The non-structural leader protein gene of foot-and-mouth disease virus is highly variable between serotypes

Monoclonal antibodies against foot-and-mouth disease virus RNA polymerase for detection of virus infection

Foot-and-mouth disease (FMD) is a major viral disease in farm animals. In the present study, seven monoclonal antibodies (mAbs) were produced against the FMD virus (FMDV)-encoded RNA-dependent RNA polymerase (3D protein) and characterized. Screening of mAb reactivity against three overlapping fragments of the 3D protein expressed in Escherichia coli revealed that the binding sites of all the mAbs were confined to the N-terminal one-third of the 3D protein. A selected mAb was utilized for detecting FMDV in the infected cell culture and tissues obtained from FMDV-infected animals.

Biological function of Foot-and-mouth disease virus non-structural proteins and non-coding elements

Foot-and-mouth disease virus (FMDV) represses host translation machinery, blocks protein secretion, and cleaves cellular proteins associated with signal transduction and the innate immune response to infection. Non-structural proteins (NSPs) and non-coding elements (NCEs) of FMDV play a critical role in these biological processes. The FMDV virion consists of capsid and nucleic acid. The virus genome is a positive single stranded RNA and encodes a single long open reading frame (ORF) flanked by a long structured 5ʹ-untranslated region (5ʹ-UTR) and a short 3ʹ-UTR. The ORF is translated into a polypeptide chain and processed into four structural proteins (VP1, VP2, VP3, and VP4), 10 NSPs (L^pro, 2A, 2B, 2C, 3A, 3B_1–3, 3C^pro, and 3D^pol), and some cleavage intermediates. In the past decade, an increasing number of studies have begun to focus on the molecular pathogenesis of FMDV NSPs and NCEs. This review collected recent research progress on the biological functions of these NSPs and NCEs on the replication and host cellular regulation of FMDV to understand the molecular mechanism of host–FMDV interactions and provide perspectives for antiviral strategy and development of novel vaccines.

Interplay of foot-and-mouth disease virus, antibodies and plasmacytoid dendritic cells: virus opsonization under non-neutralizing conditions results in enhanced interferon-alpha responses

Foot-and-mouth disease virus (FMDV) is a highly infectious member of the Picornaviridae inducing an acute disease of cloven-hoofed species. Vaccine-induced immune protection correlates with the presence of high levels of neutralizing antibodies but also opsonising antibodies have been proposed as an important mechanism of the immune response contributing to virus clearance by macrophages and leading to the production of type-I interferon (IFN) by plasmacytoid dendritic cells (pDC). The present study demonstrates that the opsonising antibody titres mediating enhanced IFN-α responses in pDC were similar to neutralizing titres, when antigenically related viruses from the same serotype were employed. However, sera cross-reacted also with non-neutralized isolates of multiple serotypes, when tested in this assay. Both uncomplexed virus and immune complexed virus stimulated pDC via Toll-like receptor 7. An additional finding of potential importance for strain-specific differences in virulence and/or immunogenicity was that pDC activation by FMDV strongly differed between viral isolates. Altogether, our results indicate that opsonising antibodies can have a broader reactivity than neutralizing antibodies and may contribute to antiviral responses induced against antigenically distant viruses.

Genetic characterization of a new pandemic Southeast Asia topotype strain of serotype O foot-and-mouth disease virus isolated in China during 2010

The full-length nucleotide sequence of the foot-and-mouth disease virus O/BY/CHA/2010 strain, Mya-98 lineage of Southeast Asia (SEA) topotype, was determined and compared with O/HKN/20/2010 and other known FMDV strains. Homology analysis indicated >98.0% nucleotide identity between O/BY/CHA/2010 and the epidemic strains, O/HKN/20/2010, and O/VN/2009. However, with the exception of the VP4, 2A, and 3BCD regions, O/BY/CHA/2010 showed a lower similarity with SEA topotype strains, O/VN/2006, and HLJOC12/03. A comparison of O/BY/CHA/2010 with non-SEA topotype strains showed the highest level of homology (97.4-100%) with UKG/7B/2007, Akesu/58, and the PanAsia strains in the 2A, P2, and 3CD regions, which suggested the presence of similar characteristics among these strains. Phylogenetic analysis revealed that O/BY/CHA/2010 is clustered in the Mya-98 lineage of the SEA topotype and is linked to four other isolates: HKN/20/2010, O/VN/2009, O/VN/2006, and HLJOC12/03. The VP1-based phylogenetic tree was divided into distinct clusters according to the different topotypes, while other gene-based phylogenetic trees exhibited some degree of intercrossing among topotypes. Furthermore, sequence analysis of the Lpro gene revealed a single amino acid insertion in O/HKN/20/2010 and a single amino acid deletion in O/BY/CHA/2010, in addition to a 70-nucleotide deletion within the 5'-untranslated region of O/HKN/20/2010. The majority of strains were shown to be homologous in the pseudoknots region although some exceptions were noted. This study provides a comprehensive genetic characterization of a novel FMDV isolate of the Mya-98 lineage.

Introduction of tag epitopes in the inter-AUG region of foot and mouth disease virus: effect on the L protein

Foot-and-mouth disease virus (FMDV) initiates translation from two in-frame AUG codons producing two forms of the leader (L) proteinase, Lab (starting at the first AUG) and Lb (starting at second AUG). In a previous study, we have demonstrated that a cDNA-derived mutant FMDV (A24-L1123) containing a 57-nucleotide transposon (tn) insertion between the two AUG initiation codons (inter-AUG region) was completely attenuated in cattle, suggesting that this region is involved in viral pathogenesis. To investigate the potential role of the Lab protein in attenuation, we have introduced two epitope tags (Flag: DYKDDDK and HA: YPYDVPDYA) or a small tetracysteine motif (tc: CCGPCC) into the pA24-L1123 infectious DNA clone. Mutant viruses with a small plaque phenotype similar to the parental A24-L1123 were recovered after transfection of constructs encoding the Flag tag and the tc motif. However, expression of the Flag- or tc-tagged Lab protein was abolished or greatly diminished in these viruses. Interestingly, the A24-L1123/Flag virus acquired an extra base in the inter-AUG region that resulted in new AUG codons in-frame with the second AUG, and produced a larger Lb protein. This N terminal extension of the Lb protein in mutant A24-L1123/Flag did not affect virus viability or L functions in cell culture.

Genetic characterization of the cell-adapted PanAsia strain of foot-and-mouth disease virus O/Fujian/CHA/5/99 isolated from swine

Background

According to Office International Des Epizooties (OIE) Bulletin, the PanAsia strain of Foot-and-Mouth Disease Virus (FMDV) was invaded into the People's Republic of China in May 1999. It was confirmed that the outbreaks occurred in Tibet, Hainan and Fujian provinces. In total, 1280 susceptible animals (68 cattle, 1212 swine) were destroyed for the epidemic control.

To investigate the distinct biological properties, we performed plaque assay, estimated the pathogenicity in suckling mice and determined the complete genomic sequence of FMDV swine-isolated O/Fujian/CHA/5/99 strain. In addition, a molecular modeling was carried out with the external capsid proteins.

Results

The pathogenicity study showed that O/Fujian/CHA/5/99 had high virulence with respect to infection in 3-day-old suckling-mice (LD₅₀ = 10^-8.3), compared to O/Tibet/CHA/1/99 (LD50 = 10^-7.0) which isolated from bovine. The plaque assay was distinguishable between O/Fujian/CHA/5/99 and O/Tibet/CHA/1/99 by their plaque phenotypes. O/Fujian/CHA/5/99 formed large plaque while O/Tibet/CHA/1/99 formed small plaque.

The 8,172 nucleotides (nt) of O/Fujian/CHA/5/99 was sequenced, and a phylogenetic tree was generated from the complete nucleotide sequences of VP1 compared with other FMDV reference strains. The identity data showed that O/Fujian/CHA/5/99 is closely related to O/AS/SKR/2002 (94.1% similarity). Based on multiple sequence alignments, comparison of sequences showed that the characteristic nucleotide/amino acid mutations were found in the whole genome of O/Fujian/CHA/5/99.

Conclusion

Our finding suggested that C275T substitution in IRES of O/Fujian/CHA/5/99 may induce the stability of domain 3 for the whole element function. The structure prediction indicated that most of 14 amino acid substitutions are fixed in the capsid of O/Fujian/CHA/5/99 around B-C loop and E-F loop of VP2 (antigenic site 2), and G-H loop of VP1 (antigenic site 1), respectively. These results implicated that these substitutions close to heparin binding sites (E136G in VP2, A174 S in VP3) and at antigenic site 1 (T142A, A152T and Q153P in VP1) may influence plaque size and the pathogenicity to suckling mice.

The potential of genetic characterization would be useful for microevolution and viral pathogenesis of FMDV in the further study.

Sequence analysis of the protein-coding regions of foot-and-mouth disease virus O/HK/2001

The nucleotide sequence of the protein-coding region of foot-mouth-disease virus (FMDV) strain O/HK/2001 was determined and compared with the sequences of other FMDVs that were registered in GenBank. The protein-coding region was 6966 nucleotides in length and encoded a protein of 2322 amino acid residues. Comparison of the nucleotide sequence and its deduced amino acid sequence with those of other isolates indicated that O/HK/2001 belonged to the Cathay topotype. A genomic coding region nucleotide sequence phylogenetic tree of several FMDV-O isolates showed that O/HK/2001 was most closely related to FMDV isolates found in Taiwan during 1997, and especially shared significant similarity to HKN/2002, suggesting that the virus causing outbreaks in Hong Kong was genetically most-closely related to that causing an outbreak of type O in Taiwan. Mutations in O/HK/2001 were revealed, including frequent substitutions in the VP1 and L proteins, and deletions involving 10 amino acid residues in the 3A protein. This study was undertaken to assess the regional variation of prevalent FMDV type O viruses and to establish a sequence database for FMDV molecular epidemiological investigation.

Complete nucleotide sequence of a Chinese serotype Asia1 vaccine strain of foot-and-mouth disease virus

The full-length nucleotide sequence of the Chinese vaccine strain Asia1/YNBS/58 of foot-and-mouth disease virus (FMDV) was determined. The results showed that the complete genome of YNBS/58 is 8,164 nucleotides (nt) in length including a 1,061-nt 5' untranslated region (UTR), a 6,990-nt open reading frame (ORF), and a 113-nt 3' UTR. Genome sequences of Asia1/YNBS/58 and other known FMDV strains were compared. The homology analysis indicated that non-structural proteins are more conserved than structural proteins in FMDV and that the 5' UTR is more conserved than the 3' UTR. Phylogenetic analysis revealed that Asia1/YNBS/58 is clustered in the Asia1 serotype and is linked to three other isolates, Asia1/IND/63/72, Asia1/3kimron/63, and Asia1/2ISRL/63, suggesting that they have a close genetic relationship. The VP1-, VP2-, and VP3-based phylogenetic trees divided into distinct clusters according to the different serotypes, while other gene-based phylogenetic trees exhibited some degree of intercrossing among serotypes. According to the nucleotide similarities between Asia1/YNBS/58 and two recent Chinese Asia1 isolates, Asia1/HKN/05, and Asia1/JS/05, each forms a distinct genotype. This study is the first description of the full-length genomic sequence of FMDV Chinese serotype Asia1.

Picornaviruses and cell death

Members of the picornavirus family, including poliovirus and foot-and-mouth disease virus, are widespread pathogens of humans and domestic animals. Recent global developments in the resurgence of poliovirus infection and in the control of foot-and-mouth disease infection highlight the problems caused by the ability of picornaviruses to alter the apoptotic machinery of host cells and establish persistent infections. Despite the medical, economic and social impact of this family of viruses, little information exists that integrates the mechanisms of cell death and damage induced by related family members. Fortunately, examination of the reported roles and functions of individual viral proteins from multiple picornaviruses makes it possible to surmise canonical functions for these proteins. This review analyzes the canonical function of picornavirus proteins involved in the alteration of apoptotic homeostasis in infected host cells.

Comparative genomics of foot-and-mouth disease virus

Here we present complete genome sequences, including a comparative analysis, of 103 isolates of foot-and-mouth disease virus (FMDV) representing all seven serotypes and including the first complete sequences of the SAT1 and SAT3 genomes. The data reveal novel highly conserved genomic regions, indicating functional constraints for variability as well as novel viral genomic motifs with likely biological relevance. Previously undescribed invariant motifs were identified in the 5' and 3' untranslated regions (UTR), as was tolerance for insertions/deletions in the 5' UTR. Fifty-eight percent of the amino acids encoded by FMDV isolates are invariant, suggesting that these residues are critical for virus biology. Novel, conserved sequence motifs with likely functional significance were identified within proteins L(pro), 1B, 1D, and 3C. An analysis of the complete FMDV genomes indicated phylogenetic incongruities between different genomic regions which were suggestive of interserotypic recombination. Additionally, a novel SAT virus lineage containing nonstructural protein-encoding regions distinct from other SAT and Euroasiatic lineages was identified. Insights into viral RNA sequence conservation and variability and genetic diversity in nature will likely impact our understanding of FMDV infections, host range, and transmission.

The binding of foot-and-mouth disease virus leader proteinase to eIF4GI involves conserved ionic interactions

The leader proteinase (L(pro)) of foot-and-mouth disease virus (FMDV) initially cleaves itself from the polyprotein. Subsequently, L(pro) cleaves the host proteins eukaryotic initiation factor (eIF) 4GI and 4GII. This prevents protein synthesis from capped cellular mRNAs; the viral RNA is still translated, initiating from an internal ribosome entry site. L(pro) cleaves eIF4GI between residues G674 and R675. We showed previously, however, that L(pro) binds to residues 640-669 of eIF4GI. Binding was substantially improved when the eIF4GI fragment contained the eIF4E binding site and eIF4E was present in the binding assay. L(pro) interacts with eIF4GI via residue C133 and residues 183-195 of the C-terminal extension. This binding domain lies about 25 A from the active site. Here, we examined the binding of L(pro) to eIF4GI fragments generated by in vitro translation to narrow the binding site down to residues 645-657 of human eIF4GI. Comparison of these amino acids with those in human eIF4GII as well as with sequences of eIF4GI from other organisms allowed us to identify two conserved basic residues (K646 and R650). Mutation of these residues was severely detrimental to L(pro) binding. Similarly, comparison of the sequence between residues 183 and 195 of L(pro) with those of other FMDV serotypes and equine rhinitis A virus showed that acidic residues D184 and E186 were highly conserved. Substitution of these residues in L(pro) significantly reduced eIF4GI binding and cleavage without affecting self-processing. Thus, FMDV L(pro) has evolved a domain that specifically recognizes a host cell protein.

Genome comparison of a novel foot-and-mouth disease virus with other FMDV strains

The genome of a novel foot-and-mouth disease virus, HKN/2002, was 8104 nucleotides (nt) in length (excluding the poly(C) tract and poly(A) tail) and was composed of a 1042-nt 5'-untranslated region (UTR), a 6966-nt open reading frame, and a 93-nt 3'-UTR. Genome sequences of HKN/2002 and other known FMDV strains were compared. The VP1, VP2, and VP3-based neighbor-joining (NJ) trees were divided into distinct clusters according to different serotypes, while other region-based NJ trees exhibited some degree of intercross among serotypes. Mutations in HKN/2002 were revealed, including frequent deletions and insertions in the G-H loop of VP1, and deletion involving 10 amino acid residues in the 3A protein. An evolutionary relationship of HKN/2002 with an Asian FMDV lineage isolated from a Hong Kong swine host in 1970 was postulated. A 43-nt deletion identified in the 5'-UTR of HKN/2002 possibly contributed to the loss of one pseudo-knot domain.

RNA-dependent RNA polymerase gene sequence from foot-and-mouth disease virus in Hong Kong

A foot-and-mouth disease virus (FMDV, HKN/2002) was isolated in Hong Kong in 2002. The nucleotide sequence of the 3D(pol) gene encoding the viral RNA-dependent RNA polymerase was determined and compared with that of the same gene from other FMDVs. The 3D(pol) gene was 1410 nucleotides in length encoding a protein of 470 amino acid residues. Sequence comparisons indicated that HKN/2002 belonged to serotype O. An evolutionary tree based on the 3D(pol) sequences of 20 FMDV isolates revealed that the nucleotide sequence of the HKN/2002 3D(pol) gene was most similar to those of isolates found in Taiwan in 1997, suggesting that they share a common ancestor. The amino acid sequence of the HKN/2002 3D(pol) gene was determined and aligned with those of representative isolates from seven other Picornaviridae genera. Eight highly conserved regions were detected, indicating a conserved functional relevance for these motifs. Alignment of 20 FMDV 3D(pol) amino acid sequences revealed a hypermutation region near the N-terminus that may help the virus evade host immune systems.

Molecular basis of pathogenesis of FMDV

Current understanding of the molecular basis of pathogenesis of foot-and-mouth disease (FMD) has been achieved through over 100 years of study into the biology of the etiologic agent, FMDV. Over the last 40 years, classical biochemical and physical analyses of FMDV grown in cell culture have helped to reveal the structure and function of the viral proteins, while knowledge gained by the study of the virus' genetic diversity has helped define structures that are essential for replication and production of disease. More recently, the availability of genetic engineering methodology has permitted the direct testing of hypotheses formulated concerning the role of individual RNA structures, coding regions and polypeptides in viral replication and disease. All of these approaches have been aided by the simultaneous study of other picornavirus pathogens of animals and man, most notably poliovirus. Although many questions of how FMDV causes its devastating disease remain, the following review provides a summary of the current state of knowledge into the molecular basis of the virus' interaction with its host that produces one of the most contagious and frightening diseases of animals or man.

Molecular epidemiology of foot-and-mouth disease virus

Foot-and-mouth disease (FMD) is the most economically important veterinary pathogen due to its highly infectious nature, ability to cause persistent infections and long term effects on the condition and productivity of the many animal species it affects. Countries which have the disease have many trade restrictions placed upon them. In the last 15 years there have been significant advances in the understanding of FMD epidemiology. These have largely been due to the application of the molecular biological techniques of polymerase chain-reaction amplification and nucleotide sequencing. In the World Reference Laboratory for FMD (Pirbright, UK), a large sequence database has been built up. This database has been used to aid in the global tracing of virus movements. It has been possible to genetically group many FMDV's based on their geographic origin and this has led to their being referred to as topotypes. The implications of this are that inter-regional spread of viruses can often be easily recognised and any evolutionary changes which subsequently occur can be monitored. Using these techniques, for the first time, we have been able to unequivocally show the recent pandemic spread of a FMDV type O strain through the whole of Asia and into Africa and Europe. This type of surveillance will become increasingly important as further globalisation of markets occurs. An increased understanding of how FMDV strains move between geographic regions will play a pivotal role in the development of future disease control strategies.

Genetic heterogeneity in the foot-and-mouth disease virus Leader and 3C proteinases

The Leader and 3C proteinases of foot-and-mouth disease virus (FMDV) are responsible for almost all the proteolytic processing events of the viral polyprotein precursor. Investigation into the genetic heterogeneity of the regions encoding these proteins from isolates of six FMDV serotypes revealed the 3C proteinase to be more conserved than the Leader proteinase. Maximum likelihood analysis indicated similar phylogenetic groupings for the non-structural protein coding regions of both the Leader and 3C. These groupings were different from the structural VP1 protein coding region which, as shown previously, grouped according to serotype. Two distinct clades were apparent for both the Leader and 3C coding regions: one comprising of serotypes A, O and C together with SAT (South African Territories) isolates from eastern Africa. The other clade consisted of SAT isolates originating from southern Africa. Only one virus isolate, obtained from a buffalo in Uganda, did not conform to this phylogenetic pattern. This SAT 1 virus grouped with types A, O and C in the Leader analysis, but with the southern African SAT types in the 3C analysis, implicating intertypic recombination. The leader proteinases of southern African SAT type isolates differed from those present in European type isolates, particularly in the self-processing region. A three-dimensional structure was modeled for the Leader proteinase of one of the SAT type viruses, ZIM/7/83/2, and compared with the previously elucidated crystal structure of O(1)Kaufbeuren Leader proteinase. The active sites of the two leaders were found to superimpose closely, despite the observed sequence variation between the two molecules. Comparison of the 3C proteinase P1 cleavage sites suggested that the FMDV 3C proteinase may possess a broader substrate specificity, as observed in hepatitis A virus 3C proteinase.