Zhang Zq

Enhanced immune response induced by a potential influenza A vaccine based on branched M2e polypeptides linked to tuftsin.

Vaccination is the most effective means for preventing influenza-associated morbidity and mortality. Since the influenza virus mutates frequently, the virus strains for new vaccine production should be changed according to predicted epidemic strains. The extracellular domain of matrix protein 2 (M2e) is 24 amino acids long, which is highly conserved and therefore a good target for the development of a universal vaccine which may protect against a much wider range of influenza A virus strains. However its low antigenicity and immunogenicity, which are related to its small size, poses a big challenge for vaccine development. Multiple antigen peptide system (MAP) is based on an inert core molecule of radially branching lysine dendrites onto which a number of peptide antigens are anchored. Tuftsin is an immuno-stimulant molecule peptide. Here we developed a novel peptide vaccine by connecting a tuftsin to a branched, four-copy M2e. Not only did this increase the molecular mass, but also potentiate the immunogenicity. Two branched peptides, (M2e)4-tuftsin and (M2e)4-G4(tuftsin was replaced with four glycines), and a M2e monomer were synthesized using standard solid-phase methods. In vitro and in vivo studies were performed to compare their antigenicity and immunogenicity. Experiments in BALB/c mice demonstrated that the branched M2e could induce stronger humoral and cellular immune responses than the M2e monomer, and (M2e)4-tuftsin induced stronger humoral and cellular immune response than (M2e)4-G4. After lethal challenge with influenza virus PR8 strain, up to 80% of the animals in the (M2e)4-tuftsin vaccinated group still survived, in contrast to 44% in the (M2e)4-G4 group and 30% in the M2e monomer group. The combination of branched polypeptides and tuftsin in vaccine design is presented here for the first time, and the results show that the new construct is a promising candidate for a universal vaccine against the influenza A virus.

Inhibitory effect of small interfering RNA specific for a novel candidate target in PB1 gene of influenza A virus.

Influenza, mainly caused by influenza virus, is becoming one of the major concerns in the world. Limitation in vaccines necessitates the urgent development of new therapeutic options against this virus. In the present study, we designed small interfering RNA (siRNA) targeting overlapping gene of PB1 and PB1-F2 gene of the influenza A virus and investigated its effect against influenza A virus infection. A reduction in virus-associated cell apoptosis was observed in A549 cells treated with this siRNA. Furthermore, its antiviral effect was confirmed by different methods. Also, a marked decrease of virus titer in chicken embryos treated with the siRNA was observed. The findings of this work highlight the potential of this shared region to be an additional therapeutic target for the treatment of influenza virus infection.

[Expression of sTNFR-IgGFc fusion gene in endothelial cell and its application in gene therapy for rheumatoid arthritis].

Tumor necrosis factor alpha (TNFalpha) is a pro-inflammatory cytokine, acting as a regulator of inflammation and immunity. TNFalpha plays a critical role in the pathogenesis of rheumatoid arthritis. Blocking of TNFa activity suppressed inflammatory tissue damage. In present study, the chimeric gene of soluble TNF receptor and IgG Fc fragment (sTNFR-IgG FC) was cloned into the mammalian cell expression vector pStar. When the plamid pStar/sTNFR-IgGFc-GFP was transfected into endothelial cells, a considerable expression of the sTNFR-IgG Fc fusion protein was detected. Moreover, the product in 100microL expression supernatant could completely antagonize the cytolytic effect of 1ng TNFa on L929 cells, even at 1/64 dilution. Then the plasmid was delivered into CIA-induced rheumatoid arthritis mice by tail vein injection. The expression of sTNFR-IgG Fc was detected in liver by RT-PCR. Animals in treatment group showed reduced symptoms of arthritis and more active. This treatment induced decrease of synovial incrassation and prevented the cartilage destruction of the mice RA model. These results show that tail vein injection is an effective way for gene therapy and sTNFR-IgGFc expression plasmid is potential for the treatment of rheumatoid arthritis.

Involvement of non-structural proteins (NS) in influenza A infection and viral tropism.

Hemagglutinin (HA) of influenza A has been reported as the key protein in viral infection. Therefore, the density and the dynamic pattern of this protein in viral envelope will affect the virus to infect target cells. We used a lentiviral system to study the influenza A H1N1 viral infection. Herein we demonstrate that the influenza non-structural proteins (NS) significantly promote viral infection. By substituting NS gene segment from an H1N1 genome set of A/WSN/1933 with the NS segment isolated from another H1N1 substrain genome set, China246, we found that viral infection tropism was significantly altered. The reassortant H1N1 shows almost identical infectivity compared with its parental virus, A/WSN/1933, for the human epithelial cell line HOT, but shows only 1/100 infectivity of its parental virus when infecting the Madin-Darby canine kidney (MDCK) cell line. These results suggest that not only is NS important in the infectivity of human influenza virus, but that it may play a critical role in viral tropism, allowing the virus to mutate and spread to other species.