Sialic acid acts as a receptor for equine rhinitis A virus binding and infection.

Equine rhinitis A virus (ERAV) is a member of the genus Aphthovirus, family Picornaviridae, and causes respiratory disease in horses worldwide. To characterize the putative receptor molecule(s) of the ERAV isolate 393/76 (ERAV.393/76) on the surface of Vero and other cells, an assay was developed to measure the binding of purified biotinylated ERAV.393/76 virions to cells by flow cytometry. Using this assay, the level of binding to different cell types correlated with the relative infectivity of ERAV in each cell type. In particular, equine fetal kidney cells, mouse fibroblast cells, rabbit kidney-13 and Crandell feline kidney cells bound virus at high levels and produced high virus yields (> or =10(7) TCID50 ml(-1)). Madin-Darby bovine kidney and baby hamster kidney cells showed little or no binding of virus, producing yields of < or =10(1.8) TCID50 ml(-1). Treatment of Vero and other cells with sodium periodate and the metabolic inhibitors tunicamycin, benzyl N-acetyl-alpha-D-galactosamide, D,L-threo-1-phenyl-2-decanoylamino-3-morpholino-1-propanol and proteases indicated that part of the receptor-binding and entry complex for ERAV.393/76 is on N-linked carbohydrates and that the carbohydrate is likely to be present on a protein rather than a lipid backbone. The effect of carbohydrate-specific lectins and neuraminidases on ERAV.393/76 binding and infection of Vero and other cell types implicated alpha2,3-linked sialic acid residues on the carbohydrate complex in the binding and infection of ERAV.

The role of management segregations in controlling intra-herd foot-and-mouth disease.

Transmission of foot-and-mouth disease virus (FMDV) by aerosol spread can occur over considerable distances. However, this is less effective in hot, dry environmental conditions, and a detailed study of an outbreak within a large dairy herd in Saudi Arabia has shown that contact spread is the main mode of transmission within a herd: both physical and spatial barriers curtailed the course of disease across the farm. Hence, the speed and path of an outbreak can be altered by changing the positioning of spatial or physical barriers. Extending the distances between pens, increasing the number of farm pens, decreasing the number of animals within the pens, and placing pens of well-protected stock between those of susceptible stock, can all contribute to the control of FMD involving contact and short-distance aerosol spread. Such management techniques offer a cost-effective supplement to control by vaccination.

Ring vaccination.

Based on the description of an outbreak of foot-and-mouth disease (FMD), a particle model is developed describing the most important properties of this epidemic. Also control measures (mass and ring vaccination) are implemented. This model shows the expected behavior in simulations. Since it is impossible to treat this model analytically, we use ideas of branching processes on two levels to derive a caricature of the particle model. In simulations it is shown that this caricature exhibits similar behavior as the particle system. It is possible to analyze the caricature and, in this way, to obtain expressions for the most important quantities like the reproduction number or the expected final number of infected individuals etc. In this way mass vaccination and ring vaccination can be compared and control strategies can be optimized.

Development of replication-defective adenovirus serotype 5 containing the capsid and 3C protease coding regions of foot-and-mouth disease virus as a vaccine candidate.

A recombinant replication-defective human adenovirus serotype 5 vector containing FMDV capsid, P1-2A, and viral 3C protease coding regions was constructed. Two viral clones were isolated, Ad5-P12X3CWT, containing the wild-type (WT) 3C protease that processes capsid polyprotein precursor into mature capsid proteins, and Ad5-P12X3CMUT, containing a point mutation in the protease coding region that inhibits processing. In 293 cells infected with either virus, synthesis of the FMDV capsid polyprotein precursor occurred, but processing of the polyprotein into structural proteins VP0, VP3, and VP1 occurred only in 3CWT virus-infected cells. Immunoprecipitation with monospecific and monoclonal antibodies indicates possible higher order structure formation in Ad5-P12X3CWT virus-infected cells. The viruses were used to elicit immune responses in mice inoculated intramuscularly (im). Only virus containing the 3CWT elicited a neutralizing antibody response. After boosting, this neutralizing antibody response increased. Swine inoculated im with Ad5-P12X3CWT virus developed a neutralizing antibody response and were either completely or partially protected from contact challenge with an animal directly inoculated with virulent FMDV. This adenovirus vector may be an efficient system for the delivery of FMDV cDNA into animals, leading to a high level of neutralizing antibody production and protection from FMDV challenge.

The Prussian state and microbiological research--Friedrich Loeffler and his approach to the "invisible" virus.

When Loeffler took his first steps in the newly-emerging field of virology, the aim and the methods of his research activities were influenced by two different issues: 1) Loeffler was rooted in the scientific paradigm of bacteriology, but during the progress of his research on foot-and-mouth-disease (FMD) he recognized that the classical techniques derived from bacteriology were useless in identifying the agent of this disease. Thus he focussed on the properties of the pathogen and--though he could not find a method in order to visualize the 'virus'--he tried to develop a vaccine against the disease. 2) The Prussian Government was highly interested in effectively combatting FMD. In 1897 Loeffler was appointed by the Ministry of Cultural Affairs to the newly-established commission for exploring that disease. The agricultural lobbies and the public pursued the activities of the commission with a mixture of hope and serious scepticism and demanded convincing results. These circumstances caused a considerable degree of political pressure on Loeffler, pressure which determined that his research activities would take a pragmatic approach, that he would avoid sophisticated reflections and trials on the nature of the 'virus', and that his research strategies would have as a goal the development of an effective immunization.

A universal virus inactivant for decontaminating blood and biopharmaceutical products.

Removal of virus infectivity from blood and biopharmaceutical products prepared from blood is an issue of considerable importance. Irrespective of the methods that are chosen it is vital that the biological activity of the product is not impaired. For blood and unfractionated plasma or serum, the problem is even more challenging. Selective inactivation of the genome is the key step in the preparation of killed virus vaccines. Imines have been used for more than 30 years for the preparation of inactivated foot-and-mouth disease virus vaccines without any evidence of survival of virus infectivity. Moreover, the immunogenicity of the virus is unimpaired. Viruses belonging to all the recognised families can be inactivated by imines. The biological properties of several proteins, including the cell growth-promoting factors in calf serum, are not impaired using conditions which ensure the inactivation of > 10(15) infectious units of poliovirus and foot-and-mouth disease virus (FMDV). Moreover, both viruses can be inactivated by imines at 4 degrees C, thus providing a method for removing infectivity from protein preparations which are unstable at higher temperatures. The mechanism by which FMDV is inactivated has been studied. We found that the RNA extracted from the virus after inactivation at 4 degrees C was not degraded and contained no hidden breaks but nevertheless was non-infectious. However, it could be amplified by PCR using primers corresponding to the gene coding for a portion of the viral RNA polymerase, but not from that coding for VP1, one of the structural proteins, showing that alteration of a base or bases had occurred in that region.

Comparison of the plaque test and reverse transcription nested PCR for the detection of FMDV in nasal swabs and probang samples.

In order to compare the sensitivity of assays for the diagnosis of foot-and mouth disease (FMD), a cell suspension plaque test on BHK21-CT cells and a reverse transcription nested PCR (RT-nPCR) were used to examine 485 nasal swabs and 227 probang samples obtained from FMDV-infected cattle during vaccine potency tests. In nasal swabs, FMDV could be detected by both tests before the onset of clinical symptoms. However, after two weeks p.i., FMDV was only detected routinely in the probang samples. Examination of nasal swabs revealed a higher number of infected animals using RT-nPCR than by the use of the plaque test. Both tests gave approximately equivalent results with the probang samples.

Evidence of partial protection against foot-and-mouth disease in cattle immunized with a recombinant adenovirus vector expressing the precursor polypeptide (P1) of foot-and-mouth disease virus capsid proteins.

A recombinant live vector vaccine was produced by insertion of cDNA encoding the structural proteins (P1) of foot-and-mouth disease virus (FMDV) into a replication-competent human adenovirus type 5 vaccine strain (Ad5 wt). Groups of cattle (n = 3) were immunized twice, by the subcutaneous and/or intranasal routes, with either the Ad5 wt vaccine or with the recombinant FMDV Ad5-P1 vaccine. All animals were challenged by intranasal instillation of FMDV 4 weeks after the second immunizations. In the absence of a detectable antibody response to FMDV, significant protection against viral challenge was seen in all of the animals immunized twice by the subcutaneous route with the recombinant vaccine. The observed partial protection against clinical disease was not associated with a reduction in titre of persistent FMDV infections in the oropharynx of challenged cattle.

Heterotypic inhibition of foot-and-mouth disease virus infection by combinations of RNA transcripts corresponding to the 5' and 3' regions.

Strategies to inhibit RNA virus multiplication based on the use of interfering nucleic acids have to consider the high genetic polymorphism exhibited by this group of viruses. Here, we report high levels of heterotypic inhibition of foot-and-mouth disease virus (FMDV) infective particle formation in cotransfection experiments of susceptible cell lines with infections viral RNA and combinations of viral transcripts. The interfering molecules used include the following regions on type C FMDV RNA: (i) sequences from the 5' region, spanning the proximal part of the internal ribosome entry site element and the two functional initiator AUGs; and (ii) the 3' terminal region including the 3' end of 3D gene and the complete 3' non-coding region. Combination of 5' antisense RNA molecules with either sense or antisense RNA molecules from the 3' region resulted in inhibition of up to 90% of the infectivity of homologous type C FMDV RNA. The inhibition was dose-dependent and specific, as no reduction was observed in the plaque-forming units recovered from RNA of swine vesicular disease virus, a related picornavirus. Interestingly, high levels-of intertypic inhibition, about 60% or higher, were observed when viral RNAs of serotypes O and A were analysed. These levels of inhibition are consistent with the levels of nucleotide homology exhibited by the viruses analysed in the target sequences. Inhibition of virus yield was also observed in FMDV-infected cells transiently expressing the interfering RNAs. Thus, transcripts of the FMDV RNA corresponding to the 5' and 3' regions specifically inhibit FMDV particle formation in a serotype-independent manner.

Problems with BHK 21 cells.

The properties of baby hamster kidney (BHK 21) cells are modified by passage in suspension culture. The suspended cells differ from monolayer cells in the surface expression of some integrin chains involved in attachment of foot-and-mouth disease virus (FMDV), in particular the progressive down-regulation of both alpha5 and alphaV integrin chains. This down-regulation is correlated with the loss of actin stress fibres. FMDV particles from these cells are unstable towards the aziridine used in inactivating the virus for vaccine production. Moreover, growth of virus in suspended cells can lead to the selection of antigenic variants which differ from those produced in monolayer cells.

Inhibition of foot and mouth disease virus (FMDV) uncoating by a plant-derived peptide isolated from Melia azedarach L leaves.

Meliacine (MA), a peptide isolated from leaves of the high plant Melia azedarach L inhibited the multiplication of foot and mouth disease virus (FMDV) in BHK-21 cells. In this report, we establish that the MA-inhibitable process takes place within the first hour of the viral reproductive cycle. MA had no virucidal effect and did not affect adsorption and penetration of the virus in cells. In experiments with neutral red-labeled virus, it was found that MA significantly suppressed the development of photoresistance of the virus in infected cells. In untreated cultures nearly all virus which adsorbed to cells was uncoated within 1 h at 37 degrees C, whereas in treated cultures, even after 3 h only 3% of the virus was uncoated. Labeling of BHK-21 cells with acridine orange showed that MA affects the pH of intracellular acidic vesicles. Therefore, it is concluded that MA prevents the process of uncoating of FMDV in BHK-21 cells by inhibiting vacuolar acidification.

An RNA virus can adapt to the multiplicity of infection.

RNA viruses evolve as complex distributions of mutants termed viral quasispecies. For this reason it is relevant to explore those environmental parameters that favour the selective advantage of some viral subpopulations over others. In the present study we provide direct evidence that the relative fitness of two competing viral subpopulations may depend on the multiplicity of infection (m.o.i.). Two closely related subpopulations of foot-and-mouth disease virus (FMDV) of serotype C, which differed in their history of cytolytic passages in BHK-21 cells, were subjected to growth-competition experiments in BHK-21 cells. One of the populations, termed S, was found to have a selective advantage over the other population, termed L, only when the competition passages were carried out at low m.o.i. In contrast, both populations, L and S, coexisted during serial passages carried out at high m.o.i. No differences between S and L were detected in assays of inhibition of infectivity by synthetic peptides, in cell binding-competition experiments, or in virulence for BHK-21 cells. However, FMDV S displayed increased heparin binding compared with L, and L higher virulence for Chinese hamster ovary (CHO) cells than S. These results with FMDV suggest that small differences in the interaction of the virus with the host cell may contribute to an m.o.i.-dependent selective advantage of one viral subpopulation over a closely related subpopulation. Therefore, different viral mutants from quasispecies replicating in vivo may be selected depending on the number of variant viruses relative to the number of susceptible cells.

Development and characterization of monoclonal antibodies to foot and mouth disease virus type 'C'.

Five fusion experiments were conducted with spleen cells from Balb/c mice immunized with purified 146S antigen of foot and mouth disease virus type 'C' (vaccine strain). Monoclones (31) thus developed were isotyped as IgM (3), IgG1 (6), IgG2a (5), IgG2b (3) and IgG3 (14). Eleven clones isotyped as IgM, IgG2a and IgG2b showed neutralizing activity in virus neutralization and plaque reduction tests. Six of the neutralizing clones precipitated 146S virus in Ouchterlony reaction. On the basis of location of MAb reactive epitopes in relation to intact virus (146S), 12S particles and VP1 in ELISA test, the clones were classified as Class II (6), Class III (11) and Class IV (14). These clones may be useful for purposes of antigen detection from field isolates and for estimation of antibody titres in vaccinated animals.

Antigenically profound amino acid substitutions occur during large population passages of foot-and-mouth disease virus.

Foot-and-mouth disease virus (FMDV) with amino acid substitutions next to the highly conserved R-G-D motif were isolated following large population passages of the virus (N. Sevilla and E. Domingo, 1996, J. Virol., in press). Reactivity with a panel of monoclonal antibodies which recognize different epitopes within site A was abolished or highly diminished in the mutants. This provides direct evidence of a drastic antigenic change occurring in the absence of selection by antibodies. Molecular modeling studies predict only minor alterations in the conformation of the G-H loop of VP1 and the R-G-D motif in these mutants. None of these variants became dominant in many serial infections involving smaller FMDV population numbers. In addition to documenting profound antigenic variation without immune selection, the results suggest that the repertoire of antigenic variants evolving in viral quasispecies may be greatly influenced by the population size of the virus.

Evolution of a persistent aphthovirus in cytolytic infections: partial reversion of phenotypic traits accompanied by genetic diversification.

Foot-and-mouth disease virus (FMDV) shows a dual potential to be cytolytic or to establish persistent infections in cell culture. FMDV R100, a virus rescued after 100 passages of carrier BHK-21 cells persistently infected with FMDV clone C-S8c1, showed multiple genetic and phenotypic alterations relative to the parental clone C-S8c1. Several FMDV R100 populations have been subjected to 100 serial cytolytic infections in BHK-21 cells, and the reversion of phenotypic and genetic alterations has been analyzed. An extreme temperature sensitivity of R100 reverted totally or partially in some passage series but not in others. The small-plaque morphology reverted to normal size in all cases. The hypervirulence for BHK-21 cells did not revert, and even showed an increase, upon cytolytic passage. Most of the mutations that had been fixed in the R100 genome during persistence did not revert in the course of cytolytic passages, but the extended polyribocytidylate tract of R100 (about 460 residues, versus 290 in C-S8c1) decreased dramatically in length, to the range of 220 to 260 residues in all passage series examined. In passages involving very large viral populations, a variant with two amino acid substitutions (L-144-->V and A-145-->P) next to the highly conserved Arg-Gly-Asp (RGD motif; positions 141 to 143) within the G-H loop of capsid protein VP1 became dominant. A clonal analysis allowed isolation of a mutant with the single replacement A-145-->P. Viral production and growth competition experiments showed the two variants to have a fitness very close to that of the parental virus. The results provide evidence that the repertoire of variants that could potentially become dominant in viral quasispecies may be influenced by the population size of the evolving virus. The net results of a series of persistent-infection passages followed by a series of cytolytic passages was progressive genomic diversification despite reversion or stasis of phenotypic traits. Implications for the evolution of RNA viruses are discussed.

Recognition of foot-and-mouth disease virus and its capsid protein VP1 by bovine peripheral T lymphocytes.

The role of T cells in immunity to foot-and-mouth disease virus is still poorly defined compared to that of the humoral response. In this paper we describe a systematic, longitudinal study on the cellular recognition of FMDV and its subunit protein VP1 by bovine peripheral blood T lymphocytes. Multiple vaccination with a single virus serotype induced a serotype cross-reactive proliferative T cell repertoire that varied in magnitude between individual animals and with the serotype of the vaccine used. Primary proliferative T cell responses of vaccinated and acutely infected cattle were weak relative to the magnitude of responses determined for the same animals after boosting. In contrast, the level of circulating antibody produced after both primary and secondary exposure to virus was good. Phenotypic analysis of lymphocytes from vaccinated or infected cattle showed a small increase in CD8+ T cells after infection compared to vaccination. However, in general the profiles of circulating lymphocytes elicited were similar. Thus, we were not able to use proliferative or phenotypic analyses to distinguish between vaccinated and convalescent cattle. T cell recognition of VP1 by multiply-vaccinated cattle was serotype-specific implying that the cross-reactive responses observed with whole virus may be attributed to proteins other than VP1. In contrast to other studies, immunization with recombinant VP1 induced only low levels of neutralizing antibody and failed to elicit profound proliferative responses or protection ever after two immunizations.

Effect of expression of the aphthovirus protease 3C on viral infection and gene expression.

Cells transformed with specific regions of the foot-and-mouth disease virus (FMDV) genome have been constructed and analyzed with respect to viability and susceptibility to FMDV infection. Constitutive expression of an active protease 3C under the control of the tk promoter has been documented by the ability of transformed cells to catalyze the processing of a P1 capsid precursor. High-level, transient expression but not low-level, constitutive expression, of 3C caused a 10-fold reduction in the yield of FMDV and was detrimental to the expression of the cotransfected reporter luciferase gene. No such effect was observed in assays involving cells transfected with a deleted, inactive form of 3C. The negative effect of 3C was not observed when the same reporter gene was integrated and expressed in a constitutive fashion nor when its translation was directed by the internal ribosome entry site element of FMDV in transient expression assays. The results show that cells with a low level of expression of the aphthoviral 3C can be stably maintained and can provide a useful tool to study polyprotein processing.

Specific inhibition of aphthovirus infection by RNAs transcribed from both the 5' and the 3' noncoding regions.

RNA molecules containing the 3' terminal region of foot-and-mouth disease virus (FMDV) RNA in both antisense and sense orientations were able to inhibit viral FMDV translation and infective particle formation in BHK-21 cells following comicroinjection or cotransfection with infectious viral RNA. Antisense, but not sense, transcripts from the 5' noncoding region including the proximal element of the internal ribosome entry site and the two functional initiation AUGs were also inhibitory, both in in vitro translation and in vivo in comicroinjected or cotransfected BHK-21 cells. This effect was not observed with nonrelated RNA transcripts from lambda phage. The inhibitions found were permanent, sequence specific, and dose dependent; an inverse correlation between the length of the transcript and the extent of the antiviral effect was seen. In all cases, the extent of inhibition increased when viral RNAs and transcripts were allowed to reanneal before transfection, concomitant with a decrease in the doses required. The antiviral effect was specific for FMDV, since transcripts failed to inhibit infective particle formation by other picornavirus, such as encephalomyocarditis virus. These results indicate that the ability of RNA transcripts to inhibit viral multiplication depends on their efficient hybridization with target regions on the viral genome. Furthermore, cells transfected with the 5'1as transcript, which is complementary to the 5' noncoding region, showed a significant reduction of plaque-forming ability during the course of a natural infection. RNA 5'1as was able to inhibit FMDV RNA translation in vitro, suggesting that the inhibitions observed are mediated by a blockage of the viral translation initiation. Conversely, hybridization of short sequences of both sense and antisense transcripts from the 3' end induces distortion of predicted highly ordered structural motifs, which could be required for the synthesis of negative-stranded viral RNA, and correlates with inhibition of viral propagation.

[Continuous production of FMD virus in a two-step bioreactor system]. / Kontinuierliche Produktion von MKS-Virus in einem zweistufigen Bioreaktorsystem.

The so-called Goettingen two step bioreactor system has been tested in a pilot-project in Argentina to produce FMD-virus. With a 10-1-reactor a cell density of 3.5-4 x 10(6) cells/ml could be maintained and virus titres of up to 10(7.2) TCID/ml were reached. A correlation existed between inoculum titre and incubation period of virus. With lower inoculum a higher titre of harvested virus and a shorter incubation period were obtained. In spite of considerable problems with peripheral infrastructure and laboratory equipment the bioreactor system did work reliably. The project was terminated before final results of virus yield could be reached.