豚鼠动物模型评价牛口蹄疫Asia-1型灭活疫苗效力的研究

以豚鼠为试验动物模型,探索一种应用豚鼠替代牛进行牛口蹄疫Asia-1型灭活疫苗效力检验的方法.豚鼠和牛同步对6批牛口蹄疫Asia-1型灭活疫苗进行PD50效力检验,其中2批进行重复性试验.豚鼠分别在免疫后7、14、21和28天采血检测Asia-1型的中和抗体水平.统计学分析显示,测定的豚鼠PD50和牛PD50之间具有极...     

Foot-and-mouth disease virus-like particles produced by a SUMO fusion protein system in Escherichia coli induce potent protective immune responses in guinea pigs,swine and cattle

Foot-and-mouth disease virus (FMDV) causes a highly contagious infection in cloven-hoofed animals. The format of FMD virus-like particles (VLP) as a non-replicating particulate vaccine candidate is a promising alternative to conventional inactivated FMDV vaccines. In this study, we explored a prokaryotic system to express and assemble the FMD VLP and validated the potential of VLP as an FMDV vaccine candidate. VLP composed entirely of FMDV (Asia1/Jiangsu/China/2005) capsid proteins (VP0, VP1 and VP3) were simultaneously produced as SUMO fusion proteins by an improved SUMO fusion protein system in E. coli. Proteolytic removal of the SUMO moiety from the fusion proteins resulted in the assembly of VLP with size and shape resembling the authentic FMDV. Immunization of guinea pigs, swine and cattle with FMD VLP by intramuscular inoculation stimulated the FMDV-specific antibody response, neutralizing antibody response, T-cell proliferation response and secretion of cytokine IFN-γ. In addition, immunization with one dose of the VLP resulted in complete protection of these animals from homologous FMDV challenge. The 50% protection dose (PD₅₀) of FMD VLP in cattle is up to 6.34. These results suggest that FMD VLP expressed in E. coli are an effective vaccine in guinea pigs, swine and cattle and support further development of these VLP as a vaccine candidate for protection against FMDV.     

Cattle remain immunocompetent during the acute phase of foot-and-mouth disease virus infection

ABSTRACT: Infection of cattle with foot-and-mouth disease virus (FMDV) results in the development of long-term protective antibody responses. In contrast, inactivated antigen vaccines fail to induce long-term protective immunity. Differences between susceptible species have also been observed during infection with FMDV, with cattle often developing persistent infections whilst pigs develop more severe symptoms and excrete higher levels of virus. This study examined the early immune response to FMDV in na?ve cattle after in-contact challenge. Cattle exposed to FMDV were found to be viraemic and produced neutralising antibody, consistent with previous reports. In contrast to previous studies in pigs these cattle did not develop leucopenia, and the proliferative responses of peripheral blood mononuclear cells to either mitogen or third party antigen were not suppressed. Low levels of type 1 interferon and IL-10 were detected in the circulation. Taken together, these results suggest that there was no generalised immunosuppression during the acute phase of FMDV infection in cattle.     

Protection of cattle against experimental haemorrhagic septicaemia by the capsular antigens of Pasteurella multocida, types B and E.

Aluminum hydroxide adjuvant vaccines containing endotoxin-free capsular antigens of Pasteurella multocida, types B and E, were administered to cattle. Dose dependent serological responses were observed which were similar for both antigens. The immunised cattle were subjected to intravenous challenge by a virulent type E strain. All animals which received the highest vaccine dose survived and all unimmunised control animals died and a vaccine dose-response relationship was obtained. The results of passive mouse protection and indirect haemagglutination tests (type E) on the sera of immunised cattle corresponded with the degree of protection against challenge of the cattle.     

Current status of foot-and-mouth disease vaccines including the use of genetic engineering

SUMMARY Foot-and-mouth disease virus (FMDV) vaccines are used to protect animals against infection by the 7 FMDV serotypes composed of greater than 60 FMDV subtypes. Because of problems of both live attenuated and inactivated FMDV vaccines and also because of the very large market for an effective safe vaccine, research into other types of vaccines has been undertaken. One of the 4 virus structural proteins, VP1, is believed to be the main protein that stimulates virus neutralising antibodies and studies have concentrated on its potential as a subunit vaccine. Genetic engineering has been used to clone the VF1 gene of FMDV and VP1 synthesised from the cloned gene has been used in experimental vaccine studies. The studies in small numbers of cattle and pigs demonstrated that 2 vaccinations with genetically engineered VP1 could confer protection against FMDV challenge. However, there are a number of areas that need further research before such a genetically engineered vaccine could be used commercially. The use of chemically synthesised antigenic fragments of VP1 has recently been reported, and these synthetic fragments appear to be potentially better at producing immunity to FMDV than the whole genetically engineered VP1 protein, perhaps because of conformational problems in the presentation of whole VP1. Other possible future directions in the research and in the development of safe, effective FMDV vaccines are discussed. In conclusion, although very significant progress has been made in cloning FMDV-VP1 genes, we are still far from a genetically engineered VP1-FMDV subunit vaccine. In the meantime, properly inactivated and safety-tested FMDV vaccines will continue to be used and to be of benefit to the livestock industry in countries where foot-and-mouth is endemic or in combating introductions of the disease.     

Intranasal vaccination of pigs against Aujeszky's disease: comparison with one or two doses of attenuated vaccines in pigs with high maternal antibody titres

Ten-week-old pigs with high levels of maternally derived antibody (MDA) against Aujeszky's disease virus (ADV) were given either a single intranasal vaccination or one or two doses (with an interval of three weeks) of commercially available attenuated ADV vaccines intramuscularly. The pigs did not produce a clear neutralising antibody response to ADV. However, pigs vaccinated intranasally and pigs given two doses of attenuated ADV vaccines were protected against intranasal challenge with virulent ADV two months after the first vaccination. Pigs given one parenteral dose of attenuated ADV vaccine were insufficiently protected. Protection was shown by shorter periods of growth arrest and fever and a greater reduction of virulent virus shedding after challenge in vaccinated pigs than in unvaccinated control pigs. Although intranasal vaccination conferred protection comparable to two parenteral doses of attenuated vaccines, it reduced shedding of virulent virus much more effectively. These results, together with those of other studies, show that intranasal vaccination confers better protection against Aujeszky's disease in pigs with MDA than parenteral vaccination. However, the efficacy of intranasal vaccination also decreases with increasing levels of MDA at the time of vaccination.     

Comparative efficacy of ten commercial Campylobacter fetus vaccines in the pregnant guinea pig: challenge with Campylobacter fetus serotype A.

Efficacy of ten commercial Campylobacter fetus vaccines was tested in pregnant guinea pigs and compared with that of an experimental vaccine prepared from the challenge-exposure strain. If the first lot of vaccine failed to protect 50% of the guinea pigs, one or two additional lots of that vaccine were purchased and retested. Three vaccines for cattle, evaluated, as the most effective of those tested, protected 62%, 72%, and 89% of the guinea pigs from abortion; the experimental vaccine protected 98%. The two vaccines for sheep protected 50% and 61% of the guinea pigs from abortion. With the other five vaccines produced for immunizing cattle, protection was from 0% to 36%, with the exception of one lot of a vaccine that protected 74%. Blood infection was found at necropsy in only 6% of the guinea pigs given vaccines that protected 50% or more from abortion, but was found in 66% of those given vaccines that protected less than 50%. Similarly, tissue infection was found at necropsy in only 18% of the guinea pigs given vaccines that protected more than 50%, but was found in 91% of those given vaccines that protected less than 50% from abortion. Oil-emulsion adjuvants appeared to enhance protection from abortion and infection. Nodules persisted at the injection site in most of the guinea pigs immunized with vaccines containing oil-emulsion adjuvants, but rarely persisted in guinea pigs given aqueous-phase adjuvant vaccines. Comparison of efficacy of the vaccines in guinea pigs with efficacy in sheep and cattle remains to be made.     

The efficacy of FMD vaccine reduced non-structural proteins with a mAb against 3B protein

A monoclonal antibody, 3BIgG, against the prokaryotically expressed foot-and-mouth disease virus (FMDV) non-structural protein (NSP) 3B was obtained. The 3BIgG-sepharose conjugant (3BmAb-6BFF) was prepared by adding the purified 3BIgG into epoxy-activated sepharose 6BFF, incubating with the inactivated FMDV, and then removing the sepharose by centrifugation. The vaccine was made from the supernatant emulsified with oil-adjuvant ISA206. Ten guinea pigs, 26 pigs and six cattle were vaccinated, and a vaccination control group was included without treatment with 3BmAb-6BFF. After 28 days, 9/10 pigs challenged with FMDV were protected, this result was the same as the control group, indicating that the vaccine potency was not reduced after treatment with 3BmAb-6BFF. The other animals were vaccinated weekly for nine weeks, and serum samples were collected to detect 3ABC-antibody titers. The results showed that 3ABC-antibody production was delayed and the positive antibody rates were lower when vaccination was carried out using vaccines treated with 3BmAb-6BFF compared with untreated vaccines. The findings of this study suggest that it is possible to reduce NSPs using a mAb-sepharose conjugant in FMD vaccines without reducing their efficacy.     

猪口蹄疫○型合成肽疫苗诱导的免疫抗体的监测

设3组猪群,首免和二免分别注射生理盐水1 mL、猪口蹄疫0型合成肽疫苗1 mL(说明书推荐免疫剂量)及猪口蹄疫0型合成肽疫苗3 mL(说明书推荐免疫剂量3倍量),二免28天后检测猪群的口蹄疫抗体,结果显示3组猪群的抗体合格率分别为33%、78%和100%,疫苗诱导的抗体水平达到农业部规定的动物强制免疫标准。     

Cedivac-FMD can be used according to a marker vaccine principle

In this study, we investigated whether Cedivac-FMD, an emergency vaccine against foot-and-mouth disease (FMD), is suitable for use conjointly with a screening program intended to confirm freedom from disease in vaccinated herds based on evidence of virus replication in vaccinates. Different sets of sera were tested using the Ceditest FMDV-NS ELISA for the detection of antibodies against non-structural proteins (NSPs) of FMD virus. During a vaccine safety study, serum samples were collected from 10 calves, 10 lambs and 10 piglets following administration of a double dose and a repeat dose of high payload trivalent Cedivac-FMD vaccine. All serum samples collected both 2 weeks following the administration of a double dose as well as those collected 2 weeks after the single dose booster (given 2 weeks after the double dose) were negative in the Ceditest FMDV-NS ELISA. In a series of vaccine potency experiments, serum samples were collected from 70 vaccinated cattle prior to and following exposure to infectious, homologous FMD virus. When testing cattle sera collected 4 weeks after vaccination with a regular dose of monovalent >6 PD(50) vaccines, 1 of 70 animals tested positive in the NSP antibody ELISA. After infection with FMD virus, antibodies to NSP were detected in 59 of 70 vaccinated cattle and 27 of 28 non-vaccinated control animals within 7 days. Cedivac-FMD vaccines do not induce NSP antibodies in cattle, pigs or sheep following administration of a double dose or a repeat dose. FMD-exposed animals can be detected in a vaccinated group within 7-14 days. Because Cedivac-FMD does not induce NSP antibodies, the principle of 'marker vaccine' applies.     

A new inactivated BVDV genotype I and II vaccine. An immunisation and challenge study with BVDV genotype I

An inactivated vaccine containing BVDV I and II strains (PT810; BVDV I, and 890; BVDV II) and using different adjuvants and antigen dosages was tested in a cattle challenge model. Groups of six healthy, seronegative cattle were vaccinated twice with a low dose (10(6.6) TCID(50) PT810 and 10(7.2) TCID(50) 890) vaccine with the adjuvant Bay R1005 or a high dose (10(7.8) TCID(50) PT810 and 10(8. 2) TCID(50) 890) vaccine with two different adjuvants (Bay R1005 or Polygen). Thirty-eight days after the second vaccination, immunised animals (n=18) and non-vaccinated control animals (n=3) were challenged intranasally with 10(6) TCID(50) BVDV strain PT810. For a period of 16 days, virus was isolated from blood leukocytes and nasal swabs, and neutralising antibody titres were determined.The induction of antibodies following immunisation was strongly dependent on the antigen dosage in the vaccine. The high dose formulation induced high serum neutralising antibody titres against both genotypes of up to 32000 after the second immunisation. Animals with neutralising antibody titres >512 (n=14) did not show any marked leukopenia after challenge and only very little or no virus could be isolated from blood leukocytes and/or nasal swabs when compared to control cattle. Furthermore, some of these animals did not show any boost of neutralising or even NS3-specific antibodies, which renders viral replication unlikely and thus would prevent infection of the fetus. Both adjuvants (Bay R1005 or Polygen) were similarly efficient and induced nearly identical antibody responses. In contrast, four of the six low dosage vaccinates had a marked leukopenia and viraemia as well as detectable nasal virus shedding for several days.We conclude that the selected strains and the system of vaccine preparation with high BVDV antigen dosages and highly efficient new adjuvants provide an effective means of protection against BVDV I infections. Investigations to demonstrate the protection against BVDV II infections, the duration of immunity and the ability of fetal protection by using the high dose vaccine in a fetal challenge model will follow.     

A complex-trapping-blocking (CTB) ELISA, using monoclonal antibodies and detecting specifically antibodies directed against foot-and-mouth disease types A, O and C. II. Application

The complex-trapping-blocking (CTB) enzyme-linked immunosorbent assay (ELISA) was evaluated to detect antibodies directed against foot-and-mouth disease virus (FMDV) strains A10 Holland, O1 BFS, and C1 Detmold. Log10 serum titres of uninfected, unvaccinated cattle (n = 100) were less than 1.80 in the CTB-ELISA. Sera from cattle vaccinated with either monovalent or trivalent vaccines were tested in both the CTB-ELISA and the serum neutralisation test (SNT); titres in both tests correlated positively (P less than 0.001). Titres of sera from cattle, sheep, and pigs vaccinated twice with FMDV A10 Holland also correlated positively in both tests. In another experiment, cattle vaccinated with FMDV strain C1 Detmold were intradermolingually challenged 3 weeks after primary vaccination; at the same time two controls were challenged. At 8 days after challenge, serum titres of the controls were distinctly higher in the CTB-ELISA than in the SNT, whereas serum titres of the vaccinated cattle were equally high in both tests. In potency tests for monovalent vaccines against FMDV strains A10 Holland, O1 BFS or C1 Detmold, serum titres correlated strongly in both tests with protection against the homologous FMDV strain. We concluded that the CTB-ELISA is not only sensitive, but easier to perform and more rapid and reproducible than the SNT. The CTB-ELISA may be useful in evaluating the immune response in cattle during FMD vaccine potency tests.     

Seasonal variations in the formation of virus-neutralizing antibodies in cattle after vaccination against foot-and-mouth disease

The GDR in 1977 had been the first country to introduce a laboratory method for potency testing of FMD vaccines on the basis of secured correlations between titres of virus-neutralising serum antibodies of immunised cattle, on the one hand, and their probit-transformed protection against FMD, on the other. This is now the only state-registered method for potency testing. The method has ever since worked well all over the place. An evaluation of results obtained between 1982 and 1988 revealed seasonal variations of anti-FMD immunogenesis in cattle. FMD immunisations from February to July proved more effective than those performed in the rest of the year, in that higher antibody titres were built up within 14 days from vaccination. These results were confirmed by rates of protection of cattle recorded from direct potency testing of immunised animals, between 1969 and 1977.     

Genes controlling vaccine responses and disease resistance to respiratory viral pathogens in cattle

Farm animals remain at risk of endemic, exotic and newly emerging viruses. Vaccination is often promoted as the best possible solution, and yet for many pathogens, either there are no appropriate vaccines or those that are available are far from ideal. A complementary approach to disease control may be to identify genes and chromosomal regions that underlie genetic variation in disease resistance and response to vaccination. However, identification of the causal polymorphisms is not straightforward as it generally requires large numbers of animals with linked phenotypes and genotypes. Investigation of genes underlying complex traits such as resistance or response to viral pathogens requires several genetic approaches including candidate genes deduced from knowledge about the cellular pathways leading to protection or pathology, or unbiased whole genome scans using markers spread across the genome. Evidence for host genetic variation exists for a number of viral diseases in cattle including bovine respiratory disease and anecdotally, foot and mouth disease virus (FMDV). We immunised and vaccinated a cattle cross herd with a 40-mer peptide derived from FMDV and a vaccine against bovine respiratory syncytial virus (BRSV). Genetic variation has been quantified. A candidate gene approach has grouped high and low antibody and T cell responders by common motifs in the peptide binding pockets of the bovine major histocompatibility complex (BoLA) DRB3 gene. This suggests that vaccines with a minimal number of epitopes that are recognised by most cattle could be designed. Whole genome scans using microsatellite and single nucleotide polymorphism (SNP) markers has revealed many novel quantitative trait loci (QTL) and SNP markers controlling both humoral and cell-mediated immunity, some of which are in genes of known immunological relevance including the toll-like receptors (TLRs). The sequencing, assembly and annotation of livestock genomes and is continuing apace. In addition, provision of high-density SNP chips should make it possible to link phenotypes with genotypes in field populations without the need for structured populations or pedigree information. This will hopefully enable fine mapping of QTL and ultimate identification of the causal gene(s). The research could lead to selection of animals that are more resistant to disease and new ways to improve vaccine efficacy.     

O型口蹄疫抗体金标试纸盒检测免疫动物抗体效价与攻毒保护关系

本研究目的在于用O型口蹄疫金标试纸条研究免疫动物抗体效价与攻毒保护之间的对应关系以及免疫牛抗体消长规律.用金标试纸条检测了口蹄疫O型疫苗质量标准规定的牛、羊和猪免疫和攻毒血清抗体效价及不同免疫程序的牛血清效价.结果显示,当牛、猪和羊免疫血清稀释≥1∶8时,试纸条是阳性结果,表示有99％的被免疫动物属于抗体水平保护范围;被检测血清稀释≤1∶2时,是阴性结果,表示被免疫动物抗体水平属于不保护范围;血清稀释1∶2～1∶8时,是阳性结果,表示有50％的被免疫动物属于抗体水平保护范围.牛在首次免疫8周后加强免疫可以获得良好的保护率和保护时间.通过本试验确定了金标试纸条检测免疫动物抗体效价与攻毒保护之间的关系及牛加强免疫最佳的时间.     

A serological survey for antibodies against foot-and-mouth disease virus (FMDV) in domestic pigs during outbreaks in Kenya

Foot-and-mouth disease (FMD) is endemic in Kenya and has been well studied in cattle, but not in pigs, yet the role of pigs is recognised in FMD-free areas. This study investigated the presence of antibodies against FMD virus (FMDV) in pigs sampled during a countrywide random survey for FMD in cattle coinciding with SAT 1 FMDV outbreaks in cattle. A total of 191 serum samples were collected from clinically healthy pigs in 17 districts. Forty-two of the 191 sera were from pigs vaccinated against serotypes O/A/SAT 2 FMDV. Antibodies against FMDV non-structural proteins were found in sera from 30 vaccinated and 71 non-vaccinated pigs, altogether 101/191 sera (53 %), and 91 % of these (92/101) also had antibodies measurable by serotype-specific ELISAs, predominantly directed against SAT 1 with titres of 10–320. However, only five high titres against SAT 1 in vaccinated pigs were confirmed by virus neutralisation test (VNT). Due to high degree of agreement between the two ELISAs, it was concluded that positive pigs had been infected with FMDV. Implications of these results for the role of pigs in the epidemiology of FMD in Kenya are discussed, and in-depth studies are recommended.     

A peptide of foot-and-mouth disease virus serotype Asia1 generating a neutralizing antibody response, and an immunostimulatory peptide

The epitopes of the capsid of foot-and-mouth disease virus (FMDV) play important roles in the construction of highly immunogenic subunit vaccines. However few epitopes have been found for FMDV serotype Asia1. In this study we screened for epitopes of the VP1 and VP2 proteins of FMDV serotype Asia1 isolate, YNBS/58. Fragments consisting of amino acids 133-163 of VP1 and amino acids 1-33 of VP2 contained epitopes, and both induced lymphoproliferation in guinea pigs. Only the VP1 fragment induced neutralizing antibodies but the VP2 peptide dramatically increased the neutralizing antibody response induced by the VP1 peptide.     

FMDV免疫活性串联片段FA的表达及免疫原性测定

将口蹄疫病毒免疫串联片段FA克隆至原核表达载体pBAD/TOPO中,经鉴定后得到重组质粒pBAD-FA,将此重组质粒转化到受体菌TOP10中,用诱导剂阿拉伯醛糖分别以不同的浓度进行诱导,并在不同诱导时间进行采样,经处理后做SDS-PAGE、Westem blot分析.结果发现以终浓度为O.002%的阿拉伯醛糖进行诱导,4 h后表达可达到高峰,其大小约为23 kD,软件扫描结果显示,FB融合蛋白的表达量占细菌总蛋白的29.3%,能与抗FMDV抗体发生特异性反应,融合蛋白以包涵体和可溶形式存在.将融合蛋白的可溶性组分用50%Ni-NTA树脂过柱纯化并抽提融合蛋白的包涵体,经过洗涤后分别制成油乳剂疫苗,经皮下注射免疫豚鼠,用乳鼠中和试验测定豚鼠血清中和指数,并用口蹄疫病毒对豚鼠进行攻毒.结果表明,用此融合蛋白可溶部分的纯化产物和包涵体免疫豚鼠能诱导产生高滴度的中和抗体,对病毒的攻击分别提供100%和75%的免疫保护.     

Difference in protective immunity of the tongue and feet of guinea pigs vaccinated with foot-and-mouth disease virus type A12 following intradermolingual and footpad challenge

Immunity to Foot-and-Mouth Disease Virus (FMDV) type A12 was developed in guinea pigs by vaccinating them with varying doses of inactivated FMDV inoculated by different routes. Vaccinated animals and FMDV convalescent animals were then tested for differences in protective immunity by challenging each animal with 10³ median guinea pigs infectious doses of FMDV intradermally into the tongue and the heelpad of a rear foot. Protected immunity was evaluated by examining the tongue and feet for the development of vesicles. Protective immunity of the tongue was found to be different from that of the feet. This led to the finding that three levels of protective immunity (LPI) could be distinguished. Convalescent guinea pigs demonstrated the highest level of protective immunity (LPI-1). They did not develop vesicles after a tongue or heelpad challenge. The second level of protective immunity (LPI-2) was shown by animals vaccinated with high doses of FMDV. After a tongue and heelpad challenge, they developed vesicles on the inoculated heelpad, but not on the tongue. The lowest level of protective immunity (LPI-3) was shown by animals vaccinated with lower doses of FMDV. After a tongue and heelpad challenge, they developed vesicles on the tongue and the inoculated foot, but FMDV did not spread to the uninoculated feet. Anti-FMDV antibody titers could not predict the level of protective immunity. Other experimental results show that protective immunity in the heelpad is complex and more difficult to induce than that of the tongue. In addition, the results show the feasibility of using double site challenges of the tongue and a foot for measuring protective immunity in guinea pigs.     

Analysis of the quality of protection induced by a porcine influenza A vaccine to challenge with an H3N2 virus

Antigenic drift of swine influenza A (H3N2) viruses away from the human A/Port Chalmers/1/73 (H3N2) strain, used in current commercial swine influenza vaccines, has been demonstrated in The Netherlands and Belgium. Therefore, replacement of this human strain by a more recent swine H3N2 isolate has to be considered. In this study, the efficacy of a current commercial swine influenza vaccine to protect pigs against a recent Dutch field strain (A/Sw/Oedenrode/96) was assessed. To evaluate the level of protection induced by the vaccine it was compared with the optimal protection induced by a previous homologous infection. Development of fever, virus excretion, and viral transmission to unchallenged group mates were determined to evaluate protection. The vaccine appeared efficacious in the experiment because it was able to prevent fever and virus transmission to the unchallenged group mates. Nevertheless, the protection conferred by the vaccine was sub-optimal because vaccinated pigs excreted influenza virus for a short period of time after challenge, whereas naturally immune pigs appeared completely protected. The immune response was monitored, to investigate why the vaccine conferred a sub-optimal protection. The haemagglutination inhibiting and virus neutralising antibody responses in sera, the nucleoprotein-specific IgM, IgG, and IgA antibody responses in sera and nasal secretions and the influenza-specific lymphoproliferation responses in the blood were studied. Vaccinated pigs developed the same or higher serum haemagglutination inhibiting, virus neutralising, and nucleoprotein-specific IgG antibody titres as infected pigs but lower nasal IgA titres and lymphoproliferation responses. The lower mucosal and cell-mediated immune responses may explain why protection after vaccination was sub-optimal.