Recombinant vaccinia virus expression of the bovine leukaemia virus envelope gene and protection of immunized sheep against infection.

The bovine leukaemia virus (BLV) envelope gene encoding extracellular glycoprotein gp51 and transmembrane glycoprotein gp30 was cloned into the HA locus of vaccinia virus (Copenhagen strain), downstream of the vaccinia virus early-late promoter, H6, or a triple promoter element consisting of the promoter for the vaccinia virus H6 gene, the promoter for the cowpox virus A-type inclusion (ATI) gene and the promoter for the vaccinia virus HA gene. Inoculation of rabbits or sheep with the recombinant vaccinia virus coding for gp51 and gp30 or an uncleaved env precursor induced neutralizing antibodies to BLV. These antibodies competed with monoclonal antibodies directed against gp51 epitopes F, G, and H previously shown to be of crucial importance for BLV infection. Seven out of eight sheep vaccinated with the vaccinia recombinants resisted a drastic challenge (1.5 x 10(3) sheep infectious doses) with BLV-infected lymphocytes. These results show that vaccination with BLV env vaccinia recombinants protects sheep against infection with extremely high doses of BLV-infected heterologous lymphocytes.     

Immunogenicity of a recombinant vaccinia virus expressing envelope a glycoprotein of bovine leukaemia virus

We constructed a recombinant vaccinia virus (RVV) expressing envelope (env) glycoprotein (gp51) of bovine leukaemia virus (BLV): the expression of gp51 was detected by Western blot of the lysates of rabbit kidney cells infected with the RVV. The rabbits inoculated intradermally with the RVV alone failed to induce detectable anti-gp51 antibodies even 10 weeks after immunization. However, when these animals were boosted with inactivated BLV virion in saline, significant levels of anti-gp51 antibodies were induced as shown both in Western blot and immunodiffusion analyses. In these animals, antibodies against gag product (p24) were not detected. On the other hand, the rabbits inoculated with wild-type vaccinia virus and boosted similarly three times with the BLV virion in saline did not induce detectable anti-gp51 antibodies at all. The present experiment revealed that the RVV possessed the capability to endow immunological memory without inducing apparent anti-gp51 antibody responses, meaning that the RVV activated helper T cells far more strongly than B cells. The applicability of the RVV to vaccine development is discussed.     

Compatibility of a live infectious bovine rhinotraheitis (IBR) marker vaccine and an inactivated bovine viral diarrhoea virus (BVDV) vaccine

The target animals and vaccination regimes for vaccines against the bovine rhinotracheitis (IBR) and the bovine viral diarrhoea virus (BVDV) are very similar. Therefore, we have compared different schedules for the combined use of a live IBR marker vaccine and an inactivated BVD vaccine. The neutralizing antibody response against BVDV did not reveal any differences between the group vaccinated only with the BVD vaccine and the groups that were vaccinated simultaneously (together in the same syringe) or concurrently (two separate injections) with the IBR marker vaccine at the first or second dose and the third dose of the BVD vaccine. Likewise, the bovine herpesvirus 1 (BHV-1) neutralizing antibody titres did not exhibit any negative effect by the simultaneous or concurrent use of the two products as compared to the single IBR marker vaccination. These results indicate that the two vaccines can be applied at the same day for the first or second dose of the BVD basic vaccination and then at the booster vaccinations (third dose onwards).     

Evaluation of the induction of NS3 specific BVDV antibodies using a commercial inactivated BVDV vaccine in immunization and challenge trials

In order to evaluate whether cattle vaccinated with an inactivated vaccine against bovine viral diarrhoea virus (BVDV) can be differentiated serologically from BVDV infected animals, two different aspects were investigated. Firstly the antibody response against non-structural proteins (NS) was measured after multiple vaccinations of cattle with a single or double dose of a commercially available inactivated BVDV vaccine. In a second study, the animals were first vaccinated with the product, and then infected with BVDV. The antibody response was determined in four different commercial ELISA systems. It can be concluded, that the inactivated BVD vaccine exhibits properties of a marker vaccine when an appropriate antibody NS3 ELISA is applied: after vaccination NS3-specific antibody levels are low or undetectable, but the vaccination does in the present study not show any interference with the development of antibodies against NS3 after subsequent field virus infection.     

Bovine leukosis: an example of poor disease monitoring of international livestock shipments to developing countries

Over the past few years, cattle imported into a number of countries have been shown to carry antibodies against bovine leukosis virus (BLV), the cause of enzootic bovine leukosis. The disease, imported into England via shipments of Canadian dairy cattle in the late 1970s, is still a significant problem in the United Kingdom. Many countries now require a blood test for serum antibodies to BLV as a precondition of shipment from certain endemic countries. Those cattle positive for BLV are excluded from shipment. Well-documented cases of shipments of hundreds of Canadian cattle without testing for BLV has been obtained. These shipments were to the African country of Malawi where the BLV status is unknown. Also, although the United States is endemic for BLV, most of the recent live cattle exports were received by countries which did not require a blood test for BLV. Of the 44 countries that imported U.S. cattle during 1982 and 1983, only 13 required BLV antibody testing before shipment. This report concerns one disease in one species. The millions of livestock shipped yearly between the countries of the world may harbor many viruses at risk of being introduced into susceptible animal populations. While international animal health agencies are doing a credible job of providing disease surveillance to member countries, there still needs to be improvements in disease information dissemination.     

Evaluation of the immune response and protective effects of rhesus macaques vaccinated with biodegradable nanoparticles carrying gp120 of human immunodeficiency virus

We previously reported that biodegradable amphiphilic poly(γ-glutamic acid) nanoparticles (NPs) carrying the recombinant gp120 env protein of the human immunodeficiency virus type 1 (HIV-1) were efficiently taken up by dendritic cells, and induced strong CD8⁺ T cell responses against the gp120 in mice. To evaluate gp120-carrying NPs (gp120-NPs) as a vaccine candidate for HIV-1 infection, we vaccinated rhesus macaques with these gp120-NPs and examined the immune response and protective efficacy against a challenge inoculation of simian and human immunodeficiency chimeric virus (SHIV). We found that gp120-NP vaccination induced stronger responses for both gp120-specific cellular and humoral immunity than gp120-alone vaccination. After the challenge inoculation with SHIV, however, the peak value of viral RNA in the peripheral blood was higher in the vaccinated groups, especially the gp120-NP vaccinated group, than naive control group. Higher value of viral load was also maintained in gp120-NP vaccinated group. Furthermore, CD4⁺ T cells from the peripheral blood decreased more in the vaccinated groups than the control group. Thus, induced immune responses against gp120 enclosed in NPs were not effective for protection but, conversely enhanced the infection, although the gp120-NPs showed a stronger induction of immune responses against the vaccinated antigen in rhesus macaques. These results support the importance of determining immune correlate of protective immunity for vaccine development against HIV-1 infection.     

Impact of prior flavivirus vaccination on immunogenicity and efficacy of an inactivated Zika vaccine in Indian rhesus macaques

Flaviviruses are antigenically related. We evaluated the immunogenicity and efficacy of Takeda’s purified inactivated Zika vaccine (PIZV) candidate in macaques previously vaccinated with several commercially available heterologous flavivirus vaccines. Heterologous flavivirus vaccination did not elicit Zika virus (ZIKV) neutralizing antibodies and did not impact neutralizing antibody titers after one dose of PIZV. After a second PIZV dose previous vaccination with flavivirus vaccines had variable impact on ZIKV neutralizing antibody titers. However, all macaques were protected against viremia after Zika virus challenge 8–12 months post-PIZV vaccination. Therefore, vaccine-induced immunity against heterologous flavivirus vaccines does not impact PIZV efficacy in macaques.     

Broad HIV-1 neutralizing antibody response induced by heterologous gp140/gp145 DNA prime-vaccinia boost immunization

Objective

To develop an effective HIV vaccine strategy that can induce cross-reactive neutralizing antibody.

Methods

Codon-optimized gp140 and gp145 env genes derived from HIV-1_cn54, a CRF07 B′/C recombinant strain, were constructed as DNA and recombinant Tiantan vaccinia (rTV) vaccines. The effect of heterologous immunization with gp140 and gp145 was tested in mice and guinea pigs. T cell responses were detected using the IFN-γ ELISPOT assay. A panel of primary isolates of clade B′ and B′/C HIV-1 and TZM-bl cells was used to determine the neutralizing activity of immunized sera.

Results

The neutralizing antibodies (NAbs) induced by the heterologous immunogen immunization neutralized all HIV-1 B′ and B′/C primary isolates in the guinea pig model. Gp145 and gp140 heterologous prime-boost induced the best neutralizing antibody response with a broad neutralizing spectrum and the highest titer of 1:270 at 6 weeks after the last inoculation. However, the T cell response to HIV-1 peptides was significantly weaker than the gp145 + gp145 homologous prime-boost.

Conclusions

This heterologous prime-boost immunization strategy could be used to design immunogen-generating broad neutralizing antibodies against genetic variance pathogens.     

An inactivated bovine virus diarrhoea virus (BVDV) type 1 vaccine affords clinical protection against BVDV type 2

This study was designed to answer to two distinct questions. Firstly, is it possible to reproduce clinical signs of acute bovine virus diarrhoea virus (BVDV) type 2 infection including signs of haemorrhagic disease under experimental conditions in cattle at 20 weeks of age? Secondly, what is the extent of the protection afforded by vaccination with an inactivated BVDV type 1 vaccine against BVDV type 2 infection? Calves were vaccinated at 12 and 16 weeks of age with a commercially available inactivated BVDV type 1 vaccine (Bovilis BVD). At 20 weeks they were challenge infected with BVDV type 2 virus together with unvaccinated control calves. The unvaccinated animals developed typical signs of respiratory disease, diarrhoea with erosions and haemorrhages along the whole length gastro-intestinal tract, and depletion of lymphocytes in lymphatic organs. These signs were either absent or markedly less severe in the vaccinated animals. The beneficial effects of vaccination were most striking in the haematological parameters thrombocytopenia and leukopenia. It can be concluded that vaccination with Bovilis BVD affords cross-protection against clinical effects of a challenge-infection with heterologous type 2 BVDV.     

Evaluation of immunosuppressive effect and efficacy of an improved-potency feline leukaemia vaccine

An inactivated feline leukaemia vaccine was tested to determine if process improvements would permit it to be effectively used in a two-dose primary regimen versus the three-dose regimen required for a previous vaccine. Twenty-five cats were vaccinated with two subcutaneous doses given 3 weeks apart. Vaccinates and controls were artificially immunosuppressed to enhance susceptibility to challenge, and inoculated with virulent feline leukaemia virus (FeLV) 2 weeks after the second dose. Following challenge, seven (28%) vaccinates became persistently viraemic, versus six (60%) controls. Nine (36%) other vaccinates became transiently viraemic and nine were aviraemic. The mean postvaccination ELISA gp70 antibody value was 0.796 for aviraemic vaccinates, 0.575 for transiently viraemic vaccinates, and 0.350 for persistently viraemic vaccinates. Eighteen of 25 vaccinates had a postvaccination antibody response greater than or equal to 32 to feline oncornavirus associated cell membrane antigen. Seven of 25 (28%) vaccinates developed postvaccination virus neutralization (VN) antibody titres, and 16 of 25 (64%) developed postchallenge VN antibody titres. One of 10 controls developed postchallenge VN antibody titres. An in vitro lymphocyte blastogenesis assay to evaluate immunosuppressive effects of vaccination revealed no significant difference in the mean stimulation index for vaccinates versus controls. Results indicated that vaccination with two doses was an effective immunoprophylactic regimen in the face of FeLV challenge severe enough to produce persistent viraemia in 60% of non-vaccinated controls.     

Comparison of immune responses after intra-typic heterologous and homologous vaccination against foot-and-mouth disease virus infection in pigs

This study compares the immune responses and protection induced by intra-typic heterologous vaccination with that induced by homologous vaccination against challenge with foot-and-mouth disease virus (FMDV). Humoral and cell-mediated immune responses and protection against challenge with FMDV O Taiwan were examined in a non-vaccinated group, a group vaccinated with O Taiwan FMD vaccine and a group vaccinated with O Manisa FMD vaccine. Five pigs from each group were challenged with FMDV type O Taiwan 14 days after vaccination and five other pigs were contact-exposed to the inoculated pigs. Both homologous and heterologous vaccination protected against challenge with FMDV O Taiwan at 2 weeks after vaccination. In the heterologous vaccinated group, cross-neutralizing antibody titres against O Taiwan could be detected although the ratio 'r(1)' was 0.4, which was significantly smaller than the critical r-value. Cell-mediated immune responses were detected after both homologous and heterologous vaccination. Virus-induced in vitro lymphocyte (cross-) proliferation and production of both a Th1-type (IFN-gamma) and a Th2-type (IL-10) cytokine response were demonstrated in cultures of peripheral blood mononuclear cells (PBMC). The findings show that heterologous (emergency) vaccination can prevent clinical disease and shedding of virus. The induction of the cell-mediated immune responses after (heterologous) vaccination needs more research but data on these responses might provide additional tools for both vaccine choice and vaccine development.     

Construction of chimeric bovine viral diarrhea viruses containing glycoprotein E rns of heterologous pestiviruses and evaluation of the chimeras as potential marker vaccines against BVDV

Bovine viral diarrhea virus (BVDV) infections are enzootic in the cattle population and continue to cause significant economic losses to the beef and dairy industries worldwide. Extent of the damages has stimulated increasing interest in control programs directed at eradicating BVDV infections. Use of a BVDV marker vaccine would facilitate eradication efforts as a negatively marked vaccine would enable differentiation of infected from vaccinated animals (DIVA). We describe here the construction of three chimeric BVDVs containing glycoprotein E(rns) of heterologous pestiviruses and the evaluation of the chimera viruses as potential marker vaccines against BVDV infections. Chimeric NADL/G-E(rns), NADL/R-E(rns), and NADL/P-E(rns) were constructed by replacing the E(rns) gene of the full-length BVDV (NADL strain) genome with the E(rns) genes of giraffe (G-E(rns)), reindeer (R-E(rns)), or pronghorn antelope (P-E(rns)) pestiviruses, respectively. Each chimeric NADL virus was viable and infectious in RD 420 (bovine testicular) and BK-6 (bovine kidney) cells. By immunohistochemistry assays, NADL/G-E(rns) and NADL/R-E(rns) chimeric viruses reacted to BVDV E(rns) specific monoclonal antibody (mAb) 15C5, whereas the NADL/P-E(rns) chimeric virus did not. In an animal vaccination study, inactivated vaccines made from two chimeric viruses and the wild type NADL BVDV induced similar neutralizing antibody responses. NADL/P-E(rns)-vaccinated animals were distinguished from animals vaccinated with the wild type virus by means of a companion serological DIVA assay. These results show that chimeric NADL/P-E(rns) virus containing the E(rns) gene of pronghorn antelope pestivirus could be a potential marker vaccine candidate for use in a BVDV control and eradication program.     

Detection of genotype 1 bovine leukemia virus from a C.schultzei pool: Do Culicoides spp. have a role on the transmission of bovine leukemia virus?

Bovine leukemia virus (BLV) is known as the etiological agent of Enzootic bovine leukosis (EBL), which is the most common neoplastic disease of cattle. While the major route of virus transmission is believed to be iatrogenic, BLV proviral DNA has been identified in biological materials, including nasal secretions, saliva, milk, colostrum, and semen, and in several insect species, including horses flies. However, insects' role in the natural transmission of BLV has not been clearly demonstrated. This study assessed the possible role of midges – Culicoides spp. – in BLV transmission. BLVs were genetically characterized and BLV infection seroprevelance was determined in 224 cattle sampled from 27 different small family herds in five different districts in Hatay province, southern Turkey. Out of the 25 Culicoides spp. pools, one (4.0%; 1/25) was a C.schultzei pool while 2.67% (6/224) of the sampled cattle were positive for BLV nucleic acid. The seroprevalance rates for the sampled herds and all sampled cattle were 7.40% (2/27) and 1.33% (3/224), respectively. According to the phylogenetic analysis, the sequences of the BLVs from the cattle (n = 6) and the one BLV-positive C.schultzei pool clustered on genotype 1 (G1) BLVs. Although these results do not reveal the exact role of Culicoides spp. or other midges flies in BLV transmission, the simultaneous presence of same substitions in BLVs from both cattle and a C.schultzei pool is noteworthy. Further studies on the env gene and other BLV gene regions detected from cattle and C.schultzei pools are ongoing to understand the possible epidemiological relationship between cattle and flies.     

Influenza virus ISCOMs: antibody response in animals

A monovalent experimental ISCOM vaccine has been prepared with the envelope glycoproteins haemagglutinin and neuraminidase of the equine virus strain A/Solvalla/79 (H3N8). In vaccination trials on BALB/c mice the ISCOM vaccine induced more than ten times higher serum antibody titres measured in ELISA than a corresponding experimental micelle vaccine. Similarly, in guinea-pigs the ISCOMs induced about tenfold higher haemagglutination inhibition (HI) and neuraminidase inhibition (NI) titres than a micelle vaccine or a conventional killed influenza whole virus vaccine. Horses vaccinated with a divalent experimental ISCOM vaccine, containing the equine strains A/Prague/56 (H7N7) and A/Solvalla/79 (H3N8), responded with ELISA antibody titres against haemagglutinin which were higher and lasted considerably longer than those in horses vaccinated with conventional whole virus vaccine. ISCOMs induced complete immunoprotection in mice vaccinated with a dose of 1 microgram envelope glycoproteins of the mouse pathogenic strain A/PR/8/34 (H1N1).     

Interference in the vaccination of cattle against rinderpest virus by antibodies against peste des petits ruminants (PPR) virus

The ability of the attenuated vaccine 75/1 of peste des petits ruminants to interfere with rinderpest vaccination in cattle was investigated experimentally. Young cattle (93) were selected and tested as being negative for antibodies against RP or PPR viruses. These were vaccinated with the peste des petits ruminants attenuated vaccine strain PPR75/1. All animals produced specific antibodies against the peste des petits ruminants vaccine after one or two doses. The cattle were then vaccinated with attenuated rinderpest vaccine. Two months later, 88 of these animals were sampled and 21/88 were positive for antibodies specific for rinderpest. The 67 negative animals received a second rinderpest vaccine dose after which 31seroconverted. The 36 animals which failed to seroconvert were re-vaccinated, of these 28 seroconverted. This study highlights the interference by peste des petits ruminants vaccination, presumably through production of antibodies that cross react with the live rinderpest virus in the vaccine used. This interference is also observed after vaccination against rinderpest followed by subsequent administration of peste des petits ruminants vaccine.     

Bovine viral diarrhea virus types 1 and 2 antibody response in calves receiving modified live virus or inactivated vaccines

Serums from calves receiving eight different commercial vaccines containing modified live virus (MLV) or inactivated bovine viral diarrhea virus (BVDV) immunogens were assayed for antibodies to types 1 and 2 BVDV strains. The immune response to the types 1 and 2 BVDV strains were evaluated in 48 calves receiving one of the eight vaccines for each group. For 7/8 vaccines, the BVDV vaccine immunogen was only type 1 whereas the remaining vaccine contained both types 1 and 2 immunogens. Calves administered MLV vaccine received only one dose at day 0, whereas those calves receiving the inactivated vaccines were administered two doses initially at days 0 and 28. Selected calves were revaccinated with only one dose at day 140. Animals vaccinated with type 1 vaccines developed titers to a broad range of type 1 BVDV, both cytopathic (CP) and noncytopathic (NCP) biotypes, with lower titers evident to type 2 BVDV strains. For some animals, the BVDV serum antibodies did not persist. Revaccination at day 140 induced a significant four-fold increase in animals with intermediate to low antibody titers. There did not appear to be any clear differences in antibody responses between type 1 MLV or inactivated vaccines. The calves receiving the inactivated vaccine containing types 1 and 2 had similar antibody levels to both types.     

No significant differences in the breadth of the foot-and-mouth disease serotype A vaccine induced antibody responses in cattle,using different adjuvants,mixed antigens and different routes of administration

Inactivated whole virus foot-and-mouth disease (FMD) vaccines are used worldwide for protection against FMD, but not all vaccines induce protection against all genetic variants of the same FMD virus serotype. The aim of this study is to investigate whether the “breadth” of the antibody response against different strains of the same FMD virus serotype in cattle could be improved by using a different adjuvant, a mix of antigens and/or different routes of administration. To this end, six groups of five cattle were vaccinated with different FMD virus serotype A strain vaccines formulated with Montanide ISA 206 VG adjuvant. Antibody responses for homologous and heterologous cross-reactivity against a panel of 10 different FMD virus serotype A strains were tested by a liquid-phase blocking ELISA. Results of cattle vaccinated with ISA 206 VG adjuvanted vaccine were compared with results obtained in a previous study using aluminium hydroxide-saponin adjuvant. No significant effect of adjuvant on the breadth of the antibody response was observed, neither for mixing of antigens nor for the route of administration (subcutaneous vs. intradermal). Comparison of antigen payload, however, increased both homologous and heterologous titres; a 10-fold higher antigen dose resulted in approximately four times higher titres against all tested strains. Our study shows that breadth of the antibody response depends mainly on the vaccine strain; we therefore propose that, for vaccine preparation, only FMD virus strains are selected that, among other important characteristics, will induce a wide antibody response to different field strains.     

Evaluation of cross-protection between O1 Manisa and O1 Campos in cattle vaccinated with foot-and-mouth disease virus vaccine incorporating different payloads of inactivated O1 Manisa antigen

Serology is used to predict vaccine induced protection against challenge with a heterologous strain of the same serotype of foot-and-mouth disease virus (FMDV). To evaluate the accuracy of such predictions, we compared the protection afforded to cattle vaccinated with the O₁ Manisa strain of FMDV against challenge with either a homologous (O₁ Manisa) or a heterologous strain (O₁ Campos). Serology by virus neutralization test (VNT) using O₁ Manisa antiserum predicted an acceptable protection against such a challenge. Two experiments were carried out to compare the results for consistency. A total of 78 naïve cattle were vaccinated with different antigen payloads (60-0.94 μg) of O₁ Manisa. They were challenged by intradermolingual inoculation with live FMDV, either O₁ Manisa or O₁ Campos. Unvaccinated naïve control cattle (n = 20) were also challenged with either the O₁ Manisa or O₁ Campos viruses and all developed generalized FMD. The protection results for the vaccinated cattle revealed that higher payloads of O₁ Manisa vaccine were needed to protect against heterologous challenge compared to that for homologous challenge. The 50% protective dose (PD₅₀) values for the vaccine in experiments 1 and 2 were found to be 28.78 and 9.44 for the homologous challenge and 3.98 and 5.01 for heterologous challenge. Furthermore, protection against O₁ Campos required a higher level of vaccine-induced antibody against this virus compared to the level of O₁ Manisa neutralizing antibody associated with protection against homologous challenge. The 50% protective level of in vitro neutralizing antibody was found to be log₁₀ 1.827 for O₁ Campos and log₁₀ 0.954 for O₁ Manisa based on O₁ Manisa based virus neutralization test.     

Oral vaccination with inactivated influenza vaccine induces cross-protective immunity

Oral vaccination would provide an easy and safe measure to prevent infectious diseases by facilitating mass immunization. We investigated the feasibility of oral vaccination with inactivated whole influenza virus (A/PR8/34). Oral vaccination of mice induced high levels of serum IgG and IgA antibodies specific to the homologous virus (A/PR8) as well as cross reactive to heterologous (A/California/04/09) and heterosubtypic viruses (A/Philippines/2/82). IgG1 isotype antibodies were found to be induced at significantly higher levels than IgG2a antibodies. These antibodies induced by oral vaccination exhibited hemagglutination inhibition activities. High levels of both IgG and IgA antibodies were induced in vagina and lungs. Mucosal IgA antibodies were also elicited in other sites including saliva, urine, and fecal samples. Orally vaccinated mice were completely protected against challenge with homologous or heterologous viruses, and partially protected against heterosubtypic virus. Importantly, high recall antibody secreting cell (ASC) responses were induced in spleen, indicating the generation of memory B cells by oral vaccination. The present study therefore presents new findings of cross-reactive antibodies at systemic and diverse mucosal sites, recall antibody responses, and cross-protective efficacies by oral vaccination, thus supporting a proof-of-concept that oral delivery of vaccines can be developed as an effective vaccination route.