The genetics of aphthovirus. Brief review

Isolation, molecular characterization, and genetic diversity of recently isolated foot-and-mouth disease virus serotype A in Egypt

Foot-and-mouth Disease (FMD) is a highly contagious viral disease affecting all hoof-cloven animals. Serotypes A, O and SAT 2 of the foot-and-mouth disease virus (FMDV) are circulating in Egypt. The present study aimed to identify and molecularly characterize the FMDV strains circulating in Northern Egypt during an epidemic that struck the nation in 2022. RNA was extracted from the epithelial specimens, vesicular fluid from affected cattle. The samples were screened using real-time reverse-transcription polymerase chain reaction (RT-PCR) targeting the RNA-dependent RNA polymerase (RdRp) gene. Positive samples underwent individual serotype-specific amplification using primers designed for VP1 of O, A, and SAT 2 serotypes. Subsequently, direct sequencing was performed on the positive samples. The real-time RT-PCR detected positive samples from epithelial and vesicular fluid samples, but not in the blood of infected animals. Out of the 16 samples, seven tested positive for FMDV serotype A. Of these seven positive samples, six were categorized as serotype A-African topotype-G-IV, and these positive samples were isolated in BHK-21 cells, yielding an overt cytopathic effect caused by the virus. In conclusion, it is necessary to sustain continuous surveillance of the evolution of circulating FMDV strains to facilitate the assessment and aid in the selection of vaccine strains for the effective control of FMDV in Egypt.

The cucumovirus 2b gene drives selection of inter-viral recombinants affecting the crossover site, the acceptor RNA and the rate of selection

RNA–RNA recombination is an important pathway in virus evolution and has been described for many viruses. However, the factors driving recombination or promoting the selection of recombinants are still unclear. Here, we show that the small movement protein (2b) was able to promote selection of RNA 1/2–RNA 3 recombinants within a chimeric virus having RNAs 1 and 2 from cucumber mosaic virus, and RNA 3 from the related tomato aspermy virus, along with heterologous 2b genes. The source of the 2b also determined the selection of the acceptor RNA and the crossover site, as well as affecting the rate of selection of the recombinant RNAs. The nature of the RNA 3 also influenced the selection of the recombinant RNAs. A 163-nt tandem repeat in RNA 3 significantly affected the rate of selection of the recombinant RNA, while a single nucleotide within the repeat affected the crossover site. The recombination occurred in a non-random manner, involved no intermediates and probably was generated via a copy-choice mechanism during (+) strand RNA synthesis.

Genetic analysis of enterovirus 71 isolated from fatal and non-fatal cases of hand, foot and mouth disease during an epidemic in Taiwan, 1998

A large scale outbreak of hand-foot-and-mouth disease (HFMD) occurred in Taiwan in 1998, in which more than 80 children died of shock syndrome with pulmonary edema/hemorrhage. Enterovirus 71 was implicated as the cause of this outbreak. In order to understand the virological basis responsible for mortality on this scale, nucleotide sequences of VP1 that is important for serotypic specificity, and the 5'-non-coding region (5'-NCR) that is important for replication efficiency, were analyzed comparatively. Phylogenetic analysis of both VP1 and 5'-NCR of nine EV71 isolates derived from specimens of fatal patients and seven isolates derived from uncomplicated HFMD patients showed that all but one isolate fell into genotype B. The one distinct isolate from a case of uncomplicated HFMD belonged to genotype C that was clustered along with one isolate from Taiwan in 1986. Complete sequence analysis of two selected isolates, one from the spinal cord of a fatal case and one from the vesicle fluid of a patient with mild HFMD, confirmed a high degree (97-100%) of identity in nucleotide sequence throughout the entire genome, except focal regions of 3C and 3'-NCR where the nucleotide homology was 90-91%. The identity of the deduced amino acid sequence in the 3C region that encodes viral proteinase dropped further to 86%, a result of missense mutations at the first nucleotide position of many codons.

Mutations in the N terminus of the brome mosaic virus polymerase affect genetic RNA-RNA recombination

Previously, we have observed that mutations in proteins 1a and 2a, the two virally encoded components of the brome mosaic virus (BMV) replicase, can affect the frequency of recombination and the locations of RNA recombination sites (P. D. Nagy, A. Dzianott, P. Ahlquist, and J. J. Bujarski, J. Virol. 69:2547-2556, 1995; M. Figlerowicz, P. D. Nagy, and J. J. Bujarski, Proc. Natl. Acad. Sci. USA 94:2073-2078, 1997). Also, it was found before that the N-terminal domain of 2a, the putative RNA polymerase protein, participates in the interactions between 1a and 2a (C. C. Kao, R. Quadt, R. P. Hershberger, and P. Ahlquist, J. Virol. 66:6322-6329, 1992; E. O'Reilly, J. Paul, and C. C. Kao, J. Virol. 71:7526-7532, 1997). In this work, we examine how mutations within the N terminus of 2a influence RNA recombination in BMV. Because of the likely electrostatic character of 1a-2a interactions, five 2a mutants, MF1 to MF5, were generated by replacing clusters of acidic amino acids with their neutral counterparts. MF2 and MF5 retained nearly wild-type levels of 1a-2a interaction and were infectious in Chenopodium quinoa. However, compared to that in wild-type virus, the frequency of nonhomologous recombination in both MF2 and MF5 was markedly decreased. Only in MF2 was the frequency of homologous recombination reduced and the occurrence of imprecise homologous recombination increased. In MF5 there was also a 3' shift in the positions of homologous crossovers. The observed effects of MF2 and MF5 reveal that the 2a N-terminal domain participates in different ways in homologous and in nonhomologous BMV RNA recombination. This work maps specific locations within the N terminus involved in 1a-2a interaction and in recombination and further suggests that the mechanisms of the two types of crossovers in BMV are different.

RNA recombination in animal and plant viruses

An increasing number of animal and plant viruses have been shown to undergo RNA-RNA recombination, which is defined as the exchange of genetic information between nonsegmented RNAs. Only some of these viruses have been shown to undergo recombination in experimental infection of tissue culture, animals, and plants. However, a survey of viral RNA structure and sequences suggests that many RNA viruses were derived form homologous or nonhomologous recombination between viruses or between viruses and cellular genes during natural viral evolution. The high frequency and widespread nature of RNA recombination indicate that this phenomenon plays a more significant role in the biology of RNA viruses than was previously recognized. Three types of RNA recombination are defined: homologous recombination; aberrant homologous recombination, which results in sequence duplication, insertion, or deletion during recombination; and nonhomologous (illegitimate) recombination, which does not involve sequence homology. RNA recombination has been shown to occur by a copy choice mechanism in some viruses. A model for this recombination mechanism is presented.

Modification of foot-and-mouth disease virus after serial passages in the presence of antiviral polyclonal sera

Foot-and-mouth disease virus (FMDV) shows a remarkable antigenic variability. Like other RNA viruses, this virus has a high rate of mutation. It has been proposed that selection exerted by the host's antibodies could play a major role in the rapid evolution of FMDV. The present work reports the selection of FMDV antibody-resistant populations (Nr), after serial passages of cloned FMDV A24 Cruzeiro strain on secondary monolayers of bovine fetal kidney cells in the presence of subneutralizing antiviral polyclonal sera (APS). After a limited number of passages under selective pressure, the virus population showed the following characteristics: (1) increased resistance to neutralization by APS; (2) altered electrophoretic mobility of structural viral proteins (VP1); (3) remarkable plaque size reduction, (4) a pronounced thermosensitivity (ts); and (5) decreased pathogenicity for mice, in both uncloned and cloned small plaque size populations. This indicates that FMDV populations under antibody pressure in vitro, have acquired, in addition to expected characteristics of natural FMDV variants (resistance to neutralization and altered viral structural proteins), phenotypic markers which correspond to attenuated, less virulent variants.

Further characterization of an RNA defective mutant of the foot-and-mouth disease virus

In this paper a further characterization of a foot-and-mouth disease virus (FMDV) temperature-sensitive mutant, ts 6, is described. This mutant presents a defective RNA synthesis at non-permissive temperature (NPT) by comparison to the wt capacity. However, a low level of viral RNA synthesis (below 10%) was sufficient to achieve an almost normal protein synthesis including a normal pattern of protein cleavage. In addition, morphogenetic precursor particles, 14S and 75S, are formed, indicating that the structural proteins VP0, VP1 and VP3 provide the necessary signal for self-assembly, and that the RNA is not necessary for such assemblage. Finally, although an almost normal synthesis of viral proteins and morphogenetic precursors (14S and 75S) occurs, the induction of cellular protein shut-off was not evident, indicating that this viral effect appears late in the viral cycle once complete viral replication has occurred.

Studies on the recombination between RNA genomes of poliovirus: the primary structure and nonrandom distribution of crossover regions in the genomes of intertypic poliovirus recombinants

A series of intertypic (type 3/type 1) poliovirus recombinants was obtained whose crossover sites were expected to be located in the middle of the viral genome, between the loci encoding type-specific antigenic properties, on the 5' side, and an altered sensitivity to guanidine, on the 3' side. The primary structures of the crossover regions in the genomes of these recombinants were determined by the primer extension method. The length of the crossover sites (the uninterrupted sequences shared by the recombinant and both parental genomes that are flanked, in the recombinant RNAs, by two heterotypic segments) varied between 2 and 32 nucleotides, but the majority of the sites were 5 nucleotides long or shorter. The crossover sites were nonrandomly distributed over the presumably available genome region: only a single such site was found within the gene for polypeptide 2A, whereas an apparent clustering of the crossover sites was encountered in other genomic segments. When the crossover sites were superimposed on a model of the secondary structure of the relevant region of the viral RNA molecule, a pattern consistent with the previously proposed mechanism of poliovirus recombination (L.I. Romanova, V.M. Blinov, E.A. Tolskaya, E.G. Viktorova, M.S. Kolesnikova, E.I. Guseva, and V.I. Agol (1986) Virology 155, 202-213) was observed. It is suggested that the nonrandom distribution of the crossover sites in the genomes of intertypic poliovirus recombinants was due to two factors: the existence of preferred sites for recombination, and selection against recombinants with a lowered level of viability.

The primary structure of crossover regions of intertypic poliovirus recombinants: a model of recombination between RNA genomes

The nucleotide sequence of crossover sites in the genome of four intertypic (type 3/type 1) poliovirus recombinants has been determined. The approximate boundaries of the crossover regions were first estimated by RNase T1 oligonucleotide mapping of the recombinant genomes; then appropriate regions were sequenced by the chain termination method using oligonucleotide-primed reverse transcription of the recombinant RNAs. The crossover sites (defined as the contiguous sequences shared by the recombinant and both parental genomes flanked, in the recombinant genome, by heterotypic RNA segments) are 5, 5, 7, and 11 nucleotides long, respectively. The recombination was precise and was not accompanied by any other genetic alterations. The recombination sites were found to be located within genome segments having a potential to form secondary structure elements. Based on this observation, a model of recombination between picornaviral RNA genomes has been proposed. The essence of this model consists in bringing together homologous regions of two recombining RNA genomes via formation of intermolecular duplexes, detachment of the nascent 3' end of the newly synthesized complementary RNA from a "parting" site on the first template and its subsequent "jumping" to the identical (or closely related) "anchoring" site on the other template. Features of this model are discussed in some detail.

Further characterization of a morphogenetic mutant of the foot-and-mouth disease virus

In this paper we describe further characterization of a foot-and-mouth disease virus (FMDV) temperature-sensitive mutant, ts 139. This mutant was very sensitive to heat inactivation, suggesting that its viral particles are somehow altered. The electrophoretic analysis of ts 139 structural proteins indicated that VP2 has an altered mobility. Furthermore, two known protein precursors of VP2, VP0 and p88, were shown to be altered, as was p64, which supports a VP2 precursor role for p64. The ts 139 viral particle assembly pathway was analyzed during viral replication. The empty-capsid to complete-viral-particle ratio was clearly increased compared to that found for the wt strain, indicating an alteration in the morphogenetic process. This encouraged us to search for the presence of possible viral precursors of low sedimentation coefficient which have not been described previously in aphthovirus-infected cells. Analysis of the viral morphogenetic process in ts 139-infected cells demonstrated the presence of viral complexes formed by VP0, VP1 and VP3 which sedimented slightly faster than a 12 S marker. The protein composition, the sedimentation coefficient of this complex and the pulse-chase results strongly suggest that it is a morphogenetic precursor of the mature viral particle.

Recombinants between attenuated and virulent strains of poliovirus type 1: derivation and characterization of recombinants with centrally located crossover points

Recombinants with a centrally located crossover point were selected from crosses between poliovirus type 1 strains and intertypic (type 3/type 1) recombinants. Two such recombinants were characterized in some detail. In one of them (v1/a1-6), the 5' half of the genome was derived from a virulent type 1 strain, while the 3' half came from an attenuated type 1 strain. The genome of the other recombinant (a1/v1-7) had the reverse organization, with the 5' and 3' halves being derived from the type 1 attenuated and virulent strains, respectively. As deduced from the RNase T1 oligonucleotide maps, the a1/v1-7 genome also had a relatively short centrally located insert of the poliovirus type 3 origin. Both recombinants exhibited ts phenotypes. The RNA phenotypes of the recombinants corresponded to that of the parent donating the 3' half of the genome, v1/a1-6 and a1/v1-7 expressing RNA- and RNA +/- characters, respectively. Despite being a ts RNA- virus, v1/a1-6 proved to be neurovirulent when injected intracerebrally into Cercopithecus aethiops monkeys, although it exhibited a somewhat diminished level of pathogenicity as compared to its virulent type 1 parent. Recombinant a1/v1-7 behaved as an attenuated strain. These data supported our previous conclusion drawn from the experiments with intertypic poliovirus recombinants that the attenuated phenotype of poliovirus depends largely on the structure of the 5' half of its genome, although mutations of the 3' half may alleviate the virulence of the virus to a degree.

Sequence variation in the gene for the immunogenic capsid protein VP1 of foot-and-mouth disease virus type A

The nucleotide sequences have been determined and compared from cloned cDNA genes coding for the foot-and-mouth disease virus (FMDV) immunogenic capsid protein, VP1, from eight different A subtypes: A5 Westerwald/58, A12 119ab (large plaque variant), A22 550 USSR/65, A24 Cruzeiro Brazil/55, A27 Cundinamarca Colombia/76, A32 Venezuela/70, A Venceslau Brazil/76, and A Argentina/79. We have also found sequence variations among different cDNA clones of the A5 and A24 subtypes. There are regions of nucleotide sequence within the VP1 gene that vary considerably among the subtypes as well as other regions that remain relatively constant. One highly variable region (codons 130-171) encodes amino acids previously identified as being exposed on the virus surface and constituting an important immunogenic site of the virus. There potentially exist secondary structures within the viral RNA sequences that code for this immunogenic site that could decrease the fidelity of replication at this sequence. The rapid generation of FMDV variants encouraged by such structures in the RNA could work together with various selective pressures to explain the observed accumulation of immunologically distinct viruses of the FMDV A type.

Comparison of structural and nonstructural proteins of virulent and less virulent Theiler's virus isolates using two-dimensional gel electrophoresis

The Theiler's murine encephalomyelitis viruses (TMEV) are important neurotropic picornaviruses because they persist in the central nervous system (CNS) and produce an inflammatory demyelinating disease in the mouse, their natural host. Insight into the pathogenesis of this disease may come from studying the genetic and biochemical compositions of these viruses; therefore, in this report, the structural and nonstructural proteins specified by both highly and less virulent TMEV were examined. Using two-dimensional gel electrophoresis, structural and nonstructural proteins, originating from each of the three regions of the picornavirus genome (Kitamura et al., 1981; Rueckert and Wimmer, 1984), from nine TMEV isolates were compared on the basis of isoelectric points (pI). Proteins of two virulent TMEV (GDVII and FA viruses) had almost indistinguishable pI values, whereas two of the three major capsid proteins of the less virulent TMEV varied considerably. For example, the structural proteins VP1 and VP3 from seven less virulent viruses ranged from pI 6.3 to 6.9 and 6.5 to 8.3, respectively. On the other hand, the pI values of VP2 and nonstructural proteins from the less virulent TMEV varied relatively little. In general, structural proteins of each TMEV group had pI ranges unique to their respective biological group, while most nonstructural proteins were similar for all TMEV. The virus-specified proteins of Vilyuisk virus, which is serologically related to the TMEV and a possible cause of encephalomyelitis in man, had pI values similar to the less virulent TMEV. Finally, VP3 not only showed the greatest variation in pI among the less virulent TMEV, but it also was preferentially radioiodinated in intact virus from each of the two biological groups using the lactoperoxidase technique.

Antigenic variation in foot-and-mouth disease: studies based on the virus neutralization reaction

The neutralization reaction is the most appropriate in vitro reference test system for assessing intratypic antigenic variation as it involves the antigenic determinants responsible for virus strain specificity and evoking protective antibody. Antigenic relationships determined in different neutralization test systems were independent of the system used and were assumed to truly reflect antigenic variation. The two-dimensional microneutralization test was found to be appropriate for foot and mouth disease (FMD) virus strain differentiation. To minimize test to test variation, comparisons are performed as matched pairs. The pooled variance of the test system is used to assess the significance of the relationships obtained. Antisera from convalescent animals were less specific than those from vaccinates. Serum quality seemed less critical for the virus neutralization than the complement fixation reaction. A system for FMD virus strain differentiation based on the use of the virus neutralization reaction taking into account the statistical and biological significance of observed r values is recommended.

The position of polypeptide G on the encephalomyocarditis virus polyprotein cleavage map

The two-dimensional mapping of tryptic peptides of encephalomyocarditis virus-specific proteins has demonstrated that the amino acid sequence of non-structural polypeptide G constitutes a portion of the molecule of a precursor of capsid proteins, polypeptide A. The results of pulse-chase in vitro translation experiments strongly suggest that polypeptide G corresponds to a C-terminal moiety of polypeptide A. Variations in the polyprotein cleavage maps of different picornaviruses are briefly discussed.

Intertypic recombination in poliovirus: genetic and biochemical studies

Poliovirus strains of type 1 and type 3 carrying genetically mapped ts mutations and differring in growth response to guanidine have been used to infect HeLa cells. With four heterotypic pairs of the mutants, recombinants with the crossover points between the loci coding for the antigenic properties, on the one hand, and for the sensitivity to guanidine, on the other, have been obtained. The recombinants have been identified on the basis of their phenotypic properties and, in particular, of the pattern of inheritance of unselected markers. One recombinant has been characterized by fingerprinting virus-specific polypeptides. It has been found that the capsid proteins (VP2, VP3, and VP1) of this recombinant originate from the type 3 parent, whereas the nonstructural polypeptides (X, 2, and 4) are inherited from the type 1 parent. Implications of the poliovirus intertypic recombination are discussed.

Recombination in RNA

The aphthovirus genome consists of a single molecule of single-stranded RNA that encodes all the virus-induced proteins. We isolated recombinant aphthoviruses from cells simultaneously infected with temperature-sensitive mutants of two different subtype strains. Analysis of the proteins induced by 16 independently generated recombinants revealed two types of protein pattern, which were consistent with single genetic crossovers on the 5' side and 3' side, respectively, of the central P34-coding region. Recombinants invariably inherited all four coat proteins from the same parent, and novel recombinant proteins were not observed. RNAase T1 fingerprints of virus RNA, prepared from representatives of each recombinant type, confirmed the approximate crossover sites that had been deduced from the inheritance of proteins. These fingerprints provide molecular evidence of recombination at the level of RNA and demonstrate the potential of RNA recombination for producing genetic diversity among picornaviruses.

Guanidine-resistant mutants of aphthovirus induce the synthesis of an altered nonstructural polypeptide, P34

Extracts of cells infected with guanidine-resistant mutants of aphthovirus were examined for differences in virus-induced polypeptides by using electrofocusing. Four of 1 independent spontaneous mutants induced the synthesis of an altered nonstructural polypeptide, P34. The precursor of P34, P52, and a previously unmapped polypeptide, P20c, also carried these charge-change mutations. No mutations in other regions of the genome were detected, and the remaining six guanidine-resistant mutants appeared entirely normal by electrofocusing. However, when the P34 of one of the latter mutants was examined by tryptic peptide fingerprinting, it too differed from that of the guanidine-sensitive parent. The frequency of P34 alterations among guanidine-resistant mutants suggests that P34 is functionally involved in the antiviral action of guanidine.