猪瘟病毒C株共感染口蹄疫病毒影响口蹄疫病毒复制

【背景】猪瘟(Classical Swine Fever)是由猪瘟病毒(Classical Swine Fever Virus,CSFV)引起的猪高度接触性传染病,致死率极高。在临床中存在着CSFV与猪其他病原菌共感染的情况,例如CSFV与口蹄疫病毒(Foot-and-Mouth Disease Virus,FMDV)的共感染。【目的】利用CSFV与FMDV共感染猪源宿主细胞,研究CSFV与FMDV共感染对FMDV病毒复制的影响。【方法】构建体外共感染细胞模型,在正常PK-15细胞上进行CSFV共感染FMDV实验,通过观察细胞病变效应(Cytopathic Effect,CPE)、实时荧光定量PCR(RT-qPCR)、Western Blot、间接免疫荧光检测CSFV和FMDV共感染及FMDV单独感染情况下FMDV复制水平的差异。利用RT-qPCR筛选鉴定能够影响FMDV复制的CSFV蛋白。【结果】CSFVC株共感染FMDV能够抑制FMDV的复制,而且灭活的CSFV同样抑制FMDV的复制。通过筛选鉴定出CSFV的C蛋白能够抑制FMDV复制。【结论】研究发现CSFV C株共感染FMDV能够抑制FMDV复制,而其C蛋白具有抑制FMDV复制的能力。     

Sequence of the viral replicase gene from foot-and-mouth disease virus C1-Santa Pau (C-S8)

The nucleotide sequence of the region including the viral replicase gene, the carboxy terminus of protein P18, and the 3'-extracistronic region of foot-and-mouth disease virus (FMDV) type C1-Santa Pau (C-S8) has been determined from previously cloned cDNA fragments [Villanueva et al., Gene 23 (1983) 185-194]. The comparison with the corresponding gene segments of FMDV of serotypes A or O shows base substitutions in 7.2-8.6% of residues in the replicase gene with no insertions or deletions. This is about fourfold lower variation than found for the region encoding capsid protein VP1 of the corresponding viruses. Intermediate variability (substitution at 16.1-23.6% positions) exists in the 3'-extracistronic region, including point mutations, insertions and deletions. The predicted amino acid sequence of the replicase gene indicates that 75.5-82.6% of mutations are silent and that 93.4% of amino acids are conserved in the four FMDV replicases. The frequency of certain types of silent mutations and of rare codon usage is significantly lower for the replicase gene than for the protein VP1 coding region.     

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.     

Phylogenomics and molecular evolution of foot-and-mouth disease virus

This report describes the use of Bayesian methods to analyze polyprotein coding region sequences (n = 217) obtained from GenBank to define the genome-wide phylogeny of foot and mouth disease virus (FMDV). The results strongly supported the monophyly of five FMDV serotypes, O, A, Asia 1, C, and SAT 3, while sequences for the two remaining FMDV serotypes, SAT 1 and SAT 2 did not separate into entirely distinct clades. The phylogenomic tree revealed three sister-group relationships, serotype O + Asia 1, A + C, and SAT 1 + 3 + 2, with a new branching pattern: {[(O, Asia 1), (A, C)], (SAT 1, 2, 3)}. Within each serotype, there was no apparent periodic, geographic, or host species influence on the evolution of global FMDVs. Analysis of the polyprotein coding region of these sequences provided evidence for the influence of purifying selection on the evolution of FMDV. Using a Bayesian coalescent approach, the evolutionary rate of FMDV isolates that circulated during the years 1932-2007 was estimated to be 1.46 × 10(-3) substitutions/site/year, and the most recent common ancestor of the virus existed approximately 481 years ago. Bayesian skyline plot revealed a population expansion in the early 20(th) century that was followed by a rapid decline in population size from the late 20(th) century to the present day. These findings provide new insights into the mechanisms that impact on the evolution of this important livestock pathogen.     

Electrical properties of the foot-and-mouth disease virus

It has been shown that the electron microscopy method can be used for characteristics of the electric properties of foot-and-mouth disease virus. The appearance of simultaneous positive and negative staining during the negative staining of virus preparations with 3-4% PTV solution shows the presence of full virions of constant poles designated as positively and negatively stained areas of protein coat surface. The lateral orientation of virions on the film at routine conditions of preparation and the possibility of virion orientation on the film in the external electrical field allow to characterize the full virions as electric dipoles. It has been suggested that there is a relationship between a virus structure and the character of its electric properties.     

The pH stability of foot-and-mouth disease virus

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This review summarized the molecular determinants of the acid stability of FMDV in order to explore the uncoating mechanism of FMDV and improve the acid stability of vaccines.

Background

The foot-and-mouth disease virus (FMDV) capsid is highly acid labile and tends to dissociate into pentameric subunits at acidic condition to release viral RNA for initiating virus replication. However, the acid stability of virus capsid is greatly required for the maintenance of intact virion during the process of virus culture and vaccine production. The conflict between the acid lability in vivo and acid stability in vitro of FMDV capsid promotes the selection of a series of amino acid substitutions which can confer resistance to acid-induced FMDV inactivation. In order to explore the uncoating activity of FMDV and enhance the acid stability of vaccines, we summarized the available works about the pH stability of FMDV.

Main body of the abstract

In this review, we analyzed the intrinsic reasons for the acid instability of FMDV from the structural and functional aspects. We also listed all substitutions obtained by different research methods and showed them in the partial capsid of FMDV. We found that a quadrangle region in the viral capsid was the place where a great many pH-sensitive residues were distributed. As the uncoating event of FMDV is dependent on the pH-sensitive amino acid residues in the capsid, this most pH-sensitive position indicates a potential candidate location for RNA delivery triggered by the acid-induced coat disassociation.

Short conclusion

This review provided an overview of the pH stability of FMDV. The study of pH stability of FMDV not only contributes to the exploration of molecule and mechanism information for FMDV uncoating, but also enlightens the development of FMDV vaccines, including the traditionally inactivated vaccines and the new VLP (virus-like particle) vaccines.

     

Influence of salts on foot-and-mouth disease virus

The effect of sodium and magnesium chloride in 1 and 2 m concentration at temperatures of 37 and 50 C on type C, strain 149, foot-and-mouth disease virus during storage for 6 days was studied. The exclusively passaged cattle strain and its tissue culture-adapted line were compared. Preparations of the various chemicals and their concentrations were made directly in suspensions of the virus, which, together with untreated control virus suspensions, were stored at indicated temperatures and tested daily for concentration of virus present. Both 1 and 2 m concentrations of Mg markedly slowed the degradation of the bovine-passaged virus, as compared with untreated virus stored at 37 or 50 C. Such was not the case with 1 and 2 m concentrations of Na at 37 and 50 C, in which instance the treated virus was degraded faster than the untreated controls at 37 C, and but slightly influenced at 50 C. The tissue culture-adapted virus at the 25th passage was not stabilized by any concentration of chemical additive either at 37 or 50 C, except for 1 and 2 m concentrations of Na at 37 C, which partially retarded degradation of the virus. After 91 passages of the virus in tissue culture, only a suggestion of the influence of 1 and 2 m concentrations of Na at 37 C remained to show a stabilizing effect. These responses tend to separate the bovine-passaged virus from the tissue culture-adapted virus under the conditions of this study.     

Interaction of foot-and-mouth disease virus with dendritic cells

Despite several decades of investigation, the manner in which foot-and-mouth disease virus (FMDV) interacts with the innate and adaptive immune compartments is not completely understood. The importance of elucidating this relationship is emphasized by the inability of current FMDV vaccines to provide long-term protection and the recent outbreaks of FMDV in formerly disease-free countries. Dendritic cells (DCs) are professional antigen-presenting cells that have evolved to monitor the environment and provide a link between the innate and adaptive immune systems. Comprehending the cross-talk between DC and FMDV will provide valuable information towards understanding the host response to the virus and will aid in the design of effective tools and vaccines to block virus spread.     

In vitro morphogenesis of foot-and-mouth disease virus.

Foot-and-mouth disease virion RNA is translated efficiently and completely in a rabbit reticulocyte lysate cell-free system. Treatment of cell-free lysates with monospecific serum prepared against the individual viral structural proteins or with monoclonal antibodies prepared against the inactivated virus or against a viral structural protein precipitated all of the structural proteins, suggesting that structural protein complexes were formed in vitro. Sucrose gradient analysis of the cell-free lysate indicated that complexes sedimenting at 5, 14, 60 to 70, and ca. 110S were assembled in vitro. Structural proteins VP0, VP1, and VP3 were the major polypeptides found in these complexes. The material sedimenting at 110S, i.e., containing VP0, VP1, and VP3, was precipitated by a 140S-specific monoclonal antibody but not by a 12S subunit-specific monoclonal antibody, suggesting that this capsid structure contained at least one epitope present on the intact virus.     

口蹄疫病毒受体的结构与功能研究进展

口蹄疫病毒（FMDV）感染过程中的特异性受体是FMDV识别,结合宿主细胞的分子基础,研究FMDV受体的结构与功能对防治口蹄疫具有重要的理论意义和应用价值。本论述了近年来关于整联蛋白αvβ3,αvβ6和硫酸乙酰肝素（HS）三种FMDV受体的结构与功能的研究进展。     

Nucleotide sequence and genome organization of foot-and-mouth disease virus.

A continuous 7802 nucleotide sequence spanning the 94% of foot and mouth disease virus RNA between the 5'-proximal poly(C) tract and the 3'-terminal poly(A) was obtained from cloned cDNA, and the total size of the RNA genome was corrected to 8450 nucleotides. A long open reading frame was identified within this sequence starting about 1300 bases from the 5' end of the RNA genome and extending to a termination codon 92 bases from its polyadenylated 3' end. The protein sequence of 2332 amino acids deduced from this coding sequence was correlated with the 260 K FMDV polyprotein. Its processing sites and twelve mature viral proteins were inferred from protein data, available for some proteins, a predicted cleavage specificity of an FMDV encoded protease for Glu/Gly(Thr, Ser) linkages, and homologies to related proteins from poliovirus. In addition, a short unlinked reading frame of 92 codons has been identified by sequence homology to the polyprotein initiation signal and by in vitro translation studies.     

Function of minor polypeptides in foot-and-mouth disease virus and poliovirus

Foot-and-mouth disease virus and poliovirus each contain several minor polypeptides, in addition to the four structural proteins. One of these, the viral RNA polymerase, can also act as a nuclease, hydrolysing the RNA and thus destroying viral infectivity. It is tightly bound to the RNA and may be the packaging signal for assembly of the particle.     

Multiple proteases in foot-and-mouth disease virus replication.

Translation of foot-and-mouth disease virus RNA in a rabbit reticulocyte lysate for short time intervals resulted in the production of the peptides P20a , P16, and P88 (Lab, Lb, and P1) (R. R. Rueckert , Recommendations of the 3rd European Study Group on Molecular Biology of Picornavirus, Urbino , Italy, 1983). If further translation was prevented, the structural protein precursor P88 was not cleaved, even after prolonged incubation. This result indicates that the mechanism of the cleavage between P20a -P16 and P88 and of that between P88 and P52 (P2) differs from the mechanism of the secondary cleavages which produce the structural proteins. Furthermore, treatment of foot-and-mouth disease virus-infected cells with the protease inhibitor D-valyl phenylalanyl lysyl chloromethyl ketone prevented the in vivo cleavage between P20a -P16 and P88 but had no effect on any of the other cleavage events. These results suggest that the cleavage of the foot-and-mouth disease virus polyprotein utilizes two different host proteases.     

Crystallization and preliminary X-ray diffraction analysis of foot-and-mouth disease virus

Foot-and-mouth disease virus has been crystallized with the objectives of (1) determining the composition and conformation of the major immunogenic site(s) and (2) comparing its structure with those of the related polio, rhino and Mengo viruses, representing the other three genera of the picornaviruses. Most of the work has been done with virus strain O1BFS 1860, which crystallized as small rhombic dodecahedra of maximum dimension 0.3 mm. Virus recovered from crystals was infectious, and was indistinguishable from native virus both in protein composition and buoyant density. The stability of the crystals in the X-ray beam was comparable with that of other picornavirus crystals and they diffracted to a resolution of better than 2.3 A. Initial analysis of the X-ray diffraction data shows the virus to be positioned on a point of 23 symmetry in a close-packed array so that examples of all the icosahedral symmetry elements, except the 5-fold axes, are expressed crystallographically. The cell dimensions are a = b = c = 345 A, alpha = beta = gamma = 90 degrees, with a space group of I23. The diameter of the virus particle is 300 A. Despite the small size of the crystals, diffraction data have been collected to a reasonable resolution using a synchrotron source. Phasing of the diffraction data will be attempted using the methods of molecular replacement.