The production of foot-and-mouth disease virus from BHK 21 C 13 cells grown on the surface of glass spheres.

In view of the advantages which are associated with the use of the BHK monolayer cell for the production of foot-and-mouth disease (FMD) virus, a unit system using glass spheres was developed to grow BHK monolayer cells and to test the susceptibility of such cells to FMD virus. The yield of cells and their susceptibility compares favorably with GREEN BHK monolayer cells which have been grown in Roux bottles.     

Growth and immunogenicity of foot-and-mouth disease virus in baby hamster kidney cells adapted to and continuously grown in a serum-free chemically defined media

The production of foot-and-mouth disease (FMD) virus in baby hamster kidney (BHK) suspension cells grown in serum-free media for subsequent use in vaccines was attempted because of the limited availability of serum in quantities sufficient for propagation of large amounts of cells, as well as the possible presence of mycoplasma, viral contaminants, and interfering antibodies in sera. Suspension cultures (50 to 600 ml) of BHK-21 cells adapted to and continually passed in a glutamine-free autoclavable, chemically defined medium (BHK-S system) were infected with all seven types of FMD virus. Cells were infected at multiplicities of infection (MOI) ranging from 10^?1 to 10^?7 plaque-forming units per cell (PFU/cell). The time course of infectious virus release and the amount of complement-fixing (CF) antigen produced were then followed. Peak harvest infectivities of approximately 10^8.5 PFU/ml were obtained from 12 to 24 hr after inoculation, depending on input MOI, and were apparently independent of cell concentration over the range 1.5 to 4.0 million cells/ml; the CF endpoint dilutions increased from 1:12 at the lower cell concentrations to 1:48 at the highest cell concentration. Monovalent and trivalent vaccines have been produced using viruses from the BHK-S system, inactivated with acetylethyleneimine and emulsified in oil, and the results of tests in steers and guinea pigs are presented.     

Selection of a stable clone of the MVPK-1 fetal porcine kidney cell for assays of foot-and-month disease virus.

The MVPK-1 cell line, derived from fetal porcine kidney cells, supports the replication of foot-and-mouth disease (FMD) virus. The cell line was adapted to grow in medium containing 5% bovine serum. The susceptibility of the adapted cells decreased as they aged at 37 degrees C. Various clones were isolated from the adapted cells and their growth characteristics and sustained susceptibility to FMD virus were compared. Clone 7 maintained uniform susceptibility to FMD virus over a 3-day period at 37 degrees C and proved superior to other clones in the characteristics studied. The clone has maintained satisfactory susceptibility to FMD virus through 40 subcultures. Clone 7 can replace primary bovine kidney cells for routine viral assays, but cannot detect as much FMD virus in animal specimens as primary bovine kidney, bovine thyroid, or swine kidney cells.     

The production of foot-and-mouth disease virus from BHK 21 C 13 cells grown on the surface of DEAE sephadex A50 beads.

Methods are described which make possible the production of foot-and-mouth disease (FMD) virus from BHK 21 C13 monolayer cells which have been grown on the surface of serum coated DEAE Sephadex A50 beads. The yield of cells and their susceptibility to infection by FMD virus are equivalent to conventional Roux monolayer systems. The potential for the commercial application of the DEAE Sephadex A50 system is discussed in relation to other unit process monolayer systems and in particular to the system in which cells are cultured in a deep bed of small glass spheres.     

Advances in novel vaccines for foot and mouth disease: focus on recombinant empty capsids

Foot and mouth disease (FMD) is a highly contagious disease of cloven-hoofed animals, which causes severe economic losses in the livestock industry. Currently available vaccines are based on inactivated FMD virus (FMDV). Although inactivated virus vaccines have proved to be effective in FMD control, they have a number of disadvantages, including the need for high bio-containment production facilities and the lack of induction of immunological memory. Novel FMD vaccines based on the use of recombinant empty capsids have shown promising results. These recombinant empty capsids are attractive candidates because they avoid the use of virus in the production facilities but conserve its complete repertoire of conformational epitopes. However, many of these recombinant empty capsids require time-consuming procedures that are difficult to scale up. Achieving production of a novel and efficient FMD vaccine requires not only immunogenic antigens, but also industrially relevant processes. This review intends to summarize and compare the different strategies already published for the production of FMDV recombinant empty capsids, focusing on large-scale production.     

Comparative immunogenecity of foot and mouth disease virus antigens in FMD-haemorrhagic septicaemia combined vaccine and FMD vaccine alone in buffalo calves

Humoral immune response was evaluated by monitoring the serum antibody titres and virus specific IgM titres against Foot and Mouth Disease (FMD) virus antigens in serum samples obtained from different groups of calves inoculated with combined vaccine or FMD vaccine alone, on 0, 7, 14, 21, 28, 42 and 56 days post-vaccination (DPV). The cellular immune response was monitored by MTT based lymphoproliferation in peripheral blood mononuclear cell cultures. Higher liquid phase blocking (LPB) ELISA antibody titres were observed in calves receiving combined vaccine as compared to calves immunized with FMD vaccine alone with the peak titres in both the groups obtained on 21 days post-vaccination. However, the virus specific IgM titres were significantly higher in group of calves inoculated with combined vaccine than FMD vaccine alone. The lymphoproliferative responses against FMDV types O, A22 and Asia 1 in the groups receiving combined vaccine and FMD vaccine alone started increasing gradually after day 14 and reached peak levels on 28 DPV followed by a gradual decline subsequently. The group receiving combined vaccine showed higher proliferative responses on in vitro stimulation with FMD virus type O, whereas, with FMD virus type Asia 1, the responses were significantly higher on 14 and 21 DPV as compared to the group immunized with FMD vaccine alone. However, in the group receiving combined vaccine, the responses on in vitro stimulation with FMD virus type A22 were significantly higher than FMD vaccine alone group on all DPV except on 42 DPV.     

Development of novel strategies to control foot-and-mouth disease: Marker vaccines and antivirals

Foot-and-mouth disease (FMD) is economically the most important viral-induced livestock disease worldwide. The disease is highly contagious and FMD virus (FMDV) replicates and spreads extremely rapidly. Outbreaks in previously FMD-free countries, including Taiwan, the United Kingdom, and Uruguay, and the potential use of FMDV by terrorist groups have demonstrated the vulnerability of countries and the need to develop control strategies that can rapidly inhibit or limit disease spread. The current vaccine, an inactivated whole virus preparation, has a number of limitations for use in outbreaks in disease-free countries. We have developed an alternative approach using a genetically engineered FMD subunit vaccine that only contains the portions of the viral genome required for virus capsid assembly and lacks the coding region for most of the viral nonstructural (NS) proteins including the highly immunogenic 3D protein. Thus, animals inoculated with this marker vaccine can readily be differentiated from infected animals using diagnostic assays employing the NS proteins not present in the vaccine and production of this vaccine, which does not contain infectious FMDV, does not require expensive high-containment manufacturing facilities. One inoculation of this subunit vaccine delivered in a replication-defective human adenovirus vector can induce rapid, within 7 days, and relatively long-lasting protection in swine. Similarly cattle inoculated with one dose of this recombinant vector are rapidly protected from direct and contact exposure to virulent virus. Furthermore, cattle given two doses of this vaccine developed high levels of FMDV-specific neutralizing antibodies, but did not develop antibodies against viral NS proteins demonstrating the ability of FMD subunit vaccinated animals to be differentiated from infected animals. To stimulate early protection prior to the vaccine-induced adaptive immune response we inoculated swine with the antiviral agent, type I interferon, and induced complete protection within 1 day. Protection can last for 3-5 days. The combination of the FMD marker vaccine and type I interferon can induce immediate, within 1 day, and long-lasting protection against FMD. Thus, this combination approach successfully addresses a number of concerns of FMD-free countries with the current disease control plan. By rapidly limiting virus replication and spread this strategy may reduce the number of animals that need to be slaughtered during an outbreak.     

Recovery of Viral RNA and Infectious Foot-and-Mouth Disease Virus from Positive Lateral-Flow Devices

Foot-and-mouth disease Virus (FMDV) is an economically important, highly contagious picornavirus that affects both wild and domesticated cloven hooved animals. In developing countries, the effective laboratory diagnosis of foot-and-mouth disease (FMD) is often hindered by inadequate sample preservation due to difficulties in the transportation and storage of clinical material. These factors can compromise the ability to detect and characterise FMD virus in countries where the disease is endemic. Furthermore, the high cost of sending infectious virus material and the biosecurity risk it presents emphasises the need for a thermo-stable, non-infectious mode of transporting diagnostic samples. This paper investigates the potential of using FMDV lateral-flow devices (LFDs) for dry transportation of clinical samples for subsequent nucleic acid amplification, sequencing and recovery of infectious virus by electroporation. FMDV positive samples (epithelial suspensions and cell culture isolates) representing four FMDV serotypes were applied to antigen LFDs: after which it was possible to recover viral RNA that could be detected using real-time RT-PCR. Using this nucleic acid, it was also possible to recover VP1 sequences and also successfully utilise protocols for amplification of complete FMD virus genomes. It was not possible to recover infectious FMDV directly from the LFDs, however following electroporation into BHK-21 cells and subsequent cell passage, infectious virus could be recovered. Therefore, these results support the use of the antigen LFD for the dry, non-hazardous transportation of samples from FMD endemic countries to international reference laboratories.     

Validation of binary ethyleneimine (BEI) used as an inactivant for foot and mouth disease tissue culture vaccine.

The complete inactivation of Foot and Mouth Disease (FMD) virus is a critical requirement in the production of FMD vaccine to ensure the safety of the product. Binary ethyleneimine (BEI) is an aziridine compound, produced from bromoethylamine hydrobromide (BEA) commonly used for the inactivation of FMD virus during vaccine manufacturing. The validation of BEI, when used as an inactivant, is essential to ensure the quality of the inactivating agent and the validity of the process. In the present study, the inactivation kinetics of Foot and Mouth Disease virus (O, A and Asia-1 serotypes) were determined for different concentrations of BEI (0.4 mM, 0.8 mM, 1.2 mM, 1.6 mM and 2.0 mM). Statistically significant differences in the inactivation kinetics were observed between 0.4 mM and 1.6 mM of BEI. The results indicated that BEI at 1.6 mM was able to inactivate the FMD virus within 8-10 h. Increasing the concentration of BEI beyond 1.6 mM did not appreciably improve the inactivation process. No differences in the inactivation kinetics were found between the various serotypes studied. This study can be used as a guideline for routine procedures for validating the quality of BEA and the inactivation process.     

植物中表达口蹄疫病毒抗原研究进展

口蹄疫(foot-and-mouth disease,FMD)是由口蹄疫病毒(foot-and-mouth disease virus,FMDV)引起的一种急性、烈性、高度接触性传染病,严重危害畜牧养殖业健康发展。口蹄疫灭活疫苗是口蹄疫防控的主导产品,为控制口蹄疫流行起到了重要作用;但是也存在抗原不稳定、在生产制备过程中存在因病毒灭活不彻底而散毒的风险、生产成本较高等问题。与传统的微生物和动物生物反应器相比,通过转基因技术以植物作为生物反应器生产抗原蛋白,具有成本低廉、安全便捷、易于储运等一些优势,且无需蛋白提取纯化过程,可直接食用免疫;但也存在着表达量低、控制性差等问题。因此,通过植物生物反应器表达口蹄疫病毒抗原蛋白,可能是一种具有一定优势但仍需不断优化的疫苗生产手段。本文综述了在植物中表达活性蛋白的主要策略,以及通过植物生物反应器表达口蹄疫病毒抗原蛋白的研究进展,并讨论了目前面临的问题与挑战,以期为相关工作提供一定的借鉴和参考。     

Peroxynitrite reduces the endothelium-derived hyperpolarizing factor component of coronary flow-mediated dilation in PECAM-1-knockout mice

Platelet endothelial cell adhesion molecule 1 (PECAM-1) is capable of transducing signals in endothelial cells exposed to shear; however, the biological consequences of this signal transduction are unknown. Because shear stress elicits flow-mediated dilation (FMD), we examined whether steady-state FMD in mouse coronary arteries (MCAs) is affected in the PECAM-1 knockout (KO) mouse. MCAs were isolated from wild-type (WT) or KO mice and prepared for videomicroscopy, histofluorescence, Western blotting, and immunohistochemistry. FMD was examined in the absence and presence of N(omega)-nitro-l-arginine methyl ester (l-NAME) and l-NAME+indomethacin (INDO). FMD was reduced in KO relative to WT MCAs, but the l-NAME-inhibitable portion of FMD was similar between the two. The INDO-sensitive component of FMD was diminished in KO MCAs. In contrast, the residual component of dilation, presumably because of endothelium-derived hyperpolarizing factor (EDHF), was abolished in KO MCAs. Histofluorescence showed relatively more superoxide (O2-.; oxy-ethidium fluorescence) and peroxide production (dihydrochlorofluorescene fluoresecence) in KO MCAs at rest. Flow augmented O2-. and peroxide production in WT MCAs but had little effect on KO MCAs. Enhanced nitric oxide generation was observed in arteries from KO mice, accompanied with increased eNOS S1177 phosphorylation. In vessels from KO mice, treatment with ebselen decreased peroxynitrite (ONOO-) formation and improved the reduced FMD, largely due to restoration of the presumed EDHF component. These results suggest that PECAM-1 is necessary for normal FMD in the mouse coronary circulation. In the absence of this adhesion and signaling molecule, ONOO- production is increased concomitant with a reduction in both the EDHF and INDO-sensitive components of FMD.     

Immunological evaluation of mannosylated chitosan nanoparticles based foot and mouth disease virus DNA vaccine,pVAC FMDV VP1–OmpA in guinea pigs

A DNA vaccine for foot and mouth disease (FMD) based on mannosylated chitosan nanoparticles was evaluated in guinea pigs. The DNA construct was comprised of FMD virus full length-VP1 gene and outer membrane protein A (Omp A) gene of Salmonella typhimurium as a Toll-like receptor (TLR)-ligand in pVAC vector. Groups of guinea pigs immunized either intramuscularly or intra-nasally were evaluated for induction of virus neutralizing antibodies, Th1(IgG2) and Th2 (IgG1) responses, lymphocyte proliferation, reactive nitrogen intermediate production, secretory IgA for naso-mucosal immune response and protection upon homotypic type O virulent FMD virus challenge. The results indicate the synergistic effect of OmpA on the immunogenic potential of FMD DNA vaccine construct delivered using mannosylated chitosan nano-particles by different routes of administration. These observations suggest the substantial improvement in all the immunological parameters with enhanced protection in guinea pigs.     

Transmission pathways of foot-and-mouth disease virus in the United Kingdom in 2007

Foot-and-mouth disease (FMD) virus causes an acute vesicular disease of domesticated and wild ruminants and pigs. Identifying sources of FMD outbreaks is often confounded by incomplete epidemiological evidence and the numerous routes by which virus can spread (movements of infected animals or their products, contaminated persons, objects, and aerosols). Here, we show that the outbreaks of FMD in the United Kingdom in August 2007 were caused by a derivative of FMDV O(1) BFS 1860, a virus strain handled at two FMD laboratories located on a single site at Pirbright in Surrey. Genetic analysis of complete viral genomes generated in real-time reveals a probable chain of transmission events, predicting undisclosed infected premises, and connecting the second cluster of outbreaks in September to those in August. Complete genome sequence analysis of FMD viruses conducted in real-time have identified the initial and intermediate sources of these outbreaks and demonstrate the value of such techniques in providing information useful to contemporary disease control programmes.     

Typing foot-and-mouth disease virus by fluorescent antibody technique.

Typing of foot-and-mouth disease (FMD) virus was performed by the direct fluorescent antibody (FA) technique. Type-specific FA was prepared from the following two sorts of procedures: (1) FA against live virus (FA-live) was prepared from hyperimmune serum taken from guinea pigs having received live FMD virus. Then it was adsorbed with concentrated heterotype antigen. (2) FA against inactivated virus (FA-Inact) was prepared from antiserum taken from guinea pigs immunized with purified FMD virus inactivated with acetylethyleneimine. Seventeen strains of FMD virus (seven strains of type A, seven strains of type O, and three strains of thpe C) were used. Type-specific FMD virus antigen was detected distinctly from the monolayer of BHK cells infected with each type of virus and fixed in acetone, in spite of negative results obtained from the cells fixed in methyl alcohol. All the 17 strains were typed successfully by the implementation of these two FA methods.     

New Vaccine Design Based on Defective Genomes That Combines Features of Attenuated and Inactivated Vaccines

Background

New vaccine designs are needed to control diseases associated with antigenically variable RNA viruses. Foot-and-mouth disease (FMD) is a highly contagious disease of livestock that inflicts severe economic losses. Although the current whole-virus chemically inactivated vaccine has proven effective, it has led to new outbreaks of FMD because of incomplete inactivation of the virus or the escape of infectious virus from vaccine production premises. We have previously shown that serial passages of FMD virus (FMDV) C-S8c1 at high multiplicity of infection in cell culture resulted in virus populations consisting of defective genomes that are infectious by complementation (termed C-S8p260).

Principal Finding

Here we evaluate the immunogenicity of C-S8p260, first in a mouse model system to establish a proof of principle, and second, in swine, the natural host of FMDV C-S8c1. Mice were completely protected against a lethal challenge with FMDV C-S8c1, after vaccination with a single dose of C-S8p260. Pigs immunized with different C-S8p260 doses and challenged with FMDV C-S8c1 either did not develop any clinical signs or showed delayed and mild disease symptoms. C-S8p260 induced high titers of both FMDV-specific, neutralizing antibodies and activated FMDV-specific T cells in swine, that correlated with solid protection against FMDV.

Conclusions

The defective virus-based vaccine did not produce detectable levels of transmissible FMDV. Therefore, a segmented, replication-competent form of a virus, such as FMDV C-S8p260, can provide the basis of a new generation of attenuated antiviral vaccines with two safety barriers. The design can be extended to any viral pathogen that encodes trans-acting gene products, allowing complementation between replication-competent, defective forms.     

Development of DNA vaccines for foot-and-mouth disease, evaluation of vaccines encoding replicating and non-replicating nucleic acids in swine.

We have developed naked DNA vaccine candidates for foot-and-mouth disease (FMD), an important disease of domestic animals. The virus that causes this disease, FMDV, is a member of the picornavirus family, which includes many important human pathogens, such as poliovirus, hepatitis A virus, and rhinovirus. Picornaviruses are characterized by a small (7-9000 nucleotide) RNA genome that encodes capsid proteins, processing proteinases, and enzymes required for RNA replication. We have developed two different types of DNA vaccines for FMD. The first DNA vaccine, pP12X3C, encodes the viral capsid gene (P1) and the processing proteinase (3C). Cells transfected with this DNA produce processed viral antigen, and animals inoculated with this DNA using a gene gun produced detectable antiviral immune responses. Mouse inoculations with this plasmid, and with a derivative containing a mutation in the 3C proteinase, indicated that capsid assembly was essential for induction of neutralizing antibody responses. The second DNA vaccine candidate, pWRMHX, encodes the entire FMDV genome, including the RNA-dependent RNA polymerase, permitting the plasmid-encoded viral genomes to undergo amplification in susceptible cells. pWRMHX encodes a mutation at the cell binding site, preventing the replicated genomes from causing disease. Swine inoculated with this vaccine candidate produce viral particles lacking the cell binding site, and neutralizing antibodies that recognize the virus. Comparison of the immune responses elicited by pP12X3C and pWRMHX in swine indicate that the plasmid encoding the replicating genome stimulated a stronger immune response, and swine inoculated with pWRMHX by the intramuscular, intradermal, or gene gun routes were partially protected from a highly virulent FMD challenge.     

Transient Gene Expression in Serum-Free Suspension-Growing Mammalian Cells for the Production of Foot-and-Mouth Disease Virus Empty Capsids

Foot-and-mouth disease (FMD) is a highly contagious disease of cloven-hoofed animals. It produces severe economic losses in the livestock industry. Currently available vaccines are based on inactivated FMD virus (FMDV). The use of empty capsids as a subunit vaccine has been reported to be a promising candidate because it avoids the use of virus in the vaccine production and conserves the conformational epitopes of the virus. In this report, we explored transient gene expression (TGE) in serum-free suspension-growing mammalian cells for the production of FMDV recombinant empty capsids as a subunit vaccine. The recombinant proteins produced, assembled into empty capsids and induced protective immune response against viral challenge in mice. Furthermore, they were recognized by anti-FMDV bovine sera. By using this technology, we were able to achieve expression levels that are compatible with the development of a vaccine. Thus, TGE of mammalian cells is an easy to perform, scalable and cost-effective technology for the production of a recombinant subunit vaccine against FMDV.     

Inhibition of foot-and-mouth disease virus infections in cell cultures with antisense morpholino oligomers

Foot-and-mouth disease (FMD) is a highly contagious viral disease of cloven-hoofed ungulates that can lead to severe losses in the livestock production and export industries. Although vaccines have been extensively used to control FMD, there is no antiviral therapy available to treat ongoing infections with FMD virus (FMDV). Six peptide-conjugated morpholino oligomers (PPMOs) with sequences complementary to various 21-nucleotide segments of the 5' and 3' untranslated regions (UTRs) of the FMDV genome (strain A(24) Cruzeiro/Brazil/1955 [A(24)Cru]) were evaluated in cell cultures. Three of the PPMOs, targeting domain 5 of the internal ribosome entry site (5D PPMO), and the two translation start codon regions (AUG1 and AUG2 PPMOs), showed high levels of anti-FMDV activity. A dose-dependent and sequence-specific reduction in viral titers of greater than 5 log(10), with a concomitant reduction of viral protein and RNA expression, was achieved at low micromolar concentrations. Under identical conditions, three other PPMOs targeting the 5'-terminal region of the genome, the cis-acting replication element in the 5' UTR, and the 3' "ab" stem-loop showed less dramatic titer reductions of 1.5 log(10) to 2 log(10). Treatment with 5D PPMO reduced the titers of FMDV strains representing five different serotypes by 2 log(10) to 4 log(10) compared to those of the controls. A(24)Cru-infected BHK-21 cells treated repeatedly with 5D or AUG2 PPMO generated resistant viruses for which phenotypic and genotypic properties were defined. Notably, three passages with low concentrations of the AUG1 PPMO extinguished all traces of detectable virus. The results indicate that PPMOs have potential for treating FMDV infections and that they also represent useful tools for studying picornaviral translation and evolution.     

Preparation of FMD type A87/IRN inactivated vaccine by gamma irradiation and the immune response on guinea pig

FMD is one of the most economically damaging diseases that affect livestock animals. In this study FMD Virus type A87/IRN was multiplied on BHK21 cells. The virus was titrated by TCID50 method, it was 10^7.5/ml. The FMD virus samples were inactivated by gamma ray from 60Co source at −20°C. Safety test was done by IBRS2 monolayer cell culture method, also antigenicity of irradiated and un-irradiated virus samples were studied by Complement Fixation Test. The Dose/Survival curve for irradiated FMD Virus was drawn, the optimum dose range for inactivation of FMDV type A87/IRN and unaltered antigenicity was obtained 40–44 kGy. The inactivated virus samples by irradiation and ethyleneimine (EI) were formulated respectively as vaccine with Al(OH)3 gel and other substances. The vaccines were inoculated to Guinea pigs and the results of Serum Neutralization Test for the normal vaccine and radio-vaccine showed protective titer after 8 months. The potency test of the inactivated vaccines was done, PD50 Value of the vaccines were calculated 7.06 and 5.6 for inactivated vaccine by EI and gamma irradiation respectively.     

Embryo transfer as a means of controlling the transmission of viral infections. XIII. Failure to transmit foot-and-mouth disease virus through the transfer of embryos from viremic donors

A total of 436 embryos/unfertilized ova was collected from 30 foot-and-mouth disease (FMD) viremic cattle; 106 of these embryos/ova were from eight donors that had FMD virus in their reproductive tracts. The 436 embryos/ova were washed and then either assayed in cell culture or intradermally in steer tongues or transferred to recipients. Foot-and-mouth infectivity was not found to be associated with any of the embryos/ova assayed in cell culture or intradermally. The 149 embryos transferred produced two abortions, five sets of twins born prematurely, and 15 normal calves. All of the recipients and all of the calves remained FMD-seronegative.