Bingshui Xiu

A novel combined vaccine candidate containing epitopes of HCV NS3, core and E1 proteins induces multi-specific immune responses in BALB/c mice

Hepatitis C virus (HCV) has emerged as the major pathogen of liver disease worldwide. The mechanisms of HCV infection and interaction with a host are poorly understood. What exactly is required for efficient control of HCV infection is largely unknown. Standard treatment combining interferon-alpha (IFN-alpha) and ribavirine is effective in about 50% of the treated patients, however associated with significant toxicity and cost. Therefore, the development of new drugs or vaccines is urgently needed. An efficient vaccine against HCV infection requires induction of broad cellular and humoral immune responses against several viral proteins. We have engineered the combined vaccine candidate mT+mE1, an inclusion of multiple epitopes from HCV NS3, core (C) and E1 proteins. mT contains multiple conserved CD4(+) and CD8(+) T cell epitopes from HCV NS3 and C proteins. mE1 is based on eight dominant neutralizing epitopes of E1 protein from six HCV genotypes. In current study, we showed that immunization with mT+mE1 induced high titers of IgG, IgG1 and IgG2a antibodies to mE1, and high level of NS3- or C-specific CTLs. Furthermore, mT+mE1 elicited a Th1-biased immune response with secretion of high amounts of IFN-gamma, compared with mT alone. Prophylactic as well as therapeutic administration of mT+mE1 in BALB/c mice led to protecting mice against SP2/0 tumor cells expressing HCV NS3 protein. These results suggested that mT+mE1 elicited strong humoral immune responses and multiple specific cellular immune responses. The vaccine candidate is now being tested in pre-clinical trials.

Double-antigen sandwich ELISA for the detection of anti-hepatitis C virus antibodies.

A double-antigen sandwich ELISA was developed a detection of HCV antibodies by a recombinant multi-epitope HCV antigen and a biotin-streptavidin amplification system. Three plasma specimens from 1708 individuals who were suspected previously to be HCV-positive using an HCV antibody diagnostic kit (Chuangxin, Xiamen, China) displayed negative results when using the ELISA. These results were validated by a recombinant immunoblotting assay (two were negative, and one was indeterminate). Among 889 blood specimens donated for clinical evaluation, 246 were positive and 630 were negative using the ELISA. The sensitivity and specificity of the ELISA were 98.7% and 100%, respectively. In 43 donors and 14 patients with chronic hepatitis C, the detectable rates for HCV IgM by both ELISA and the HCV anti-IgM detection reagents (Huimin, Shenyang, China) were 100%, and the detectable rate for HCV IgG using an indirect HCV-antibody detection kit (GWK, Beijing, China) was 98.3%. Thus, the double-antigen sandwich ELISA exhibits strong specificity and sensitivity and has been approved by the China State Food and Drug Administration (SFDA). The performance of the double-antigen sandwich ELISA was similar to the Ortho ELISA 3.0. It did not give false-negative results otherwise IgM was undetectable using an indirect HCV-antibody detection kit. This ELISA provides another method for the detection of HCV antibodies.

Hepatitis C virus core protein promotes the migration and invasion of hepatocyte via activating transcription of extracellular matrix metalloproteinase inducer

The chronic infection of hepatitis C virus (HCV) becomes a main factor evoking hepatocellular carcinoma, where the HCV core protein plays a central role in hepatocarcinogenesis. Whether the core protein directly contributes to metastasis of hepatocytes still remains to be reported in literature. Transwell chamber migration assay, Boyden chamber invasion assays and scanning electron microscopy observations were performed to determine the prometastatic ability of HCV core protein when expressed in human hepatocyte L02 cells. In addition, western blots, dual-luciferase assays, and chromatin immunoprecipitation assays were used to elucidate HCV core protein dependent pathways that promote metastasis in hepatocytes. Our investigation suggests that HCV core protein markedly enhances the capability of migration and invasion in L02 clones expressing HCV core proteins. The metastasis-promoting effect of the core protein is, in part, highly dependent on its effect on promoting the binding of transcription factor Sp1 to the extracellular matrix metalloproteinase inducer promoter. The effect of Sp1 binding resulted in an increase in extracellular matrix metalloproteinase inducer expression and progression of metastasis. Thus, we report that the expression of HCV core protein contributes to the metastasis of hepatocyte cells through activating transcription of extracellular metalloproteinase inducer.

Construction, Expression, Purification and Biotin Labeling of a Single Recombinant Multi-Epitope Antigen for Double-Antigen Sandwich ELISA to Detect Hepatitis C Virus Antibody

Based on B cell epitope predictions, a recombinant antigen with multiple epitopes from four Hepatitis C Virus fragments (C, NS3, NS4 and NS5) were engineered. The recombinant gene was then highly expressed in E. coli. The non-modified and C-terminal-modified recombinant proteins were used for coating and biotin labeling, respectively, to establish the double-antigen sandwich ELISA. Ten positive reference samples confirmed by the CHIRON RIBA HCV 3.0 SIA kit were detected positive, Forty one plasma samples were positive among samples from 441 volunteers, which indicated that the recombinant antigen could readily react well with plasma HCV antibody. As critical reagents of double-antigen sandwich ELISA, the recombinant multi-epitope antigen and the C-terminal-modified and biotin-conjugated antigen show good antigenicity. In this study, we provide a simple approach to produce multiple epitopes within one recombinant protein in order to avoid the costly expression of less-effective pools of multiple proteins, which is the conventional strategy of diagnostic antigen production for HCV antibody detection.

Construction of an immunostimulatory plasmid, pUCpGs10, and research on its immune adjuvant effect.

In order to overcome the instability of CpG ODN in vivo, sequence diversity, and individual differences, eleven CpG ODN fragments were meticulously selected and linked to form a Multi-CpG, which were repeatedly inserted into the cloning vector pUC19 for constructing the recombinant plasmid pUCpGs10 containing ten of Multi-CpG. Using the multi-genotype HCV E1 and multi-epitope complex HCV-T as immunogens, and plasmid pUCpGs10 as the immune adjuvant, Balb/c mice were immunized through nasal and subcutaneous immunization. Strong-specific humoral and cellular immune response were induced, which can obviously inhibit the growth of homograft expressing HCV antigen. The immune adjuvant effect of pUCpGs10 closely matched that of Freund’s complete adjuvant. The plasmid pUCpGs10 can significantly improve IgA content in serum and different mucosal extract and systematical T-cell response via intranasal immunization. In conclusions, the newly constructed immunostimulatory plasmid pUCpGs10 is able to effectively activate the humoral and cellular immune activity, and possesses activation on mucosal immune response.