Alternative codon usage of PRRS virus ORF5 gene increases eucaryotic expression of GP(5) glycoprotein and improves immune response in challenged pigs

Pigs exposed to GP(5) protein of PRRSV by means of DNA immunization develop specific neutralizing and protecting antibodies. Herein, we report on the consequences of codon bias, and on the favorable outcome of the systematic replacement of native codons of PRRSV ORF5 gene with codons chosen to reflect more closely the codon preference of highly expressed mammalian genes. Therefore, a synthetic PRRSV ORF5 gene (synORF5) was constructed in which 134 nucleotide substitutions were made in comparison to wild-type gene (wtORF5), such that 59% (119) of wild-type codons were replaced with known preferable codons in mammalian cells. In vitro expression in mammalian cells of synORF5 was considerably increased comparatively to wtORF5, following infection with tetracycline inducible replication-defective human adenoviral vectors (hAdVs). After challenge inoculation, SPF pigs vaccinated twice with recombinant hAdV/synORF5 developed earlier and higher antibody titers, including virus neutralizing antibodies to GP(5) than pigs vaccinated with hAdV/wtORF5. Data obtained from animal inoculation studies suggest direct correlation between expression levels of immunogenic structural viral proteins and immune response.     

DNA vaccines co-expressing GP5 and M proteins of porcine reproductive and respiratory syndrome virus (PRRSV) display enhanced immunogenicity

The two major membrane-associated proteins of porcine reproductive and respiratory syndrome virus (PRRSV), GP5 and M (encoded by ORF5 and ORF6 genes, respectively), are associated as disulfide-linked heterodimers (GP5/M) in the virus particle. In the present study, three different DNA vaccine constructs, expressing GP5 alone (pCI-ORF5), M alone (pCI-ORF6) or GP5 and M proteins simultaneously (pCI-ORF5/ORF6), were constructed. In vitro, the co-expressed GP5 and M proteins could form heterodimeric complexes in transfected cells and heterodimerization altered the subcellular localization of GP5. The immunogenicities of these DNA vaccine constructs were firstly investigated in a mouse model. Mice inoculated with pCI-ORF5/ORF6 developed PRRSV-specific neutralizing antibodies at 6 and 8 weeks after primary immunization. However, only some mice developed low levels of neutralizing antibodies in groups immunized with pCI-ORF5 or pCI-ORF6. The highest lymphocyte proliferation responses were also observed in mice immunized with pCI-ORF5/ORF6. Interestingly, significantly enhanced GP5-specific ELISA antibody could be detected in mice immunized with pCI-ORF5/ORF6 compared to mice immunized with pCI-ORF5. The immunogenicities of pCI-ORF5/ORF6 were further evaluated in piglets (the natural host) and all immunized piglets developed neutralizing antibodies at 10 weeks after primary immunization, whereas there was no detectable neutralizing antibodies in piglets immunized with pCI-ORF5. These results indicate that the formation of GP5/M heterodimers may be involved in post-translational modification and transport of GP5 and may play an important role in immune responses against PRRSV infection. More importantly, co-expression of GP5 and M protein in heterodimers can significantly improve the potency of DNA vaccination and could be used as a strategy to develop a new generation of vaccines against PRRSV.     

Immunogenicity and protective efficacy of recombinant pseudorabies virus expressing the two major membrane-associated proteins of porcine reproductive and respiratory syndrome virus

Porcine reproductive and respiratory syndrome virus (PRRSV) infection still remains today as the most significant health threat to swine and poses a challenge to current vaccination strategies. To develop a new generation of vaccine against PRRSV, a live attenuated pseudorabies virus (PRV) was used as vaccine vector to express the two major membrane-associated proteins (GP5 or M) of PRRSV in various forms. Four PRV recombinants, rPRV-GP5 (expressing native GP5), rPRV-GP5m (expressing GP5m, a modified GP5), rPRV-GP5-M (co-expressing GP5 and M proteins), rPRV-GP5m-M (co-expressing GP5m and M proteins) were generated. Mouse immunized with all these recombinants developed comparable PRV-specific humoral immune responses and provided complete protection against a lethal PRV challenge. However, the highest level of PRRSV-specific neutralizing antibodies and lymphocyte proliferative responses was observed in mice immunized with rPRV-GP5m-M. The immunogenicity and protective efficiency of rPRV-GP5m-M were further evaluated in the piglets. Compared to commercial PRRSV killed vaccine, detectable PRRSV-specific neutralizing antibody and higher lymphocyte proliferative responses could be developed in piglets immunized with rPRV-GP5m-M before virus challenge. Furthermore, more efficient protection against a PRRSV challenge was obtained in piglets immunized with rPRV-GP5m-M, as showed by the balanced body-temperature fluctuation, shorter-term viremia, lower proportion of virus load in nasal and oropharyngeal scrapings and tissues, and milder lung lesions. These data indicate that the recombinant rPRV-GP5m-M is a promising candidate bivalent vaccine against both PRV and PRRSV infection.     

Immune response of pigs inoculated with Mycobacterium bovis BCG expressing a truncated form of GP5 and M protein of porcine reproductive and respiratory syndrome virus

Pigs were immunised with recombinant BCG (rBCG) expressing a truncated form of GP5 (lacking the first 30 NH(2)-terminal residues) (rBCGGP5) and M protein (rBCGM) of porcine reproductive and respiratory syndrome virus (PRRSV). At 30 days post-inoculation (dpi), pigs inoculated with rBCGGP5 and rBCGM developed a specific humoral immune response against the viral proteins, as detected by commercial ELISA and Western blot tests, and at 60 dpi, three out of five animals developed neutralizing antibodies with titers ranging from 1:4 to 1:8. At 67 dpi, an IFN-gamma response against BCG antigens, but not against the viral proteins, was detected by ELISPOT in inoculated pigs. Following challenge with a pathogenic strain of PRRSV, pigs inoculated with rBCG showed lower (P<0.05) temperature, viremia and virus load in bronchial lymph nodes than control animals, suggesting the establishment of partial protection against PRRSV infection.     

A novel baculovirus vector shows efficient gene delivery of modified porcine reproductive and respiratory syndrome virus antigens and elicits specific immune response

Porcine reproductive and respiratory syndrome (PRRS) is an economically devastating epizootic of porcine species. Current vaccines are inadequate to control the disease burden and outbreaks in the field. We report a novel baculovirus vaccine vector with White spot syndrome virus immediate early 1 shuttle promoter, with strong activity in both insect cells and mammalian cells, for immunization against PRRSV. The insect cell cultured baculovirus vector produces PRRSV envelope glycoproteins ORF2a, ORF3, ORF4 and ORF5, which are similar to the antigens in the infectious PRRS virion, and these antigens are stably incorporated on the surface of the baculovirus. Further, the baculovirus vector efficiently transduces these antigens in cells of porcine origin, thereby simulating a live infection. The baculovirus vectored PRRSV antigens, upon inoculation in mice, elicits robust neutralizing antibodies against the infective PRRS virus. Further, the experiments indicate that hitherto under emphasized ORF2a and ORF4 are important target antigens for neutralizing PRRSV infectivity.     

Immunogenicity of the highly pathogenic porcine reproductive and respiratory syndrome virus GP5 protein encoded by a synthetic ORF5 gene

Since May 2006, a highly pathogenic porcine reproductive and respiratory syndrome virus (PRRSV), which causes continuous high fever and a high proportion of deaths in vaccinated pigs of all ages, has emerged and prevailed in Mainland China. Huge efforts should be made towards the development of an efficient vaccine against the highly pathogenic PRRSV. Although the ORF5-encoded GP5 is the most important immunogenic protein, accumulating evidences have demonstrated that incomplete protection conferred by GP5-based vaccines. The inability to induce robust protective immunity has been postulated to be associated with the presence of a non-neutralizing decoy epitope and heavy glycosylation in close to its neutralizing epitope. In this study, a synthetic ORF5 gene (SynORF5) was engineered with the codon usage optimized for mammalian cell expression based on the native ORF5 gene of highly pathogenic PRRSV strain WUH3. Additional modifications, i.e., inserting a Pan DR T-helper cell epitope (PADRE) between the neutralizing epitope and the non-neutralizing decoy epitope, and mutating four potential N-glycosylation sites (N30, N34, N35 and N51) were also included in the synthetic ORF5 gene. The immunogenicity of the SynORF5-encoded GP5 was evaluated by DNA vaccination in mice and piglets. Results showed that significantly enhanced GP5-specific ELISA antibody, PRRSV-specific neutralizing antibody, IFN-γ level, as well as lymphocyte proliferation response, could be induced in mice and piglets immunized with DNA construct encoding the modified GP5 than those received DNA vaccine expressing the native GP5. The enhanced immunogenicity of the modified GP5 will be useful to facilitate the development of efficient vaccines against the highly pathogenic PRRSV in the future.     

HSP70 fused with GP3 and GP5 of porcine reproductive and respiratory syndrome virus enhanced the immune responses and protective efficacy against virulent PRRSV challenge in pigs

Porcine reproductive and respiratory syndrome virus (PRRSV) has been mainly responsible for the heavy economic losses in pig industry all over the world. Current vaccination strategies provide only a limited protection. In this study recombinant adenoviruses expressing GP3/GP5 of highly pathogenic PRRSV and heat shock protein 70 (HSP70) gene of Heamophilus parasuis were constructed, and the immune responses and protective efficacy against homologous challenge were examined in pigs. The results showed that all animals vaccinated with rAd-GP35 (co-expressing GP3-GP5), rAd-HS35 and rAd-HSA35 (co-expressing GP3-GP5 fused with HSP70 using different linkers), developed specific anti-PRRSV ELISA antibody and neutralizing antibody. The humoral immune responses of rAd-HS35, especially rAd-HSA35 containing 2A of FMDV between HSP70 and GP3 gene, were significantly higher than that of rAd-GP35. Moreover, the fusion of HSP70 markedly induced both IFN-γ and IL-4 in pigs’ sera. Following challenge with PRRSV, pigs inoculated with recombinant rAd-HS35 and rAd-HSA35 showed lighter clinical signs, lower viremia and less pathological lesion of lungs, as compared to those in rAd-GP35 group. Moreover, the protective efficiency induced by rAd-HSA35 was higher than that of rAd-HS35. It indicated that HSP70 fused with GP3 and GP5 of PRRSV could induce enhanced immune responses and provide protection against virulent PRRSV challenge in pigs. The recombinant adenovirus rAd-HSA35 might be an attractive candidate vaccine for the prevention and control of highly pathogenic PRRSV infections.     

CD40 ligand expressed in adenovirus can improve the immunogenicity of the GP3 and GP5 of porcine reproductive and respiratory syndrome virus in swine

Porcine reproductive and respiratory syndrome virus (PRRSV) has recently caused heavy economic losses in swine industry worldwide. Current vaccination strategies only provide a limited protective efficacy, thus immune modulators are being considered to enhance the effectiveness of PRRSV vaccines. In this study, the recombinant adenoviruses expressing porcine CD40 ligand (CD40L) and GP3/GP5 of PRRSV were constructed and the immune responses were examined in pigs. The results showed that rAd-CD40L-GP35 (co-expressing CD40L and GP3-GP5) or rAd-GP35 (expressing GP3-GP5) plus rAd-CD40L (expressing CD40L) could provide significant higher specific anti-PRRSV ELISA antibody and neutralizing antibody. And the levels of proliferative responses of peripheral blood mononuclear cells (PBMC), IFN-γ and IL-4 were markedly increased in rAd-CD40L-GP35 and rAd-CD40L plus rAd-GP35 groups than those in rAd-GP35 group. Following homologous challenge with Chinese isolate of the North-American genotype of PRRSV, pigs inoculated with recombinant rAd-CD40L-GP35 and rAd-CD40L plus rAd-GP35 showed lighter clinical signs and lower viremia, as compared to those in rAd-GP35 group. It indicated that porcine CD40L could effectively increase humoral and cell-mediated immune responses of GP3 and GP5 of PRRSV. Porcine CD40L might be used as an attractive adjuvant or immunotargeting strategies to enhance the PRRSV subunit vaccine responses in swine.     

Construction and immunogenicity of DNA vaccines encoding fusion protein of murine complement C3d-p28 and GP5 gene of porcine reproductive and respiratory syndrome virus

Porcine reproductive and respiratory syndrome virus (PRRSV) has recently caused catastrophic losses in swine industry worldwide. The commercial vaccines only provide a limited protection against PRRSV infection. At present, DNA vaccine is the focus on the new vaccines. The gene fragment (p28) coding for the molecular adjuvants complement protein C3d (mC3d) from BALB/c mouse was cloned and expressed as a fusion protein for its application in the vaccine study of mice. Three potential vaccines construct units were engineered to contain two, four and six copies of mC3d-p28 coding gene linked to the GP5 gene of PRRSV and one vaccine expressing GP5 alone (pcDNA3.1-GP5) was constructed. Subsequently, the vaccines’ abilities to elicit the humoral and cellular immune responses were investigated in mice. These results showed that significantly enhanced GP5-specific ELISA antibody, GP5-specific neutralizing antibody, IFN-γ level, and IL-4 level, could be induced in mice immunized with DNA construct units encoding the pcDNA3.1-C3d-p28.n-GP5 than those received DNA vaccine expressing GP5 alone (pcDNA3.1-GP5). Analysis of the immunogenicity of different repeats of mC3d-p28 revealed that mC3d-p28 had an enhancing effect on the immunogenicity of antigens, and that six or more repeats of mC3d-p28 may be necessary for efficient enhancement of antigen specific immune responses. This approach may provide a new strategy for the development of efficient vaccines against the PRRSV for pigs in the future.     

Immune responses of pigs inoculated with a recombinant fowlpox virus coexpressing GP5/GP3 of porcine reproductive and respiratory syndrome virus and swine IL-18

Two recombinant fowlpox viruses (rFPV-ORF5-ORF3 and rFPV-IL-18-ORF5-ORF3) containing the ORF5/ORF3 cDNAs of PRRSV (strain Chang Chun) and IL-18 of swine were constructed and evaluated for theirs abilities to induce humoral and cellular responses in piglets. In addition, their abilities to protect piglets against homologous virus challenge were examined. All piglets were given booster vaccinations at 21 days after the initial inoculation, and all piglets were challenged at 60 after the initial inoculation. Control groups were inoculated with wild-type fowlpox virus (wtFPV). All animals vaccinated with rFPV-ORF5-ORF3 and rFPV-IL-18-ORF5-ORF3 developed specific anti-PRRSV ELISA antibody and neutralizing antibody, as well as T-lymphocyte proliferation response. To evaluate the cellular immune function, IFN-gamma production in pigs serum and T-lymphocytes (CD4 and CD8 T cells) in peripheral blood were examined. Following challenge with a pathogenic strain of PRRSV (strain Chang Chun), piglets inoculated with recombinant fowlpox virus (rFPV) showed lower (P<0.05) temperature, viremia and virus load in bronchial lymph nodes than control animals, suggesting the establishment of partial protection against PRRSV infection. The results demonstrated the potential use of a fowlpox virus-based recombinant vaccine in the control and prevention of PRRSV infections.     

A recombinant plasmid co-expressing swine ubiquitin and the GP5 encoding-gene of porcine reproductive and respiratory syndrome virus induces protective immunity in piglets

We transfected a recombinant plasmid that co-expressed swine ubiquitin and a codon optimized GP5 encoding-gene of porcine reproductive and respiratory syndrome virus (PRRSV), designated pCA-U-optiGP5, as well as the plasmid pCA-optiGP5 encoding codon optimized GP5, and the plasmid pCA-GP5 expressing wild-type pGP5 into 293T cells. Expression of GP5 was measured by indirect immunofluorescence (IIF) assay and Western blot and found to be considerably higher in response to pCA-U-optiGP5 than the wild-type vector. GP5 protein was rapidly degraded in pCA-U-optiGP5-transfected 293T cells. The proteasome inhibitor, MG-132, however, successfully inhibited degradation. Immunogenicity of the three constructs was examined by measuring GP5-specific antibody production, lymphocyte proliferation, cytotoxic T lymphocyte (CTL) responses, and cytokine secretion in intramuscularly immunized pigs. Three weeks after the last inoculation, all animals were challenged intranasally with 2-ml 10(5)TCID(50)/ml PRRSV CH-1a. DNA immunization with pCA-optiGP5 produced a higher level of GP5-specific antibody than immunization with pCA-GP5, and the humoral response remained undetectable in the pCA-U-optiGP5 group. However, the fusion DNA had a significantly enhanced stimulation index (SI) and induced a stronger Th1 type cellular immune response than the single gene DNA, suggesting that ubiquitin conjugation improved the cellular but not the humoral immune response. Four of six pigs in the pCA-U-optiGP5 group, three of six in the pCA-optiGP5 group, and two of six in the pCA-GP5 group were devoid of visible pathological changes that were present in other vaccinated and control animals after challenge. Viral replication and distribution in the blood and tissues was lower in the pCA-U-optiGP5 vaccinated group than the other groups, suggesting that codon optimization, along with the development of rapidly processed antigen, represents a novel strategy to increase the immune efficacy of DNA vaccines against PRRSV.     

Construction and immunogenicity of recombinant Mycobacterium bovis BCG expressing GP5 and M protein of porcine reproductive respiratory syndrome virus

Mycobacterium bovis BCG was used to express a truncated form of GP5 (lacking the first 30 NH(2)-terminal residues) and M protein of porcine reproductive and respiratory syndrome virus (PRRSV). The PRRSV proteins were expressed in BCG under control of the mycobacterial hsp60 gene promoter either in the mycobacterial cytoplasm (BCGGP5cyt and BCGMcyt) or as MT19-fusion proteins on the mycobacterial surface (BCGGP5surf and BCGMsurf). Mice inoculated with BCGGP5surf and BCGMsurf developed antibodies against the viral proteins at 30 days post-inoculation (dpi) as detected by ELISA and Western blot. By 60 dpi, the animals developed titer of neutralizing antibodies of 8. A PRRSV-specific gamma interferon response was also detected in splenocytes of recombinant BCG-inoculated mice at 60 and 90 dpi. These results indicate that BCG was able to express antigens of PRRSV and elicit an immune response against the viral proteins in mice.     

Production and immunogenicity of chimeric virus-like particles containing porcine reproductive and respiratory syndrome virus GP5 protein

Porcine reproductive and respiratory syndrome virus (PRRSV) poses a severe threat in swine industry and causes heavy economic losses worldwide. Currently, the available vaccines are the inactivated and attenuated virus vaccines, but the use of PRRSV in their production raises the issue of safety. We developed a chimeric virus-like particles (VLPs) vaccine candidate for PRRSV protection. The chimeric VLPs was composed of M1 protein from H1N1 influenza virus and a fusion protein, denoted as NA/GP5, containing the cytoplasmic and transmembrane domains of H1N1 virus NA protein and PRRSV GP5 protein. Vaccination of BALB/c mice with 10 μg of chimeirc VLPs by intramuscular immunization stimulated antibody responses to GP5 protein, and induced cellular immune response. The data suggested that the chimeric VLP vaccine candidate may provide a new strategy for further development of vaccines against PRRSV infection.     

Construction and immunogenicity of pseudotype baculovirus expressing Toxoplasma gondii SAG1 protein in BALB/c mice model

Toxoplasma gondii is a protozoan parasite causing toxoplasmosis to almost one-third of population all over the world. One of the most efficient ways to control this disease is immunization. However, so far, there is no effective vaccine available against this pathogen. Recently, a baculovirus pseudotype with vesicular stomatitis virus G protein (Bac-VSV–G) was found to efficiently transduce and express transgenes on mammalian cells, so it was considered as an excellent expressing vector. In this study, the value of Bac-VSV–G in delivering T. gondii antigen was investigated. T. gondii SAG1 gene was cloned into Bac-VSV–G, and recombinant baculovirus BV-G-SAG1 was obtained. Indirect immunofluorescence test showed BV-G-SAG1 was efficiently transduced and expressed in pig kidney cells. Then BALB/c mice were immunized with BV-G-SAG1 at different doses (1 × 10⁸, 1 × 10⁹, and 1 × 10¹⁰ PFU/mouse) and challenged with T. gondii RH strain tachyzoites after immunization. The levels of specific T. gondii antibody, interferon (IFN)-γ, IL-4, IL-10 expression and release, and the survival rate of treated mice were evaluated. Compared with the mice immunized with DNA vaccine (pcDNA/SAG1) encoding the same gene, BV-G-SAG1 induced higher levels of specific T. gondii antibody and (IFN)-γ expression with dose-dependent manner and the survival rate of mice with BV-G-SAG1 was significantly improved. These results indicated that pseudotype baculovirus-mediated gene delivery can be utilized as an alternative strategy to develop new generation of vaccines against T. gondii infection.     

In vivo targeting of porcine reproductive and respiratory syndrome virus antigen through porcine DC-SIGN to dendritic cells elicits antigen-specific CD4T cell immunity in pigs

Immunogenicity of protein subunit vaccines may be dramatically improved by targeting them through antibodies specific to c-type lectin receptors (CLRs) of dendritic cells in mice, cattle, and primates. This novel vaccine development approach has not yet been explored in pigs or other species largely due to the lack of key reagents. In this study, we demonstrate that porcine reproductive and respiratory syndrome virus (PRRSV) antigen was targeted efficiently to dendritic cells through antibodies specific to a porcine CLR molecule DC-SIGN (dendritic cell-specific intercellular adhesion molecule-3-grabbing non-integrin) in pigs. A recombinant PRRSV antigen (shGP45M) was constructed by fusing secretory-competent subunits of GP4, GP5 and M proteins derived from genetically-shuffled strains of PRRSV. In vaccinated pigs, when the PRRSV shGP45M antigen was delivered through a recombinant mouse-porcine chimeric antibody specific to the porcine DC-SIGN (pDC-SIGN) neck domain, porcine dendritic cells rapidly internalized them in vitro and induced higher numbers of antigen-specific interferon-γ producing CD4T cells compared to the pigs receiving non-targeted PRRSV shGP45M antigen. The pDC-SIGN targeting of recombinant antigen subunits may serve as an alternative or complementary strategy to existing vaccines to improve protective immunity against PRRSV by inducing efficient T cell responses.     

Baculovirus surface display of E envelope glycoprotein of Japanese encephalitis virus and its immunogenicity of the displayed proteins in mouse and swine models

Japanese encephalitis virus (JEV), an important pathogen in humans and animals, is capable of causing febrile syndrome, encephalitis and death. The E glycoprotein of JEV is the main target for inducing neutralizing antibodies and protective immunity in the natural host. In this work, we have succeeded in construction of one recombinant baculovirus BacSC-E expressing His6-tagged E with the baculovirus envelope protein gp64 TM and CTD. After infection, E was expressed and anchored on the plasma membrane of Sf-9 cells, as demonstrated by Western blot and confocal microscopy. Immunogold electron microscopy demonstrated that the E glycoprotein was successfully displayed on the viral surface. Vaccination of mouse and swine with recombinant baculovirus BacSC-E successfully induced neutralizing antibody response and protective immunity toward a lethal challenge of the JEV. Taken all findings together, our results indicate that the recombinant baculovirus BacSC-E can be a potential vaccine against JEV infections. This finding provides valuable information for establishing subunit vaccines for JEV antigenic complex viruses. This is a fresh research demonstrating the potential of E-pseudotyped baculovirus as a JEV vaccine.     

Generation and immunogenicity of porcine circovirus type 2 chimeric virus-like particles displaying porcine reproductive and respiratory syndrome virus GP5 epitope B

Virus-like particles (VLPs) can be used as transfer vehicles carrying foreign proteins or antigen epitopes to produce chimeric VLPs for bivalent or multivalent vaccines. Based on the crystal structure of porcine circovirus type 2 (PCV2) capsid protein (Cap), in addition to alignment of the Cap sequences collected from various isolates of PCV2 and PCV1, we predicted that Loop CD of the PCV2 Cap should tolerate insertion of foreign epitopes, and furthermore that such an insertion could be presented on the surface of PCV2 VLPs. To validate this, the GP5 epitope B of porcine reproductive and respiratory syndrome virus (PRRSV) was inserted into Loop CD of the PCV2 Cap. The 3D structure of the recombinant PCV2 Cap (rCap) was simulated by homology modeling; it appeared that the GP5 epitope B was folded as a relatively independent unit, separated from the PCV2 Cap backbone. Furthermore, based on transmission electron microscopy, the purified PCV2 rCap self-assembled into chimeric VLPs which entered PK-15 cells. In addition, PCV2 chimeric VLPs induced strong humoral (neutralizing antibodies against PCV2 and PRRSV) and cellular immune responses in mice. We concluded that the identified insertion site in the PCV2 Cap had great potential to develop PCV2 VLPs-based bivalent or multivalent vaccines; furthermore, it would also facilitate development of a nano-device to present a functional peptide on the surface of the VLPs that could be used for therapeutic purposes.     

Purifying selection in porcine reproductive and respiratory syndrome virus ORF5a protein influences variation in envelope glycoprotein 5 glycosylation

Porcine reproductive and respiratory syndrome virus ORF5a protein is encoded in an alternate open reading frame upstream of the major envelope glycoprotein (GP5) in subgenomic mRNA5. Bioinformatic analysis of 3466 type 2 PRRSV sequences showed that the two proteins have co-evolved through a fine balance of purifying codon usage to maintain a conserved RQ-rich motif in ORF5a protein, while eliciting a variable N-linked glycosylation motif in the alternative GP5 reading frame. Conservation of the ORF5a protein RQ-motif also explains an anomalous uracil desert in GP5 hypervariable glycosylation region. The N-terminus of the mature GP5 protein was confirmed to start with amino acid 32, the hypervariable region of the ectodomain. Since GP5 glycosylation variability is assumed to result from immunological selection against neutralizing antibodies, these findings show that an alternative possibility unrelated to immunological selection not only exists, but provides a foundation for investigating previously unsuspected aspects of PRRSV biology. Understanding functional consequences of subtle nucleotide sequence modifications in the region responsible for critical function in ORF5a protein and GP5 glycosylation is essential for rational design of new vaccines against PRRS.     

Characterization of antigenic regions in the porcine reproductive and respiratory syndrome virus by the use of peptide-specific serum antibodies

The porcine reproductive and respiratory syndrome virus (PRRSV) is an RNA virus that causes reproductive failure in sows and boars, and respiratory disease in pigs of all ages. Antibodies against several viral envelope proteins are produced upon infection, and the glycoproteins GP4 and GP5 are known targets for virus neutralization. Still, substantial evidence points to the presence of more, yet unidentified neutralizing antibody targets in the PRRSV envelope proteins. The current study aimed to identify and characterize linear antigenic regions (ARs) within the entire set of envelope proteins of the European prototype PRRSV strain Lelystad virus (LV). Seventeen LV-specific antisera were tested in pepscan analysis on GP2, E, GP3, GP4, GP5 and M, resulting in the identification of twenty-one ARs that are capable of inducing antibodies upon infection in pigs. A considerable number of these ARs correspond to previously described epitopes in different European- and North-American-type PRRSV strains. Remarkably, the largest number of ARs was found in GP3, and two ARs in the GP3 ectodomain consistently induced antibodies in a majority of infected pigs. In contrast, all remaining ARs, except for a highly immunogenic epitope in GP4, were only recognized by one or a few infected animals. Sensitivity to antibody-mediated neutralization was tested for a selected number of ARs by in vitro virus-neutralization tests on alveolar macrophages with peptide-purified antibodies. In addition to the known neutralizing epitope in GP4, two ARs in GP2 and one in GP3 turned out to be targets for virus-neutralizing antibodies. No virus-neutralizing antibody targets were found in E, GP5 or M. Since the neutralizing AR in GP3 induced antibodies in a majority of infected pigs, the immunogenicity of this AR was studied more extensively, and it was demonstrated that the corresponding region in GP3 of virus strains other than LV also induces virus-neutralizing antibodies. This study provides new insights into PRRSV antigenicity, and contributes to the knowledge on protective immunity and immune evasion strategies of the virus.     

汉坦病毒G2糖蛋白在昆虫细胞中的表达及其在免疫诊断中的应用

目的构建汉坦病毒(HV）Z10株包膜糖蛋白G2基因的重组表达载体，探索其在昆虫细胞中的表达及在免疫荧光诊断中的应用。方法以质粒pUCm—Z10M为模板设计引物，用聚合酶链反应(PCR)扩增Z10株G2基因片段，将G2片段克隆入pUCm—T质粒载体，碱法提取质粒pUCm-Z10-G2，酶切后将回收片段插入杆状病毒转移载体pFastBacHTa，构建重组体pFastBacHTa-Z10-G2，重组体转化感受态细胞E．coli DH10Bac后，经2轮筛选，提取重组质粒转染昆虫细胞sf9，并用间接免疫荧光技术检测表达的G2蛋白。结果获得含有编码HV Z10株的包膜糖蛋白G2基因的重组质粒，转染昆虫细胞表达出G2蛋白，与肾综合征出血热(HFRS)阳性血清反应，昆虫细胞内呈现特异性环状荧光。检测40份HFRS血清，与全病毒细胞抗原片的符合率为95％。结论成功构建HV Z10株包膜糖蛋白G2基因的表达载体，并在昆虫细胞中表达。可利用重组G2蛋白检测HV感染。