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.     

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.     

双抗体夹心ELISA与NIH法在狂犬病疫苗抗原检测中的比较

通过用单克隆抗体制备双抗体夹心ELISA,快速检测狂犬病疫苗中狂犬病毒糖蛋白(G)的含量,将狂犬病疫 苗的检定时间由28天缩短至2个工作日,以此缩短疫苗库存待检时间,提高疫苗的生产和销售效率,并最终替代 NIH动物法。将待检的狂犬病疫苗样品在同一性别12～14g昆明鼠体内作效力检定试验(NIH),同时用双抗体夹 心ELISA检测狂犬病疫苗中狂犬病毒G蛋白含量,用Microsoft Office Excel做出标准品和各样品疫苗的线性关 系图并计算出疫苗效力值E-NIH。结果用双抗体夹心ELISA所得的E-NIH与对应的小鼠效力试验所得结果M- NIH之间呈正相关性;同一批狂犬病疫苗分次测得E-NIH值在2．41～5．85之间,而相应的M-NIH值在5．11～ 10．19之间。从而得出E-NIH与相应的M-NIH之间存在明显的线性关系;与NIH法比较,ELISA具有重复性好、 成本低、快速等优点;用双抗体夹心ELISA替代小鼠效力试验是可能并可行的。     

Creation of DNA vaccine vector based on codon-optimized gene of rabies virus glycoprotein (G protein) with consensus amino acid sequence

An optimized design of the rabies virus glycoprotein (G protein) for use within DNA vaccines has been suggested. The design represents a territorially adapted antigen constructed taking into account glycoprotein amino acid sequences of the rabies viruses registered in the Russian Federation and the vaccine Vnukovo-32 strain. Based on the created consensus amino acid sequence, the nucleotide codon-optimized sequence of this modified glycoprotein was obtained and cloned into the pVAX1 plasmid (a vector of the last generation used in the creation of DNA vaccines). A twofold increase in this gene expression compared to the expression of the Vnukovo-32 strain viral glycoprotein gene in a similar vector was registered in the transfected cell culture. It has been demonstrated that the accumulation of modified G protein exceeds the number of the control protein synthesized using the plasmid with the Vnukovo-32 strain viral glycoprotein gene by 20 times. Thus, the obtained modified rabies virus glycoprotein can be considered to be a promising DNA vaccine antigen.     

Prevention of rabies virus infection in dogs by a recombinant canine adenovirus type-2 encoding the rabies virus glycoprotein

Safe and effective vaccination is important for rabies prevention in animals. Although several genetically engineered rabies vaccines have been developed, few have been licensed for use, principally due to biosafety concerns or due to poor efficacy in animal models. In this paper, we describe the construction and characterization of a replication-competent recombinant canine adenovirus type-2 expressing the rabies virus glycoprotein (SRV9 strain) by a different strategy from that reported previously, i.e., the recombinant genome carrying the glycoprotein cDNA was generated by a series of strictly gene cloning steps, infectious recombinant virus was obtained by transfecting the recombinant genome into a canine kidney cell line, MDCK. This recombinant virus, CAV-E3delta-CGS, was subcutaneously injected into dogs. All vaccinated dogs produced effective neutralizing antibodies after one inoculation and a stronger anamnestic immune response was produced after booster injection. The immunized dogs could survive the challenge of 60,000 mouse LD50 CVS-24, which is lethal to all unimmunized dogs and is comparable to the conventional vaccines. The immunity lasts for months with a protective level of neutralizing antibody. This recombinant virus would be an alternative to the attenuated and the inactivated rabies vaccines and be prospective in immunizing dogs against rabies.     

Progress towards rabies control.

Although safe and efficacious tissue-culture-derived rabies vaccines are available in developed countries, much of the world still depends on vaccines derived from neural tissue which were introduced half a century ago. Considerable advances have been made in our understanding of the molecular biology of rabies virus, and genetically engineered recombinant viruses (vaccinia-rabies virus glycoprotein) have been developed. These may facilitate the control of rabies in some species by oral vaccination campaigns.     

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.     

Novel, chimpanzee serotype 68-based adenoviral vaccine carrier for induction of antibodies to a transgene product

An E1-deletion-containing adenoviral recombinant based on the chimpanzee serotype 68 (AdC68) was developed to express the rabies virus glycoprotein. Mice immunized with this construct (AdC68rab.gp) developed antibodies to rabies virus and remained resistant to challenge with an otherwise lethal dose of rabies virus. In na?ve mice immunized intranasally, the rabies virus-specific antibody responses elicited by AdC68rab.gp were comparable with regard to both titers and isotype profiles to those induced by an adenoviral recombinant based on human serotype 5 (Adhu5) expressing the same transgene product. In contrast, subcutaneous immunization with the AdC68rab.gp vaccine resulted in markedly lower antibody responses to the rabies virus glycoprotein than the corresponding Adhu5 vaccine. Antibodies from AdC68rab.gp-immunized mice were strongly biased towards the immunoglobulin G2a isotype. The antibody response to the rabies virus glycoprotein presented by Adhu5rab.gp was severely compromised in animals preexposed to the homologous adenovirus. In contrast, the rabies virus-specific antibody response to the AdC68rab.gp vaccine was at most marginally affected by preexisting immunity to common human adenovirus serotypes, such as 2, 4, 5, 7, and 12. This novel vaccine carrier thus offers a distinct advantage over adenoviral vaccines based on common human serotypes.     

Rabies virus infects mouse and human lymphocytes and induces apoptosis.

Attenuated and highly neurovirulent rabies virus strains have distinct cellular tropisms. Highly neurovirulent strains such as the challenge virus standard (CVS) are highly neurotropic, whereas the attenuated strain ERA also infects nonneuronal cells. We report that both rabies virus strains infect activated murine lymphocytes and the human lymphoblastoid Jurkat T-cell line in vitro. The lymphocytes are more permissive to the attenuated ERA rabies virus strain than to the CVS strain in both cases. We also report that in contrast to that of the CVS strain, ERA viral replication induces apoptosis of infected Jurkat T cells, and cell death is concomitant with viral glycoprotein expression, suggesting that this protein has a role in the induction of apoptosis. Our data indicate that (i) rabies virus infects lymphocytes, (ii) lymphocyte infection with the attenuated rabies virus strain causes apoptosis, and (iii) apoptosis does not hinder rabies virus production. In contrast to CVS, ERA rabies virus and other attenuated rabies virus vaccines stimulate a strong immune response and are efficient live vaccines. The paradoxical finding that a rabies virus triggers a strong immune response despite the fact that it infects lymphocytes and induces apoptosis is discussed in terms of the function of apoptosis in the immune response.     

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.     

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.     

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。     

Purification of rabies virus glycoprotein produced in Drosophila melanogaster S2 cells: An efficient immunoaffinity method

Most rabies vaccines are based on inactivated virus, which production process demands a high level of biosafety structures. In the past decades, recombinant rabies virus glycoprotein (RVGP) produced in several expression systems has been extensively studied to be used as an alternative vaccine. The immunogenic characteristics of this protein depend on its correct conformation, which is present only after the correct post-translational modifications, typically performed by animal cells. The main challenge of using this protein as a vaccine candidate is to keep its trimeric conformation after the purification process. We describe here a new immunoaffinity chromatography method using a monoclonal antibody for RVGP Site II for purification of recombinant rabies virus glycoprotein expressed on the membrane of Drosophila melanogaster S2 cells. RVGP recovery achieved at least 93%, and characterization analysis showed that the main antigenic proprieties were preserved after purification.     

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.     

Inactivated or live-attenuated bivalent vaccines that confer protection against rabies and Ebola viruses

The search for a safe and efficacious vaccine for Ebola virus continues, as no current vaccine candidate is nearing licensure. We have developed (i) replication-competent, (ii) replication-deficient, and (iii) chemically inactivated rabies virus (RABV) vaccines expressing Zaire Ebola virus (ZEBOV) glycoprotein (GP) by a reverse genetics system based on the SAD B19 RABV wildlife vaccine. ZEBOV GP is efficiently expressed by these vaccine candidates and is incorporated into virions. The vaccine candidates were avirulent after inoculation of adult mice, and viruses with a deletion in the RABV glycoprotein had greatly reduced neurovirulence after intracerebral inoculation in suckling mice. Immunization with live or inactivated RABV vaccines expressing ZEBOV GP induced humoral immunity against each virus and conferred protection from both lethal RABV and EBOV challenge in mice. The bivalent RABV/ZEBOV vaccines described here have several distinct advantages that may speed the development of inactivated vaccines for use in humans and potentially live or inactivated vaccines for use in nonhuman primates at risk of EBOV infection in endemic areas.     

Raccoon poxvirus recombinants expressing the rabies virus nucleoprotein protect mice against lethal rabies virus infection.

Raccoon poxvirus (RCN) recombinants expressing the rabies virus internal structural nucleoprotein (RCN-N) protected A/WySnJ mice against a lethal challenge with street rabies virus (SRV). Maximum survival was achieved following vaccination by tail scratch and footpad (FP) SRV challenge. RCN-N-vaccinated mice inoculated in the FP with SRV were resistant to infection for at least 54 weeks postvaccination. Protection was also elicited by RCN recombinants expressing the rabies virus glycoprotein (RCN-G). Vaccination with RCN-G evoked rabies virus neutralizing antibody. Rabies virus neutralizing antibody was not detected in RCN-N-vaccinated mice prior to or following SRV infection. Radioimmunoprecipitation assays showed that sera from RCN-N-vaccinated mice which survived SRV infection did not contain antibody to SRV structural protein G, M, or NS. The mechanism(s) of N-induced resistance appears to correlate with the failure of peripherally inoculated SRV to enter the central nervous system (CNS). Support for this correlation with resistance was documented by the observations that SRV-inoculated RCN-N-vaccinated mice did not develop clinical signs of CNS rabies virus infection, infectious SRV was not detected in the spinal cord or brain following FP challenge, and all RCN-N-vaccinated mice died following direct intracranial infection of the CNS with SRV. These results suggest that factors other than anti-G neutralizing antibody are important in resistance to rabies virus and that the N protein should be considered for incorporation with the G protein in recombinant vaccines.     

Sensitive Procedure for Detecting Residual Viable Virus in Inactivated Rabies Vaccine

A procedure for testing inactivated rabies vaccines of tissue culture origin for residual viable virus is reported in which the vaccine to be tested is passed in primary hamster kidney cell culture (PHK) before mouse inoculation. In preliminary experiments, titrations of rabies virus in which each dilution was passed in PHK before inoculating mice yielded titers 100 to 10,000 times higher than the titers obtained for the same virus by direct mouse inoculation. This rabies virus amplification procedure was evaluated by testing 18 lots of inactivated rabies vaccine of tissue culture origin. No viable virus was found in these vaccine lots when tested by direct intracerebral inoculation of mice. Eight of these 18 lots were found to contain viable virus, however, when tested by passage in PHK cell culture. The significance of low levels of viable virus in rabies vaccines is discussed. It is recommended that the amplification procedure described in this report be used in the safety testing of rabies vaccines of tissue culture origin and that it be evaluated for use in testing other rabies vaccines of low tissue content.     

家养犬、猫及野生动物中狂犬病病毒流行病学调查及我国不同类型狂犬病疫苗免疫效果观测研究

选择我国狂犬病高发地区(湖南、贵州)、低发地区(江苏、武汉)和无狂犬病报告地区(沈阳)等三种不同类型的地区,开展针对家养犬、猫和啮齿类动物,以及蝙蝠等野生动物的狂犬病病毒带毒率的流行病学调查,对分离到的病毒株在抗原型别、基因变异以及与现行疫苗是否匹配等方面进行分析、比较研究。结果显示:我国狂犬病的主要宿主动物为犬,捕获犬总带毒率为2.56%;犬中狂犬病病毒的监测点最高阳性检出率达到20.0%;啮齿类动物及蝙蝠等野生动物在本次研究未检测到狂犬病病毒。我国自主研制成功的以aG株和CTN株为毒种的现行人用狂犬病疫苗,经应用研究发现,CTN株的糖蛋白基因与本研究分离到的街毒核酸序列更接近。为进一步评价现行疫苗的有效性,在5个观察点分别以aG株和CTN株毒种生产的疫苗接种两组人群(每组各约50人),结果显示均未出现中、强度反应,疫苗免疫后第7d和14d产生的中和抗体分别达到0.49IU/mL~0.52IU/mL和6.7IU/mL~7.53IU/mL;抗体阳转率分别为45.1%~47.9%和100%,表明这些疫苗具有良好的安全性和保护效果。     

Vaccination of small Asian mongoose (Herpestes javanicus) against rabies

Oral vaccination of free-ranging wildlife is a promising technique in rabies control. The small Asian mongoose (Herpestes javanicus) is an important reservoir of rabies on several Caribbean islands, but no vaccines have been evaluated for this species. Captive mongooses were used to test the safety and efficacy of the commercially licensed vaccinia-rabies glycoprotein (V-RG) recombinant vaccine and a newly developed genetically engineered oral rabies virus vaccine (SPBNGA-S). In one study using V-RG, no vaccinated animals developed detectable rabies virus-neutralizing antibodies, and all but one died after experimental challenge with rabies virus. In contrast, all animals given SPBNGA-S demonstrated seroconversion within 7 to 14 days after vaccination and survived rabies virus challenge. On the basis of these preliminary results indicating the greater efficacy of SPBNGA-S vs. V-RG vaccine, additional investigations will be necessary to determine the optimal dose and duration of vaccination, as well as incorporation of the SPBNGA-S vaccine into edible bait.     

The influence of the type of immunosorbent on rabies antibody EIA; advantages of purified glycoprotein over whole virus

Two types of in vitro assay (enzyme immunoassay and sero-neutralization test) for the titration of rabies antibodies were used to assay sera from mice and humans immunized with cell culture vaccines or neural tissue vaccines. Enzyme immunoassays (EIA) were performed in plates sensitized with whole virus, purified glycoprotein or purified nucleocapsid. Neutralizing antibody titres were determined by the rapid fluorescent focus inhibition test (REFIT) and by an in vitro seroneutralization test including a rapid enzyme immunotitration of intracellular antigens (REITICA). The results obtained with sera of immunized mice and humans showed that (1) cell culture vaccines mainly induced the synthesis of antiglycoprotein neutralizing antibodies; and (2) neural tissue vaccines induced a high synthesis of antinucleocapsid non-neutralizing antibodies and a more or less important synthesis of antiglycoprotein antibodies depending on the origin of the tissue used for their preparation. Consequently, it was emphasized that when using EIA, the antibody titration must be run in glycoprotein-coated plates rather than in whole virus-coated plates to appreciate correctly the immunizing potency of a rabies vaccine, especially neural tissue vaccine.