狂犬病毒糖蛋白DNA疫苗的研制及其免疫效果的观察

构建了含有狂犬病毒（RV）CVS株糖蛋白（GP）基因的重组质粒pCMVCVSRG,将其转染至鼠NIH3T3细胞中,用间接免疫荧光法和APAAP法均证实RVGP能在真核细胞中表达。分别将合RV不同毒株的GP基因的质粒（DNA疫苗）及空白载体质粒（对照组）免疫小鼠,仅DNA疫苗免疫的小鼠产生了中和抗体。以RV攻击后,DNA疫苗免疫组小鼠的存活率与对照组相比,差异有极显著性意义（P＜0．01）;不同的启动子（CMV或SV40）与不同GP基因（来源于CVS株或ERA株）对DNA疫苗的免疫效果无明显影响。在注射120d后．用PCR方法仍可检测出RVGP基因。结果表明：狂犬病DNA疫苗能够诱生低水平的中和抗体和记忆性B淋巴细胞,并能保护小鼠抵抗RV的攻击。该疫苗能在体内稳定存在。狂犬病DNA疫苗的研制为狂犬病免疫开辟了一条新途径,并可为防治其他疾病的DNA疫苗的研制奠定基础。     

A simple immuno-capture ELISA to estimate rabies viral glycoprotein antigen in vaccine manufacture.

Rabies is an endemic, fatal zoonotic disease in the developing countries. Prevention and post-exposure therapy require safe and efficacious vaccines. The vaccine potency depends on the amount of immunogenic rabies viral glycoprotein antigen in the vaccine preparation. In order to estimate the rabies viral glycoprotein antigen, a specific monoclonal antibody was developed and used in an immuno-capture ELISA (IC-ELISA). The monoclonal antibody binds a conformational epitope on the natively folded rabies viral glycoprotein as indicated by specific, membrane fluorescence on unfixed, rabies virus infected murine neuroblastoma (MNA) cells and glycoprotein gene encoding plasmid transfected COS cells. In addition, the monoclonal antibody competes with and blocks a glycoprotein antigen site III binding monoclonal antibody (mAb-D1, Institut Pasteur, Paris, France). The monoclonal antibody was used in an IC-ELISA using an in-house standard to quantify the rabies viral glycoprotein antigen in 12 vaccine preparations with potency values ranging from 4 to 18 IU. The results indicated a good correlation with the NIH mouse potency assay (r=0.83). The immuno-capture ELISA described in this study can be used to quantify the immunogenic rabies viral glycoprotein antigen in the inactivated rabies viral antigen preparation in a simple and rapid format, which enables better vaccine formulation.     

Rabies vaccine

Rabies vaccines produced by means of molecular biology are described. Recombinant vaccines employing either viruses as vectors (vaccinia, adenovirus, poxvirus, baculovirus, plant viruses) or a plasmid vector carrying the rabies virus glycoprotein gene are discussed. Synthetic peptide technology directed to rabies vaccine production is also presented.     

Improving the safety of viral DNA vaccines: development of vectors containing both 5′ and 3′ homologous regulatory sequences from non-viral origin

Although some DNA vaccines have proved to be very efficient in field trials, their authorisation still remains limited to a few countries. This is in part due to safety issues because most of them contain viral regulatory sequences to driving the expression of the encoded antigen. This is the case of the only DNA vaccine against a fish rhabdovirus (a negative ssRNA virus), authorised in Canada, despite the important economic losses that these viruses cause to aquaculture all over the world. In an attempt to solve this problem and using as a model a non-authorised, but efficient DNA vaccine against the fish rhabdovirus, viral haemorrhagic septicaemia virus (VHSV), we developed a plasmid construction containing regulatory sequences exclusively from fish origin. The result was an “all-fish vector”, named pJAC-G, containing 5′ and 3′ regulatory sequences of β-acting genes from carp and zebrafish, respectively. In vitro and in vivo, pJAC-G drove a successful expression of the VHSV glycoprotein G (G), the only antigen of the virus conferring in vivo protection. Furthermore, and by means of in vitro fusion assays, it was confirmed that G protein expressed from pJAC-G was fully functional. Altogether, these results suggest that DNA vaccines containing host-homologous gene regulatory sequences might be useful for developing safer DNA vaccines, while they also might be useful for basic studies.     

Safe and effective two-in-one replicon-and-VLP minispike vaccine for COVID-19: Protection of mice after a single immunization

Vaccines of outstanding efficiency, safety, and public acceptance are needed to halt the current SARS-CoV-2 pandemic. Concerns include potential side effects caused by the antigen itself and safety of viral DNA and RNA delivery vectors. The large SARS-CoV-2 spike (S) protein is the main target of current COVID-19 vaccine candidates but can induce non-neutralizing antibodies, which might cause vaccination-induced complications or enhancement of COVID-19 disease. Besides, encoding of a functional S in replication-competent virus vector vaccines may result in the emergence of viruses with altered or expanded tropism. Here, we have developed a safe single round rhabdovirus replicon vaccine platform for enhanced presentation of the S receptor-binding domain (RBD). Structure-guided design was employed to build a chimeric minispike comprising the globular RBD linked to a transmembrane stem-anchor sequence derived from rabies virus (RABV) glycoprotein (G). Vesicular stomatitis virus (VSV) and RABV replicons encoding the minispike not only allowed expression of the antigen at the cell surface but also incorporation into the envelope of secreted non-infectious particles, thus combining classic vector-driven antigen expression and particulate virus-like particle (VLP) presentation. A single dose of a prototype replicon vaccine complemented with VSV G, VSVΔG-minispike-eGFP (G), stimulated high titers of SARS-CoV-2 neutralizing antibodies in mice, equivalent to those found in COVID-19 patients, and protected transgenic K18-hACE2 mice from COVID-19-like disease. Homologous boost immunization further enhanced virus neutralizing activity. The results demonstrate that non-spreading rhabdovirus RNA replicons expressing minispike proteins represent effective and safe alternatives to vaccination approaches using replication-competent viruses and/or the entire S antigen.     

A DNA Construct That Encodes the Rabies Virus Consensus Glycoprotein with a Proteasome Degradation Signal Induces Antibody Production with IgG2A Subtype Predominance

The possibility of enhancing the immunogenicity of the rabies virus glycoprotein antigen encoded by a DNA vaccine has been investigated. Ubiquitin-like protein FAT10 has been attached to the N-terminus of the glycoprotein to target it to the proteasome and stimulate its presentation by MHC class I. Two forms of the protein, chimeric and original, have been detected in cells transfected with the DNA construct encoding the chimeric protein. The presence of the glycoprotein on the cell surface has been detected by immunostaining of transfected cells. The production of IgG and IgG2a antibodies has been more efficiently induced in mice immunized with the plasmid that encodes the chimeric protein than in those immunized with the plasmid that encodes unmodified glycoprotein. Moreover, the level of IgG2a antibodies exceeded the level of IgG1 antibodies, which indicates a preferential increase in the Th1 component of the immune response. The proposed DNA construct that encodes a modified glycoprotein with a proteasome degradation signal may be a promising DNA vaccine immunogen for post-exposure prophylaxis of rabies.     

狂犬病病毒SRV_9突变株的构建与拯救

为构建人工修饰的狂犬病病毒,首先用人细胞色素C基因替换狂犬病病毒SRV9株基因间隔区中的非必需区域Ψ区并缺失基因组全长cDNA的糖蛋白CD编码区,得到突变型SRV9cDNA质粒。然后,该质粒与表达野生型SRV9四种结构蛋白N、P、G和L的质粒共转染BHK-21细胞。免疫荧光试验显示转染细胞中有大量特异性荧光,电子显微镜观察可见大量典型的狂犬病病毒粒子。上述结果表明已成功地拯救出了人工修饰的狂犬病病毒。狂犬病病毒SRV9突变株的成功构建与拯救,为新型狂犬病减毒活疫苗的研究提供了重要的实验工具。     

汉坦病毒囊膜糖蛋白G1基因重组腺病毒载体的构建及其在Vero E6细胞中的表达

拟构建汉坦病毒Gl基因重组腺病毒载体并在VeroE6细胞中表达,为汉坦病毒基因疫苗的研究提供实验基础。PCR法从含汉坦病毒-76118株M基因的M56质粒扩增糖蛋白G1基因片段,利用穿梭质粒pShuttle,将其克隆入Adeno—X病毒DNA,获得重组腺病毒DNA,转染HEK293细胞,包装、扩增后得到汉坦病毒Gl基因重组腺病毒原种,感染VetoE6细胞,用IFA法和ELISA法检测表达产物。得到了含汉坦病毒G1基因的重组腺病毒,其滴度约为10^11pfu／ml,感染VeroE6细胞后检测到汉坦病毒糖蛋白G1的表达。     

Rabies virus (RV) glycoprotein expression levels are not critical for pathogenicity of RV

Previous comparisons of different rabies virus (RV) strains suggested an inverse relationship between pathogenicity and the amount of glycoprotein produced in infected cells. In order to provide more insight into this relationship, we pursued an experimental approach that allowed us to alter the glycoprotein expression level without altering the glycoprotein sequence, thereby eliminating the contribution of amino acid changes to differences in viral virulence. To this end, we constructed an infectious clone of the highly pathogenic rabies virus strain CVS-N2c and replaced its cognate glycoprotein gene with synthetic versions in which silent mutations were introduced to replace wild-type codons with the most or least frequently used synonymous codons. A recombinant N2c variant containing the fully codon-optimized G gene and three variants carrying a partially codon-deoptimized G gene were recovered on mouse neuroblastoma cells and shown to express 2- to 3-fold more and less glycoprotein, respectively, than wild-type N2c. Pathogenicity studies in mice revealed the WT-N2c virus to be the most pathogenic strain. Variants containing partially codon-deoptimized glycoprotein genes or the codon-optimized gene were less pathogenic than WT-N2c but still caused significant mortality. We conclude that the expression level of the glycoprotein gene does have an impact on pathogenicity but is not a dominant factor that determines pathogenicity. Thus, strategies such as changes in codon usage that aim solely at altering the expression level of the glycoprotein gene do not suffice to render a pathogenic rabies virus apathogenic and are not a viable and safe approach for attenuation of a pathogenic strain.     

狂犬病病毒糖蛋白在大肠埃希菌中的表达及鉴定

目的表达狂犬病病毒糖蛋白（GP）,用于狂犬病疫苗免疫抗体评估和狂犬病病毒糖蛋白功能的研究。方法采用分析软件,分析其可能的抗原表位,利用PCR方法扩增狂犬病病毒SRV9疫苗株G蛋白抗原位点区域基因,PCR产物经EcoRI和SalI双酶切后,插入大肠埃希菌表达载体pGEX-6P-1,构建重组表达质粒pGEX-6P-1/G87a和pGEX-6P-1/G100a。将重组质粒转化大肠埃希菌BL21感受态细胞中,在IPTG诱导下表达目的蛋白,进行SDS-PAGE分析。表达蛋白进行电洗脱纯化和Western blot鉴定分析。结果成功构建了pGEX-6P-1/G87a和pGEX-6P-1/G100a表达质粒,序列分析表明,插入片段大小分别为1314 bp和1275 bp。SDS-PAGE分析结果证明,在大肠埃希菌系统中成功表达了狂犬病病毒部分糖蛋白,表达的融合蛋白含有GST标签,大小分别约为74×103和73×103。Western blot鉴定结果表明,表达产物有抗原特异性并能与狂犬病病毒抗血清反应。结论利用大肠埃希菌表达系统成功表达了狂犬病病毒部分糖蛋白,表达产物有良好的反应原性。     

狂犬病病毒糖蛋白的杆状病毒表达及其免疫原性研究

构建表达狂犬病病毒SRV9株糖蛋白(GP)的重组杆状病毒,评价其表达出的SRV9株糖蛋白对小鼠免疫效果。将狂犬病病毒SRV9株GP基因的完整开放阅读框克隆入穿梭质粒Bacmid中,构建重组穿梭质粒Bacmid-G,以此转染Sf9细胞。对病变细胞培养物进行电镜观察,获得正确重组杆状病毒后,通过Western-blot、IFA及小鼠免疫实验鉴定表达产物的免疫反应性及免疫原性。正确构建重组穿梭质粒Bacmid-G;获得表达SRV9株糖蛋白的重组杆状病毒,其表达产物具有良好免疫原性;表达产物接种小鼠可诱导其产生抗狂犬病病毒中和抗体,中和抗体达到保护水平的比例为100%。本实验所获得的重组杆状病毒表达出的SRV9株糖蛋白具有较好的免疫原性,可诱导小鼠产生保护性中和抗体,该实验为进一步开发狂犬病亚单位疫苗奠定了基础。     

人源抗狂犬病毒单克隆抗体Fab段基因的获得和表达

运用噬菌体表面呈现（phage display）技术获得了人源抗狂犬病毒糖蛋白基因工程单克隆抗体Fab段基因及其表达。从狂犬病毒PM株Vero细胞疫苗免疫的人抗凝血中分离获得外周淋巴细胞,提取细胞总RNA,通过RTPCR方法,用一组人IgG Fab基因4特异性引物,从合成的cDNA中扩增了一组轻链和重链Fab段基因,将轻链和重链Fab段基因,将轻链和重链先后克隆入噬菌体载体pComb3,成功地建立了抗狂犬病毒抗原的方法,对此抗体库进行富积筛选表达,成功地获得了抗狂犬病毒的人源单抗Fab段基因及其在大肠杆菌中的有效表达,对其中一株单抗G10进行了较为系统的分析,发现它与一株鼠源中和性狂犬病毒糖蛋白特异性单抗存在竞争,证实该单抗能识别狂犬病毒糖蛋白,其序列资料分析表明,该单抗为一株新的抗狂犬病毒人源基因工程抗体。     

Plant Transformation Vectors Having Street Rabies Virus (Indian Strain) Glycoprotein Gene

Rabies, a serious health hazard, affects central nervous system of mammals and is caused by rabies virus. The viral glycoprotein forms the external surface of virus and is the most antigenic protein. Hence the rabies glycoprotein is an ideal candidate for use in the construction of a subunit marked vaccine. With the idea to substitute the total inactivated virus with G protein in the production of vaccine, the study was undertaken to clone the full-length glycoprotein gene under the control of various constitutive and expression promoters for its expression in bacterial background and its further cloning for plant transformation.     

Standardization of an enzyme immunoassay for the in vitro potency assay of inactivated tissue culture rabies vaccines: determination of the rabies virus glycoprotein with polyclonal antisera

A non-competitive enzyme-linked immunoassay (ELISA) has been standardized to supplement the in vivo potency test used for the quality control of inactivated tissue culture vaccines against rabies. The essentials of the ELISA were: fixation of the virus in different dilutions of vaccine on the surface of microtitre plates; testing of the reference and up to six test vaccines on one plate; incubation with polyclonal antisera to rabies virus glycoprotein containing an excess of antibody; further incubation with a species-specific anti-IgG coupled to peroxidase; a final incubation with a substrate. The incubation periods were 1 h, 1 h and 30 min both at +37 degrees C. The relative potency determinations were made graphically or by a computer using a parallel line bioassay in which the potencies of the vaccines of unknown potency were tested against the reference preparation on a single microtitre plate. Under these conditions inactivated rabies vaccines of different types (virus strains, cell substrates, inactivation and concentration procedures) were tested for potency. Furthermore, it was possible with this in vitro method to assay adjuvanted vaccines, in process samples such as tissue culture supernatants with live or inactivated rabies virus, concentrates, and vaccines undergoing thermal stability tests. The rabies glycoprotein antigen-antibody reaction was highly specific according to the results and the glycoprotein content was measured quantitatively. The potency determined by the in vitro ELISA correlated with the in vivo NIH protection potency test. The lower limit of detection of the ELISA was 0.015 IU/ml. Quantitative antigen determination was possible with both homologous and heterologous antisera to rabies virus glycoprotein when vaccines of the same virus strain were tested. When the potencies of vaccines of different virus strain specificity were calculated, it was necessary to take into account the strain-specific antigenicity. Even so vaccines of high potency were found to give a stronger reaction with a heterologous serum than did weak vaccines with a homologous antiserum. Stability tests made on inactivated tissue culture vaccines such as vaccine from the human diploid cell strain (HDCS), from purified chicken embryo cell (PCEC) or from purified Vero cell rabies vaccine (PVRV), showed high stability of the glycoprotein antigen even after four months of storage at +37 degrees C or 24 h at +56 degrees C, provided that the vaccines were stored in a lyophilized state. The antigenicity of liquid vaccines was inactivated after a few hours at +56 degrees C. For tropical areas, therefore, only lyophilized vaccines should be considered.     

C-terminal lysosome targeting domain of CD63 modifies cellular localization of rabies virus glycoprotein

The glycoprotein of rabies virus is the central antigen elicited the immune response to infection; therefore, the majority of developing anti-rabies vaccines are based on this protein. In order to increase the efficacy of DNA immunogen encoding rabies virus glycoprotein, the construction of chimeric protein with the CD63 domain has been proposed. The CD63 is a transmembrane protein localized on the cell surface and in lysosomes. The lysosome targeting motif GYEVM is located at its C-terminus. We used the domain that bears this motif (c-CD63) to generate chimeric glycoprotein in order to relocalize it into lysosomes. Here, it was shown that, in cells transfected with plasmid that encodes glycoprotein with c-CD63 motif at the C-terminus, the chimeric protein was predominantly observed in lysosomes and at the cell membrane where the unmodified glycoprotein is localized in the endoplasmic reticulum and at the cell surface. We suppose that current modification of the glycoprotein may improve the immunogenicity of anti-rabies DNA vaccines due to more efficient antibody production.     

Construction of an infectious pseudorabies virus recombinant expressing a glycoprotein gIII-β-galactosidase fusion protein

An infectious herpesvirus mutant has been constructed in which a major structural envelope glycoprotein gene was replaced by a hybrid gene encoding a novel fusion protein consisting of the N-terminus of the viral glycoprotein joined to Escherichia coli β-galactosidase (ßGal). Specifically, we fused DNA encoding the first 157 amino acids of the structural glycoprotein gIII from pseudorabies virus strain Becker to the E. coli lacZ gene in a bacterial expression vector. The resulting hybrid gene was then used to replace the wild-type gIII gene in the virus by cotransfection of plasmid and viral DNA. The desired viral recombinants were identified by their inability to react with specific monoclonal antibodies that recognized only wild-type gIII protein. One such mutant virus, PRV-Z1, was chosen for further analysis. PRV-Z1 expressed a glycosylated gIII-ßGal fusion protein after infection of PK15 cells. The fusion protein has no demonstrable ßGal activity and, although glycosylated, remains sensitive to the enzyme endo-β-N-acetylglucosaminidase H, unlike the mature gIII gene product, indicating that the fusion protein was incompletely processed.     

Rabies Virus Glycoprotein with a Consensus Amino Acid Sequence and a Lysosome Targeting Signal Causes Effective Production of Antibodies in DNA-Immunized Mice

Safe and effective anti-rabies vaccines are intensely sought worldwide. DNA vaccines have already shown their efficacy and safety and have occupied a special place in the field. Two prototype anti-rabies DNA vaccines were compared for the potential to induce virus-specific antibody production. One vector contained a codon-optimized gene with a territory-adapted consensus sequence of the rabies virus glycoprotein. The other one expressed the same glycoprotein in fusion with a c-CD63 lysosome targeting motif at the C terminus. ELISA of serum samples from immunized mice showed that the c-CD63 variant induced more efficient antibody production and shifted the IgG2a/IgG1 ratio towards the Th2-type immune response. The results gave grounds to believe that the approach successfully applied to the rabies glycoprotein may help to develop new-generation anti-rabies vaccines.     

The influence of homologous vs. heterologous challenge virus strains on the serological test results of rabies virus neutralizing assays

The effect that the relatedness of the viral seed strain used to produce rabies vaccines has to the strain of challenge virus used to measure rabies virus neutralizing antibodies after vaccination was evaluated. Serum samples from 173 subjects vaccinated with either purified Vero cell rabies vaccine (PVRV), produced from the Pittman Moore (PM) seed strain of rabies virus, or purified chick embryo cell rabies vaccine (PCECV), produced from the Flury low egg passage (Flury-LEP) seed strain of rabies virus, were tested in parallel assays by RFFIT using a homologous and a heterologous testing system. In the homologous system, CVS-11 was used as the challenge virus in the assay to evaluate the humoral immune response in subjects vaccinated with PVRV and Flury-LEP was used for subjects vaccinated with PCECV. In the heterologous system, CVS-11 was used as the challenge virus in the assay to evaluate subjects vaccinated with PCECV and Flury-LEP was used for subjects vaccinated with PVRV. Although the difference in G protein homology between the CVS-11 and Flury-LEP rabies virus strains has been reported to be only 5.8%, the use of a homologous testing system resulted in approximately 30% higher titers for nearly two-thirds of the samples from both vaccine groups compared to a heterologous testing system. The evaluation of equivalence of the immune response after vaccination with the two different vaccines was dependent upon the type of testing system, homologous or heterologous, used to evaluate the level of rabies virus neutralizing antibodies. Equivalence between the vaccines was achieved when a homologous testing system was used but not when a heterologous testing system was used. The results of this study indicate that the strain of virus used in the biological assays to measure the level of rabies virus neutralizing antibodies after vaccination could profoundly influence the evaluation of rabies vaccines.     

Serological method of detecting antirabies antibodies]

The possibility of the determination of rabies antibodies by the serological method has been demonstrated, involving the use of culture rabies virus, strain Vnukovo-32, concentrated and purified by high speed centrifugation, for the sensitization of anserine erythrocytes. The neutralization test in mice and the passive hemagglutination test showed a correlation in rabies antibody titers in the sera of animlas immunized with rabies vaccines. The advantages of the passive hemagglutination test consist in the rapidity of obtaining the results, in a simple and economic method of carrying out the test.     

Evaluation of the single radial-immunodiffusion assay for measuring the glycoprotein content of rabies vaccines

The glycoprotein content of rabies vaccines containing the Pitman-Moore strain of rabies virus was measured by the single radial immunodiffusion assay and correlated with vaccine potency. The variability of this assay was 6.3% for a single vaccine lot tested over a one-year period. Using sera prepared against rabies virus glycoprotein from different strains of virus, the assay gave different values. These differences could be eliminated by using a homologous vaccine strain as an internal reference. Single radial-immunodiffusion values for Pitman-Moore vaccines correlated with the manufacturers' NIH potency assay, but required a mathematical transformation to convert values from one assay to the other. Single radial-immunodiffusion values for Street Alabama Dufferin and Flury-LEP vaccines did not correlate with NIH values. Modification of the single radial immunodiffusion technique and the feasibility of using this assay for the determination of rabies vaccine potency are discussed.