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.

[Preparation of monoclonal antibody against E domain III (ED3) protein of duck Tembusu virus with neutralizing activity].

Objective To prepare the specific monoclonal antibody (mAb) against E domain III (ED3) of duck Tembusu virus (DTMUV) and explore its neutralization activity. Methods The ED3 gene was amplified by using reverse transcription PCR according to the genome of the DTMUV AH-F10 strain. Then, the recombinant expression vector pET32a-ED3 was constructed and transformed into E.coli Rosetta. The ED3 protein was expressed and purified by nickel column affinity chromatography. After the recombinant ED3 protein was identified by SDS-PAGE and Western blot analysis, the BALB/c mice were immunized subcutaneously three times. The splenocytes of the immunized mice were hybridized with Sp2/0 myeloma cells, and the hybridization was screened by the limiting dilution method. The specificity and sensitivity of the antibody were identified by indirect immuno-fluorescent assay and Western blot analysis. Subsequently, antibody titers were determined by ELISA. Finally, this study titrated the neutralization titers of the antibodies on DTMUV-infected BHK-21 cells. Results The ED3 protein was successfully prepared and purified using the prokaryotic expression system. Three strains of monoclonal antibodies named B9D10C7, B9D7B8G10 and B9D7B8F11 were prepared. Their subtypes were IgG1, IgG2a and IgG2b, respectively. The titers of monoclonal antibody ascites can reach 1:51 200, and they could specifically recognize the E protein of DTMUV. Neutralization test showed that they had a certain neutralizing activities. Conclusion The monoclonal antibodies against ED3 protein of DTMUV are successfully prepared.

A novel Tembusu virus isolated from goslings in China form a new subgenotype 2.1.1.

Since 2010, several duck Tembusu viruses (DTMUVs) have been isolated from infected ducks in China, and these virus strains have undergone extensive variation over the years. Although the infection rate is high, the mortality rate is usually relatively low-~5%-30%; however, since fall 2019, an infectious disease similar to DTMUV infection but with a high mortality rate of ~50% in goslings has been prevalent in Anhui Province, China. The present study identified a new Tembusu virus, designated DTMUV/Goose/China/2019/AQ-19 (AQ-19), that is believed to be responsible for the noticeably high mortality in goslings. To investigate the genetic variation of this strain, its entire genome was sequenced and analysed for specific variations, and goslings and mice were challenged with the isolated virus to investigate its pathogenicity. The AQ-19 genome shared only 94.3%-96.9% and 90.9% nucleotide identity with other Chinese and Malaysian DTMUVs, respectively; however, AQ-19 has high homology with Thailand DTMUVs (97.2%-98.1% nucleotide identity). Phylogenetic analysis of the E gene revealed that AQ-19 and most of Thailand DTMUVs form a branch separate from any of the previously reported DTMUV strains in China. After the challenge, some goslings and mice showed typical clinical signs of DTMUV, particularly severe neurological dysfunction. AQ-19 has high virulence in goslings and mice, resulting in 60% and 70% mortality through intramuscular and intracerebral routes, respectively. Pathological examination revealed severe histological lesions in the brain and liver of the infected goslings and mice. Taken together, these results demonstrated the emergence of a novel Tembusu virus with high virulence circulating in goslings in China for the first time, and our findings highlight the high genetic diversity of DTMUVs in China. Further study of the pathogenicity and host range of this novel Tembusu virus is particularly important.

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.

Development of colloidal gold immunochromatographic strips for detection of Riemerella anatipestifer.

Riemerella anatipestifer is one of the most important bacterial pathogen of ducks and causes a contagious septicemia. R. anatipestifer infection causes serositis syndromes similar to other bacterial infections in ducks, including infection by Escherichia coli, Salmonella enterica and Pasteurella multocida. Clinically differentiating R. anatipestifer infections from other bacterial pathogen infections is usually difficult. In this study, MAb 1G2F10, a monoclonal antibody against R. anatipestifer GroEL, was used to develop a colloidal gold immunochromatographic strip. Colloidal gold particles were prepared by chemical synthesis to an average diameter of 20 ± 5.26 nm by transmission electron microscope imaging. MAb 1G2F10 was conjugated to colloidal gold particles and the formation of antibody-colloidal gold conjugates was monitored by UV/Vis spectroscopy. Immunochromatographic strips were assembled in regular sequence through different accessories sticked on PVC plate. Strips specifically detected R. anatipestifer within 10 min, but did not detect E. coli, S. enterica and P. multocida. The detection limit for R. anatipestifer was 1 × 10(6) colony forming units, which was 500 times higher than a conventional agglutination test. Accuracy was 100% match to multiplex PCR. Assay stability and reproducibility were excellent after storage at 4°C for 6 months. The immunochromatographic strips prepared in this study offer a specific, sensitive, and rapid detection method for R. anatipestifer, which is of great importance for the prevention and control of R. anatipestifer infections.

The M949_1556 gene plays a role on the bacterial antigenicity and pathogenicity of Riemerella anatipestifer.

Riemerella anatipestifer is one of the most economically important pathogens of farm ducks worldwide. However, the molecular mechanisms regarding its antigenicity and pathogenicity are poorly understood. We previously constructed a library of random Tn4351 transposon mutants using R. anatipestifer strain CH3. In this study, M949_1556 gene inactivated mutant strain CH3ΔM949_1556 was identified by screening of the library using monoclonal antibody against R. anatipestifer serotype 1 lipopolysaccharide (LPS) (anti-LPS MAb) followed by sequence analysis. The mutant strain presented no reactivity to the anti-LPS MAb in an indirect ELISA. Animal studies showed that the median lethal dose (LD50) of CH3ΔM949_1556 was >10(10) colony forming units (CFU), which was attenuated more than 50 times, compared with that of wild-type strain CH3 (LD50=2×10(8) CFU). The bacterial loads in the blood of CH3ΔM949_1556 infected ducks were significantly decreased, compared with those of CH3-infected ducks. In addition, CH3ΔM949_1556 presented significant, higher susceptibility to complement-dependent killing than CH3 did in vitro. Furthermore, CH3ΔM949_1556 showed increased bacterial adhesion and invasion capacities to Vero cells. Immunization with CH3ΔM949_1556-inactived vaccine was effective in protecting the ducks from challenge with R. anatipestifer serotype 1 strain WJ4, serotype 2 strain Yb2 and serotype 10 strain HXb2, suggesting that the mutant strain CH3ΔM949_1556 could provide a broad cross-protection among R. anatipestifer serotypes 1, 2 and 10 strains. Our results demonstrated that the M949_1556 gene plays a role on the bacterial antigenicity and pathogenicity of R. anatipestifer.

Complete Genome Sequence of Riemerella anatipestifer Serotype 1 Strain CH3.

Riemerella anatipestifer is a well-described pathogenic bacterium, which is reported worldwide as the cause of epizootic infectious polyserositis of waterfowl and other avian species. Here, we present the complete genome sequence of R. anatipestifer strain CH3, the serotype 1 prevalent in China.

Molecular cloning of the duck mitogen-activated protein kinase 1 (MAPK1) gene and the development of a quantitative real-time PCR assay to detect its expression.

Mitogen-activated protein kinase 1 (MAPK1) acts as an integration point for multiple biochemical signals, and is involved in a wide variety of biological processes such as cell proliferation and differentiation, transcription regulation, and development. Mitogen-activated protein kinase 1 plays an important role in inducing cell death in bacterial infections. In this study, the duck MAPK1 gene was cloned for the first time from the Cherry Valley duck. Sequence analysis showed that duck MAPK1 cDNA is 1,557 bp long, with an open reading frame of 1,107 bp. It encodes 368 amino acids, with 85.4, 84.5, and 97.3% homology with the human, mouse, and chicken MAPK1 gene, respectively. Furthermore, a SYBR Green quantitative real-time PCR assay was developed to detect duck MAPK1 expression. Following Riemerella anatipestifer infection by virulent strain Yb2, MAPK1 mRNA level increased more than 200-fold in the duck spleens, suggesting that increased duck MAPK1 expression can be used as an indicator of bacterial infection. Our results provide ground work to warrant further studies of the duck MAPK1 gene in bacterial pathogenesis.