ABSTRACT
[Objective] Using the bimolecular fluorescence complementation (BiFC) technology, the present experiment aimed to study the interaction relationship and localization of the target peptide and the complementary peptide based on the porcine epidemic diarrhea virus (PEDV) S protein receptor binding site peptide in living cells, so as to provide the foundation and theoretical support for the further use of the peptide in the detection of porcine epidemic diarrhea virus. [Method] The target peptide was designed according to the physical and chemical characteristics of the target protein, such as the amino acid composition, the type of charge, the ability to form intennolecular hydrogen bonds, the strength of polarity, and hydrophobicity;According to the amino acid composition of the target protein, a complementary peptide that interacted with it in theory was designed, and the target peptide and complementary peptide were predicted and analyzed by using bioinfonnatics tools;The target peptide and complementary peptide were inserted into the pBiFC-VC155 and pBiFC-VN173 vector, which was double digested by the EcoRI/XhoI and NotI/SalI, respectively, verified by enzyme digestion and sequencing, and then transfected into Vero cells to study the interaction between the target peptide and the complementary peptide, and the precise localization of BiFC complex in cells. [Result] Bioinfonnatics analysis showed that the target peptide and complementary peptide had hydrophilic and hydrophobic domains, respectively, and the hydrophilic domains were both positively and negatively charged, which could generate electrostatic attraction. The results of enzyme digestion and sequencing showed that the pBiFC-VC155-target peptide and pBiFC-VNI73-complementary peptide plasmids were successfully constructed;Cell transfection experiments showed that the target peptide and complementary peptide could form BiFC complexes in Vcro cells after co-transfection of recombinant plasmids, indicating that they could interact with each other;Indirect immuttolluorescence assay confirmed that the BiFC complex was mainly distributed in the nucleus. [Conclusion] It was confirmed that the peptide designed based on the PEW/ S protein receptor binding site can interact with each other in living cells, demonstrating the feasibility of the peptide for detection.
ABSTRACT
Background and purpose: The sequence of Omp25 is conserved in all Brucella species. The high antigenicity of the product of this gene stimulates the host's immune system. Using engineered probiotic bacteria is an appropriate method for vaccine transport. The aim of this study was to express the Omp25 of the Brucella abortus pathogenic bacterium in Lactococcus lactis probiotic bacterium. Materials and methods: In this experimental study, the required vector was designed and synthesized to include the gene of interest and a signal peptide (pNZ8148-Usp45-Omp25). E. coli strain TOP10F was transformed using the pNZ8148-Usp45-Omp25 expression vector based on induction by nisin. The recombinant plasmid was extracted from the transformed bacteria using a plasmid extraction kit. The L. lactis was transformed by pNZ8148-Usp45-Omp25 vector using electroporation. Evaluation of the expression of Omp25 gene at the RNA level was assessed by reverse transcription method and confirming the presence of recombinant Omp25 protein in the engineered bacteria using SDS-PAGE method. Results: Successful expression of B. abortus Omp25 in L. lactis was verified by RT-PCR. Subsequently, the proteins were separated based on molecular weight using sodium dodecyl sulfate- polyacrylamide gel electrophoresis (SDS-PAGE). The protein expression analysis showed the expression of Omp25 as a 25 kDa extra band in transformed L. lactis compared to the L. lactis receiving the vector lacking the target gene. Conclusion: This study shows that Omp25 is expressed in L. lactis transformed via pNZ8148-Usp45-Omp25 by electroporation. Transformed L. lactis can be successfully used as a subunit oral vaccine in prevention of Brucellosis.
ABSTRACT
Objective: To investigate the molecular mechanism of the action by which the MERS-CoV E proxein induces autophagy in 293T cells.
ABSTRACT
As a member of the family Picornaviridae, porcine sapelovirus (PSV) is often infected with porcine epidemic diarrhea virus, teschovirus and so on. In recent years, PSV has been isolated from porcine in many provinces of China. It suggests that it is necessary to strengthen the research on PSV. In this study, according to the sequence of PSV HuN2 strain, VP1 gene was inserted into the pGEX-6 P-1 vector, and expressed the recombinant protein. BALB/c mice aged 6-8 weeks were immunized according to the standard procedure. After the third immunization, the mouse orbital blood was collected to identify the antibody level. The highly positive mouse spleen cells were selected for cell fusion. The positive hybridoma cells and two subclones were screened by IFA method, and then a PSV VP1 monoclonal antibody was obtained, named as 33-2 A. The results of IFA showed that PSV could be recognized by 33-2 A MAb, and specific green fluorescence appeared in the cytoplasm;The results of WB and IP showed that PSV infected porcine cell could specifically bind to 33-2 A, and there was a specific band at 32 ku. We also identified the B-cell antigen epitope of 33-2 A, it was at amino acids 40-46 of PSV VP1 protein, and the polypeptide sequence was 40PALTAAE46. The results showed that the monoclonal antibody can react with PSV VP1 protein. The epitope was analyzed with the PSV sequences uploaded in NCBI, 33-2 A antibody can react with most PSV strains and has a certain universal to PSV. This study laid a foundation for the study of the etiology and pathogenesis of PSV.
ABSTRACT
Objective: To prepare the recombinant antigen and monoclonal antibody (mAb) of nucleocapsid protein of severe acute respiratory syndrome coronavirus 2 (SARA-CoV-2).