardiosis that results in serious economic losses in the aquaculture industry. However, the virulence factors and pathogenic mechanisms of the bacterium are poorly understood. Here, a new N. seriolae strain AHLQ20-01 was isolated from the diseased Micropterus salmoides and identified by phenotypic examination combined with 16S rRNA sequencing. Subsequently, the potential virulence factors of the strain were analysed at genome level by whole-genome sequencing. The results showed that the whole-genome sequence derived from N. seriolae AHLQ20-01 circular chromosome contains 8,129,380 bp DNA with G + C content of 68.14%, and encompasses 7650 protein-coding genes, 114 pseudo-genes, 3 rRNAs, 66 tRNAs and 36 non-coding RNAs. More importantly, a total of 139 genes, which mainly involved in adhesion, invasion, resistance to oxidative and nitrosative stress, phagosome arresting, iron acquisition system, toxin production and bacterial secretion systems, were identified as core virulence-associated genes. Furthermore, the pathogenicity of N. seriolae AHLQ20-01 to M. salmoides was further investigated through experimental infection. It was found that the LD50 value of the strain to M. salmoides was 9.3 × 106  colony forming unit/fish. Histopathological examination demonstrated typical granuloma with varying sizes in the liver, head kidney, spleen and heart of the experimentally infected fish. Terminal deoxynucleotidyl transferase dUTP nick end labelling assay and 4',6-diamidino-2-phenylindole staining showed that there were distinctly more apoptotic cells in all the tested tissues in the infection group, but not in the control group. Together, these findings provide the foundation to further explore the pathogenic mechanism of N. seriolae, which might contribute to the prevention and treatment of fish nocardiosis.

Interleukin-1ß enhances the expression of two antimicrobial peptides in grass carp (Ctenopharyngodon idella) against Vibrio mimicus via activating NF-κB pathway.

Vibrio mimicus (V. mimicus) is a pathogen causing serious vibriosis in aquatic animals. Hepcidin and ß-Defensin1 are two important antibacterial peptides (AMPs) with broad-spectrum antibacterial activity in fish. In mammals, some evidences demonstrated that interleukin-1ß (IL-1ß) primarily promote AMPs expression via activating classical NF-κB pathway, but it still remains unclear in fish. Here, the temporal and spatial expression patterns of grass carp IL-1ß (gcIL-1ß) gene and two AMPs genes (gchepcidin and gcß-defensin1) in tissues post-V. mimicus infection and anti-V. mimicus activity of these two AMPs in vitro were detected, showing that V. mimicus infection significantly elevated the mRNA levels of these three genes in the immune-related tissues although their expression patterns were not entirely consistent, and both gcHepcidin and gcß-Defensin1 possessed anti-V. mimicus activity in vitro. Subsequently, the recombinant gcIL-1ß (rgcIL-1ß) was expressed prokaryotically in an inclusion body, which could promote proliferation of grass carp head kidney leukocytes (gcHKLs) and enhance respiratory burst activity and phagocytic activity of head kidney macrophages. Stimulation with rgcIL-1ß was able to significantly regulate the mRNA expression of key regulatory genes (il-1RI, traf6, tak1, ikkß, iκBα and p65) involved in the activation of classical NF-κB pathway, and then induce gcTAK1 phosphorylation, promote gcp65 nuclear translocation and enhance endogenous gcIL-1ß expression at both mRNA and protein levels, implying NF-κB pathway was activated. More importantly, exogenous rgcIL-1ß stimulation also significantly up-regulated both gcHepcidin and gcß-Defensin1 mRNA levels against V. mimicus, and the regulatory effect was blocked or inhibited by NF-κB inhibitor PDTC. Taken together, our results demonstrated for the first time that grass carp IL-1ß stimulation could significantly enhance the expression of these two anti-V.mimicus AMPs via activating classical NF-κB pathway.

First identification of Nocardia seriolae GapA adhesion function and its three B-cell epitopes with cell-binding activity.

Fish nocardiosis mainly caused by Nocardia seriolae (N. seriolae) is a serious threat to aquaculture. Bacterial adhesion to host cells mediated by adhesin is an initial step of pathogenesis. But it is not clear whether glyceraldehyde-3-phosphate dehydrogenase (GapA) is an adhesin of N. seriolae. Here, recombinant GapA protein (rGapA) was prokaryotic expressed, and its role in the bacterial adhesion to Ctenopharyngodon idella kidney cells was investigated by indirect immunofluorescence, protein-binding assay and adhesion inhibition assay. The results showed that an obvious green fluorescence was observed on the surface of the cells co-incubated with rGapA protein; the cytomembrane proteins of the cells pretreated with rGapA could react with anti-rGapA antibody; and the antibody significantly inhibited the adhesion ability of the bacteria. Subsequently, B-cell linear epitopes of GapA protein were identified by using a immunoinformatics approach combined with peptide ELISA and Western blot for the first time. It was found that four predicted epitopes (Ep58-69 , Ep139-150 , Ep186-197 , Ep318-329 ) could all react with anti-rGapA antibody and obviously inhibit the immunoreactivity between rGapA and anti-rGapA antibody, and they were confirmed as indeed B-cell linear epitopes of the protein. Furthermore, flow cytometry analysis found the percentage of positive cells co-incubated with FITC-labelled epitope peptides (Ep139-150 , Ep186-197 , Ep318-329 ) was significantly higher than those in the FITC-labelled Ep58-69 , unrelated control peptide and cell control. Collectively, GapA is an adhesin of N. seriolae, and epitope peptides (Ep139-150 , Ep186-197 , Ep318-329 ) possess cell-binding activity, which are potential candidates for developing a multiple epitopes-based adhesin vaccine against fish nocardiosis.

Integrated transcriptomic and proteomic analyses of grass carp intestines after vaccination with a double-targeted DNA vaccine of Vibrio mimicus.

Intestinal mucosal immunity plays a vital role against Vibrio mimicus infection because it is an enteric pathogen causing serious vibriosis in fish. In the previous studies, we developed an oral double-targeted DNA vaccine of V. mimicus and demonstrated that the vaccine could elicit significantly higher intestinal mucosal immune response than did naked DNA vaccine. But, little is known underlying regulatory molecular mechanisms of the enhanced intestinal mucosal immunity. Here the transcriptome and proteome in the intestines of the grass carps immunized or not with the double-targeted DNA vaccine were investigated by using RNA-seq and iTRAQ-coupled LC-MS/MS. Compared with the control group, a total of 5339 differentially expressed genes (DEGs) and 1173 differentially expressed proteins (DEPs) were identified in the immunized fish intestines. Subsequently, the integrated analysis between transcriptome and proteome data revealed that 250 DEPs were matched with the corresponding DEGs (named associated DEPs/DEGs) at both transcriptome and proteome levels. Fifty of all the associated DEPs/DEGs were immune-related and mainly enriched in phagosome, antigen-processing and presentation, complement and coagulation cascades, NLRs and MAPK signaling pathways via Gene Ontology and KEGG pathway analyses, which suggested the coordination of the five activated pathways was essential to the enhanced intestinal mucosal immune response in the immunized fish. The protein-protein interaction analysis showed that 60 of the 63 immune-related DEPs to form an integrated network. Additionally, randomly selected DEGs and DEPs were respectively validated by quantitative real-time RT-PCR and multiple reaction monitoring (MRM) assay, indicating that the both RNA-Seq and iTRAQ results in the study were reliable. Overall, our comprehensive transcriptome and proteome data provide some key genes and their protein products for further research on the regulatory molecular mechanisms underlying the enhanced intestinal mucosal immunity.

Identification and immunogenicity of immunodominant mimotopes of outer membrane protein U (OmpU) of Vibrio mimicus from phage display peptide library.

Vibrio mimicus (V. mimicus) is the causative agent of ascites disease in aquatic animals. Outer membrane protein U (OmpU) is an important antigen of V. mimicus, but its protective epitopes are still unclear. A random 12-mer phage-displayed peptide library was used to screen and identify immunodominant mimotopes of the OmpU protein in V. mimicus by panning against purified OmpU-specific polyclonal antibody. Then the immunogenicity and immunoprotection in fish of these mimotopes was evaluated. Nine positive phage clones presented seven different 12- peptide sequences and more than 50% of them carried a consensus core motif of DSSK-P. These positive clones reacted with the target antibody and this interaction could be blocked, in a dose-dependent manner, by OmpU protein. Intraperitoneal injection of seven positive phage clones into fish induced a specific antibody response to OmpU protein. The fish immunized respectively with the positive phage clones C17, C24, C60 and C66 obtained 100% immunoprotective effect against experimental V. mimicus challenge. Taken together, these mimotopes presented by clone C17, C24, C60 and C66 were immunodominant mimotopes of the OmpU protein and exhibited a more appropriate candidate as epitope-based vaccine against V. mimicus infection in aquatic animals.

Nonstructural protein VP2 of chicken anemia virus triggers IFN-ß expression via host cGAS.

Chicken anemia virus (CAV) constitutes an important economic threat for the poultry industry. Advancing the understanding of the pathogenic process of CAV infection, we had previously demonstrated that CAV VP1 has the ability to inhibit expression of IFN-ß via cGAS-STING signalling pathway. Here to go further to reveal this regulatory role of viral phosphatase VP2, we have performed protein-protein interaction assays with cGAS adaptors, as well as IFN-ß induction screenings. Contrary to VP1, VP2 of CAV stimulates the expression of IFN-ß, a regulatory effect more closely associated with cGAS (in the context of the cGAS-STING axis) than with STING, TBK1 or IRF7. The results reported here offer new insights about the molecular mechanisms that varied viral proteins act in a timely manner on the host during CAV infection.

Chicken anemia virus VP1 negatively regulates type I interferon via targeting interferon regulatory factor 7 of the DNA-sensing pathway.

The cyclic GMP-AMP synthase (cGAS)-stimulator of interferon genes (STING) signaling pathway plays a vital role in sensing viral DNA in the cytosol, stimulating type I interferon (IFN) production and triggering the innate immune response against DNA virus infection. However, viruses have evolved effective inhibitors to impede this sensing pathway. Chicken anemia virus (CAV), a nonenveloped ssDNA virus, is a ubiquitous pathogen causing great economic losses to the poultry industry globally. CAV infection is reported to downregulate type I IFN induction. However, whether the cGAS-STING signal axis is used by CAV to regulate type I IFN remains unclear. Our results demonstrate that CAV infection significantly elevates the expression of cGAS and STING at the mRNA level, whereas IFN-ß levels are reduced. Furthermore, IFN-ß activation was completely blocked by the structural protein VP1 of CAV in interferon stimulatory DNA (ISD) or STING-stimulated cells. VP1 was further confirmed as an inhibitor by interacting with interferon regulatory factor 7 (IRF7) by binding its C-terminal 143-492 aa region. IRF7 dimerization induced by TANK binding kinase 1 (TBK1) could be inhibited by VP1 in a dose-dependent manner. Together, our study demonstrates that CAV VP1 is an effective inhibitor that interacts with IRF7 and antagonizes cGAS-STING pathway-mediated IFN-ß activation. These findings reveal a new mechanism of immune evasion by CAV.

Novel peptides screened by phage display peptide library can mimic epitopes of the FnBPA-A protein and induce protective immunity against Staphylococcus aureus in mice.

Fibronectin-binding protein A (FnBPA) is a key adhesin of Staphylococcus aureus, and the protein binding to fibrinogen and elastin is mediated by its N-terminal A domain. Thus, FnBPA-A has been considered a potential vaccine candidate, but the relevant epitopes are not fully understood. Here, purified rabbit anti-FnBPA-A antibodies were produced and used to screen for peptides corresponding to or mimicking the epitope of native FnBPA-A protein by using a phage random 12-mer peptide library. After four rounds of panning, 25 randomly selected phage clones were detected by phage-ELISA and competition-inhibition ELISA. Then, eight anti-rFnBPA-A antibody-binding phage clones were selected for sequencing, and six different 12-mer peptides were displayed by these phages. Although these displayed peptides shared no more than three consecutive amino acid residues identical to the sequence of FnBPA-A, they could be recognized by the FnBPA-A-specific antibodies in vitro and could induce specific antibodies against FnBPA-A in vivo, suggesting that these displayed peptides were mimotopes of FnBPA-A. Finally, the protective efficiencies of these mimotopes were investigated by mouse vaccination and challenge experiments. Compared with that of control group mice, the relative percent survival of mice immunized with phage clones displaying a mimotope was 13.33% (C2 or C15), 0% (C8), 6.67% (C10), 26.67% (C19 or 1:2 mixture of C23 and C19), 53.33% (C23), 33.33% (1:1 mixture of C23 and C19), and 66.67% (2:1 mixture of C23 and C19). Overall, five peptides mimicking FnBPA-A protein epitopes were obtained, and a partially protective immunity against S. aureus infection could be stimulated by these mimotope peptides in mice.

Identification of fish source Vibrio alginolyticus and evaluation of its bacterial ghosts vaccine immune effects.

Vibrio alginolyticus (V. alginolyticus) is a common pathogen for humans and marine aquatic animals. Vibriosis of marine aquatic animals, caused by V. alginolyticus, has become more prevalent globally in recent years. Hence, a safe and effective vaccine is urgently needed for the control of this disease. Here, the strain 16-3 isolated from the large yellow croaker (Larimichthys crocea) suffered from canker was identified as V. alginolyticus based on morphological, biochemical, and 16S rDNA sequencing analysis. Then, recombinant temperature-controlled lysis plasmid pBV220-lysisE was electroporated into the strain 16-3 to generate V. alginolyticus bacterial ghosts (VaBGs) by inducing lysis gene E expression, and the safety and immune effects of VaBGs were further investigated in mice and large yellow croaker. The results showed that VaBGs were as safe as formalin-killed V. alginolyticus cells (FKC) to mice and fish. Compared with FKC and PBS groups, significant elevations of the serum agglutinating antibody titer, serum bactericidal activity, lymphocyte proliferative responses, and levels of four different cytokines (Th1 type: IL-2, TNF-α; Th2 type: IL-4 and IL-6) in serum were detected in the VaBGs group, indicating that a Th1/Th2-mediated mixed immune response was elicited by the VaBGs. More importantly, after challenged with the parent strain 16-3, VaBGs-vaccinated mice and fish showed higher protection than FKC-vaccinated mice, the relative percent of survival (RPS) being 60%, 66.7% and 40%, respectively. Taken together, this is the first demonstration that the newly constructed V. alginolyticus ghosts may be developed as a safe and effective vaccine against V. alginolyticus infection in aquaculture.

First acetyl-proteome profiling of Salmonella Typhimurium revealed involvement of lysine acetylation in drug resistance.

Salmonella are becoming increasingly resistant to fluoroquinolones (FQs), therefore determining the resistance mechanism is very important. Recent studies have shown that protein post-translational modifications (PTM) play a role in bacterial antibiotic resistance. One such type of PTM, lysine acetylation, is a reversible and highly regulated PTM which has been found to be associated with antibiotic resistance in Mycobacterium and Acinetobacter species. Salmonella Typhimurium are major zoonotic pathogens, which are becoming increasingly resistant to FQs, the antibiotics of choice where therapy is indicated. To date, however, there have been no studies on the relationship between PTM and drug resistance in Salmonella. Therefore, in the present study, ciprofloxacin-resistant and susceptible strains of Salmonella were used as the research objects, and tandem mass tag labeling and acetylation enrichment techniques were used to screen for the different expression of actylated proteins between the two strains, and for quantitative and bioinformatics analysis. We identified a total of 631 acetylated proteins involving 1259 lysine acetylation sites. Among the quantified sites, compared with the susceptible strain, the expression of lysine acetylation was upregulated for 112 sites and downregulated for 149 sites in the resistant strain. Bioinformatic analyses showed that the main enrichment pathways for these differentially acetylated proteins are microbial metabolic process, biosynthesis of antibiotics, and bacterial chemotaxis. Among the differentially acetylated proteins, 14 proteins related to bacterial antibiotic resistance were identified (excluding metabolic and virulence-related proteins), and the lysine acetylation expression of these proteins was significantly different between the resistant and susceptible strains. These results indicated that protein lysine acetylation is not only related to metabolism and virulence, but also to antibiotic resistance. The results provide an important basis for in-depth studies of the relationship between protein lysine acetylation and bacterial antibiotic resistance.

[Design and immunogenicity evaluation for the bacteria-like particle vaccine against swine type O foot-and-mouth disease virus].

Based on gram positive enhancer matrix displaying technology, we designed and evaluated a bacteria-like particle vaccine against swine type O Foot-and-mouth disease virus. Three optimized genes of type O Foot-and-mouth disease virus strain Mya98 were cloned into recombinant prokaryotic expression vector pQZ-PA and renamed as pQZ-BT1B-PA, pQZ-BT2B-PA and pQZ-B (T1BT2) 4B-PA, fused with an anchor protein (PA) binding to Gram-positive enhancer matrix (GEM) particles specifically. The protein expression was identified with SDS-PAGE and Western blotting, and then purified with GEM particles. Five-week old female mice were randomly divided into six groups and all the immunization was developed according to subcutaneous injection. Mice in the first three groups were injected with 50 µg/dose GEM-BT1B, GEM-BT2B and GEM-B (T1BT2) 4B, respectively. Mice in the fourth group were immunized with commercial peptide vaccine as positive control. The fifth group vaccinated with host E. coli transformed with pQZ-PA fulfilled as negative control. Mice in the last group injected with sterile PBS served as blank control. The humoral immunity of recombinant protein vaccine was evaluated with peptide-specific antibody and LPB antibody. The cellular immunity was evaluated with lymphocyte proliferation test and cytokine expression detection. SDS-PAGE and Western blotting showed that the most part of soluble target fusion protein have been purified and displayed on GEM particles. Vaccine GEM-B (T1BT2) 4B stimulated mice produce not only higher level of specific antibody against peptide and Foot-and-mouth disease virus specific liquid phase blocking antibody, but also more vigorous spleen lymph proliferation and higher levels of Th1 type cytokines. To summarize, vaccine of GEM-B (T1BT2) 4B possessed good immunogenicity and opened a new way for further Foot-and-mouth disease virus subunit vaccine design.

Screening a Phage Display Library for Two Novel OmpU-Binding Peptides with Adhesion Antagonistic Activity against Vibrio mimicus.

Vibrio mimicus is a pathogen that causes ascites disease in fish. We have previously demonstrated that the outer membrane protein U (OmpU) is an important adhesin in V. mimicus. Here eight specific OmpU-binding phage clones, which presented three different OmpU-binding peptides (designated P1, P2, P3), were screened from a commercially available phage displayed 12-mer peptide library using rOmpU protein as target. Then, synthetic OmpU-binding peptides were measured for their adhesion antagonistic activity and binding affinity via adhesion inhibition test and non-competitive ELISA, respectively. The results showed that after co-incubated with the mixture of rOmpU and P3, visible green fluorescence could be observed on the epithelioma papulosum cyprinidi (EPC) cells surface; while the EPC cells co-incubated with the mixture of rOmpU and P1/P2 exhibited little green fluorescence. The average adhesion number of V. mimicus 04-14 isolate before and after treatment with peptide was 21.4 ± 1.5, 20.8 ± 0.8 (irrelevant peptide), 20.2 ± 0.5 (P3), 5.1 ± 0.7 (P1) and 3.4 ± 0.8 (P2), respectively. There was a significant decrease in the adhesive level of 04-14 isolate treated with P1/ P2 compared to the untreated isolate (p<0.01). The affinity constants of P1 and P2 were (6.17 ± 0.19) × 108 L/mol and (1.24 ± 0.56) × 109 L/mol, respectively. Furthermore, protective effects of P1 and P2 on grass carps challenged with V. mimicus were preliminary detected. It was found there was delayed death of fish in the groups treated with P1/P2, and the survival rate of challenged fish improved with the increase of the dose of adhesion antagonistic peptide. Taken together, two novel OmpU-binding peptides, which possessed adhesion antagonistic activity, high affinity and a certain degree of antibacterial activity against V. mimicus, were screened and identified.

Identification of three novel B-cell epitopes of VMH protein from Vibrio mimicus by screening a phage display peptide library.

Vibrio mimicus is the causative agent of ascites disease in fish. The heat-labile hemolytic toxin designated VMH is an immunoprotective antigen of V. mimicus. However, its epitopes have not been well characterized. Here, a commercially available phage displayed 12-mer peptide library was used to screen epitopes of VMH protein using polyclonal rabbit anti-rVMH protein antibodies, and then five positive phage clones were identified by sandwich and competitive ELISA. Sequences analysis showed that the motif of DPTLL displayed on phage clone 15 and the consensus motif of SLDDDST displayed on the clone 4/11 corresponded to the residues 134-138 and 238-244 of VMH protein, respectively, and the synthetic motif peptides could also be recognized by anti-rVMH-HD antibody in peptide-ELISA. Thus, both motifs DPTLL and SLDDDST were identified as minimal linear B-cell epitopes of VMH protein. Although no similarity was found between VMH protein and the consensus motif of ADGLVPR displayed on the clone 2/6, the synthetic peptide ADGLVPR could absorb anti-rVMH-HD antibody and inhibit the antibody binding to rVMH protein in enhanced chemoluminescence Western blotting, whereas irrelevant control peptide did not affect the antibody binding with rVMH. These results revealed that the peptide ADGLVPR was a mimotope of VMH protein. Taken together, three novel B-cell epitopes of VMH protein were identified, which provide a foundation for developing epitope-based vaccine against V. mimicus infection in fish.

Avian leukosis virus subgroup J triggers caspase-1-mediated inflammatory response in chick livers.

Many pathogens trigger caspase-1-mediated innate immune responses. Avian leukosis virus subgroup J (ALV-J) causes serious immunosuppression and diverse tumors in chicks. The caspase-1 inflammasome mechanism of response to ALV-J invading remains unclear. Here we investigated the expression of caspase-1, the inflammasome adaptor NLRP3, IL-1ß and IL-18 in response to ALV-J infection in the liver of chick. We found caspase-1 mRNA expression was elevated at 5 dpi and peaked at 7 dpi in ALV-J infected animals. Corresponding to this, the expressions of NLRP3 and proinflammatory cytokines IL-1ß and IL-18 were significantly increased at 5 or 7 dpi. In addition, caspase-1 protein expression and inflammatory cell infiltration were induced after virus infection. These results indicated that ALV-J infection could trigger the caspase-1- mediated inflammatory response in chicks. Thus, an understanding of the inflammatory responses can provide a better insight into the pathogenicity of ALV-J and a possible anti-virus target for ALV-J infection.

Outer membrane protein U (OmpU) mediates adhesion of Vibrio mimicus to host cells via two novel N-terminal motifs.

Vibrio mimicus (V.mimicus) is a causative agent of ascites disease in aquatic animals. Our previous studies have demonstrated that the outer membrane protein U (OmpU) from V.mimicus is an immunoprotective antigen with six immunodominant linear B-cell epitopes. Although the N-terminus of OmpU contains potential binding motifs, it remained unclear whether OmpU possesses adhesion function. Here, the adhesive capacity of recombinant OmpU and V.mimicus to epithelioma papulosum cyprinid (EPC) cells was determined by immunofluorescence and adherence assay. The results showed that after co-incubated with rOmpU, an obvious visible green fluorescence could be observed on the EPC cell surface and the nuclei exhibited blue fluorescence; while the control cell surface did not show any signal, only nuclei exhibited blue fluorescence. The average number of wild-type strain adhered to each cell was 32.3 ± 4.5. The average adhesion number of OmpU gene deletion mutant was significantly reduced to 10.8 ± 0.5 (P < 0.01) and restored to 31.3 ± 2.8 by complement strain (P >0.05). Pretreatment of cells with rOmpU reduced the average adhesion number of wild-type strain to 9.7 ± 2.9 (P < 0.01). Likewise, binding was significantly decreased to 8.8 ± 3.2 (P < 0.01) due to blocking role of OmpU antibodies. To determine binding motifs of OmpU, six immunodominant B-cell epitope peptides labeled with FITC were employed in flow cytometry-based binding assay. Two FITC-labeled epitope peptides (aa90-101 and aa173-192) showed strong binding to EPC cells (the fluorescence positive cell rate was 99 ± 0.6% and 98 ± 0.3%, respectively), which could be specifically competed by excess corresponding unlabeled peptides, whereas the remaining four showed a low level of background binding. This is the first demonstration that OmpU possesses adhesion function and its N terminal 90-101 and 173-192 amino acid regions are critical sites for cell surface binding.

Prevalence and characteristics of extended-spectrum ß-lactamase and plasmid-mediated fluoroquinolone resistance genes in Escherichia coli isolated from chickens in Anhui province, China.

The aim of this study was to characterize the prevalence of extended-spectrum ß-lactamase (ESBL) genes and plasmid-mediated fluoroquinolone resistance (PMQR) determinants in 202 Escherichia coli isolates from chickens in Anhui Province, China, and to determine whether ESBL and PMQR genes co-localized in the isolates. Antimicrobial susceptibility for 12 antimicrobials was determined by broth microdilution. Polymerase chain reactions (PCRs), DNA sequencing, and pulsed field gel electrophoresis (PFGE) were employed to characterize the molecular basis for ß-lactam and fluoroquinolone resistance. High rates of antimicrobial resistance were observed, 147 out of the 202 (72.8%) isolates were resistant to at least 6 antimicrobial agents and 28 (13.9%) of the isolates were resistant to at least 10 antimicrobials. The prevalence of blaCTX-M, blaTEM-1 and blaTEM-206 genes was 19.8%, 24.3% and 11.9%, respectively. Seventy-five out of the 202 (37.1%) isolates possessed a plasmid-mediated quinolone resistance determinant in the form of qnrS (n = 21); this determinant occurred occasionally in combination with aac(6')-1b-cr (n = 65). Coexistence of ESBL and/or PMQR genes was identified in 31 of the isolates. Two E. coli isolates carried blaTEM-1, blaCTX-M and qnrS, while two others carried blaCTX-M, qnrS and aac(6')-1b-cr. In addition, blaTEM-1, qnrS and aac(6')-1b-cr were co-located in two other E. coli isolates. PFGE analysis showed that these isolates were not clonally related and were genetically diverse. To the best of our knowledge, this study is the first to describe detection of TEM-206-producing E. coli in farmed chickens, and the presence of blaTEM-206, qnrS and aac(6')-1b-cr in one of the isolates.

Design and evaluation of a tandemly arranged outer membrane protein U (OmpU) multi-epitope as a potential vaccine antigen against Vibrio mimicus in grass carps (Ctenopharyngodon idella).

Vibrio mimicus (V. mimicus) is an extracellular pathogen that causes ascites disease in aquatic animals. In our previous studies, the outer membrane protein U (OmpU) of V. mimicus has been proven to be a protective antigen, and several mimotopes of the protein were identified. Here, a tandemly arranged multi-epitope peptide (named 6EPIS) was designed with six mimotopes and heterologously expressed. Then, the immunoprotection efficacy of recombinant 6EPIS (r6EPIS) was evaluated in grass carps (Ctenopharyngodon idella) by determining relative percentage survival (RPS), specific immunoglobulin M (IgM) antibody titer, and transcriptional levels of immune-related genes of inoculated grass carps. Fish vaccinated with r6EPIS via intraperitoneal injection exhibited 85.71% RPS over the control, when challenged with V. mimicus. The enzyme-linked immunosorbent assay titer of specific IgM antibodies against r6EPIS reached 1:12,800 on Day 28 post the primary immunization. After 28 days post immunization, the transcriptional level of total IgM mRNA was significantly higher in the r6EPIS-vaccinated fish than in those vaccinated with recombinant OmpU, inactivated bacterin and rHis tag peptide (p<0.05). In addition, the transcription levels of interleukin-1ß and tumor necrosis factor-α genes in the spleen and head kidney of r6EPIS-vaccinated fish were significantly increased during the period of immunization and early phase of infection, while the transcription level of interleukin-10 gene was significantly increased from Day 3 to 7 post challenge, compared to the control level. These results show that r6EPIS was highly immunogenic and could elicit strong protective immune responses. It may be an attractive vaccine candidate against V. mimicus infection.

[Effects of Galla chinensis on bacteria and algae in pool water].

With experimental aquarium, this paper studied the effects of different concentration Galla chinensis on the bacteria and algae in pool water. The results showed that when treated for 72 h, there was a significant correlation (r = - 0.84349, P < 0.05) between the total number of bacteria and the concentration of G. chinensis. At the concentration of G. chinensis being higher than 3 mg x L(-1), the total number of bacteria was decreased by 96.2% averagely, and the proportion of Gram-negative bacteria decreased most. After 72 h, the total number of bacteria showed an increasing trend. Definite concentrations of G. Chinensis had a short-term inhibitory effect on the growth of algae. For fish-pond disinfection, the optimal concentration of G. Chinensis could be 3 mg x L(-1), and the optimal treating duration could be 72 h.

Molecular cloning and expression of two chicken invariant chain isoforms produced by alternative splicing.

The biosynthesis of distinct forms of the invariant chain (Ii) protein from a unique gene as the result of differential splicing patterns has been observed in humans and mice. However, there have been no reports on the existence of Ii isoforms in avian species. In the present study, we identified two chicken Ii cDNAs by RT-PCR and RACE, and examined the Ii gene copy number, mRNA expression and protein expression by Southern blotting, Northern blotting and immunofluorescence confocal microscopy, respectively. One of the Ii cDNAs, named Ii-1, was 1,151 bp in length, and had an open reading frame (ORF) of 672 nucleotides, in agreement with a previously identified chicken Ii sequence; the other, named Ii-2, was 1,337 bp long and had an ORF of 861 nucleotides. Southern blotting confirmed that these cDNAs were derived from a single copy gene. Northern blotting performed with total RNA from various tissues of 6-week-old chickens revealed high levels of Ii-1 and Ii-2 mRNA expression in the spleen and bursa of Fabricius, and low levels of Ii-1 expression in the thymus, heart and liver, while Ii-2 was not expressed in these tissues. High levels of expression of both Ii isoforms were detected in the spleen and bursa of Fabricius during late embryogenesis. Immunofluorescence staining showed that Ii proteins were expressed in the cell membranes of the splenocytes. These data suggest that chicken Ii exists in two isoforms resulting from alternative splicing, and is strongly expressed in the major immune organs.