Identification and screening of host proteins interacting with ORFV-ORF047 protein.

BACKGROUND: Orf virus (ORFV) is a member of the genus Parapoxvirus and family Poxviridae. The virus has a worldwide distribution and infects sheep, goats, humans, and wild animals. However, due to the complex structure of the poxvirus, the underlying mechanism of the entry and infection by ORFV remains largely unknown. ORFV ORF047 encodes a protein named L1R. Poxviral L1R serves as the receptor-binding protein and blocks virus binding and entry independently of glycosaminoglycans (GAGs). The study aimed to identify the host interaction partners of ORFV ORF047. METHODS: Yeast two-hybrid cDNA library of sheep testicular cells was applied to screen the host targets with ORF047 as the bait. ORF047 was cloned into a pBT3-N vector and expressed in the NMY51 yeast strain. Then, the expression of bait proteins was validated by Western blot analysis. RESULTS: Sheep SERP1and PABPC4 were identified as host target proteins of ORFV ORF047, and a Co-IP assay further verified their interaction. CONCLUSIONS: New host cell proteins SERP1and PABPC4 were found to interact with ORFV ORF047 and might involve viral mRNA translation and replication.

Crystal structures of ORFV125 provide insight into orf virus-mediated inhibition of apoptosis.

Premature apoptosis of cells is a strategy utilized by multicellular organisms to counter microbial threats. Orf virus (ORFV) is a large double-stranded DNA virus belonging to the poxviridae. ORFV encodes for an apoptosis inhibitory protein ORFV125 homologous to B-cell lymphoma 2 or Bcl-2 family proteins, which has been shown to inhibit host cell encoded pro-apoptotic Bcl-2 proteins. However, the structural basis of apoptosis inhibition by ORFV125 remains to be clarified. We show that ORFV125 is able to bind to a range of peptides spanning the BH3 motif of human pro-apoptotic Bcl-2 proteins including Bax, Bak, Puma and Hrk with modest to weak affinity. We then determined the crystal structures of ORFV125 alone as well as bound to the highest affinity ligand Bax BH3 motif. ORFV125 adopts a globular Bcl-2 fold comprising 7 α-helices, and utilizes the canonical Bcl-2 binding groove to engage pro-apoptotic host cell Bcl-2 proteins. In contrast with a previously predicted structure, ORFV125 adopts a domain-swapped dimeric topology, where the α1 helix from one protomer is swapped into a neighbouring unit. Furthermore, ORFV125 differs from the conserved architecture of the Bcl-2 binding groove and instead of α3 helix forming one of the binding groove walls, ORFV125 utilizes an extended α2 helix that comprises the equivalent region of helix α3. This results in a subtle variation of previously observed dimeric Bcl-2 architectures in other poxvirus and human encoded Bcl-2 proteins. Overall, our results provide a structural and mechanistic basis for orf virus-mediated inhibition of host cell apoptosis.

Structural Features of a Conformation-dependent Antigen Epitope on ORFV-B2L Recognized by the 2E4 mAb.

Previously, we successfully prepared a monoclonal antibody (mAb) named 2E4, that directly recognizes the major envelope protein B2L of the orf virus (ORFV), but there is little information about its epitope. Here, we meticulously mapped the 2E4 epitope through combinatorial programs and identified the functional binding domain and a key amino acid residue. Briefly, the simulated epitope peptide closely resembles 84VDVQSKDKDADELR97 located at the N-terminus of B2L, strongly suggesting that the epitope is conformationally or spatially structure-dependent. Subsequently, we combined these findings with the results from the antigenicity prediction of B2L to design three truncated fragments of B2L (F1, F2 and F3) selected using 2E4, and only the F1 fragment was found to be eligible for the advanced stage. Alanine-scanning mutagenesis suggested that the D94 residue is structurally crucial for the 2E4 epitope. The other participating residues, including K61, E62, and D92, together with D94 were responsible for enabling 2E4 binding and served as factors that synergistically enabled binding to the whole 2E4 epitope. In this paper, we describe, for the first time, the architecture of an ORFV conformational epitope, and it is also expected that mAb 2E4 and its epitope can be used for applications relating to orf control.

Structures of Orf Virus Chemokine Binding Protein in Complex with Host Chemokines Reveal Clues to Broad Binding Specificity.

The chemokine binding protein (CKBP) from orf virus (ORFV) binds with high affinity to chemokines from three classes, C, CC, and CXC, making it unique among poxvirus CKBPs described to date. We present its crystal structure alone and in complex with three CC chemokines, CCL2, CCL3, and CCL7. ORFV CKBP possesses a ß-sandwich fold that is electrostatically and sterically complementary to its binding partners. Chemokines bind primarily through interactions involving the N-terminal loop and a hydrophobic recess on the ORFV CKBP ß-sheet II surface, and largely polar interactions between the chemokine 20s loop and a negatively charged surface groove located at one end of the CKBP ß-sheet II surface. ORFV CKBP interacts with leukocyte receptor and glycosaminoglycan binding sites found on the surface of bound chemokines. SEC-MALLS and chromatographic evidence is presented supporting that ORFV CKBP is a dimer in solution over a broad range of protein concentrations.

[Characterization of a recombinant goatpox virus expressing Orfv F1L gene].

OBJECTIVE: In order to establish the vaccine against the contagious ecthyma, we constructed and characterized recombinant goatpox virus expressing F1L protein of Orf virus. METHODS: The F1L gene was amplified and cloned into the vector pUC-TK12 carrying the LacZ gene and a bidirectional promoter. With the help of lipidosome, the recombinant plasmid pTL-F1L was transfected into the BHK-21 cells, which had been infected by Gpv. The aim is to make the Gpv and pTL-F1L recombined randomly and get the recombinant virus, which was defined as rGpv-F1L. The rGpv-F1L was screened by blue plaque, and then the F1L recombination and translation were identified by PCR, indirect immunofluorescence and Western blot. By the means of TCID50, we evaluated the physicochemical properties of rGpv-F1L. Female mice were immunized with the rGpv-F1L, and the specific antibodies levels in serum were detected by ELISA. RESULTS: We obtained rGpv-F1L, which was stably expressing F1L protein. The results of biological characteristics showed the rGpv-F1L was sensitive to acids, alkalis, organic solvents and ultraviolet. The activity of specific antibodies significantly increased in mice infected by rGpv-F1L more than Gpv (P < 0.01). CONCLUSION: In this research, we have successfully obtained the candidate vaccine, which is stably expressing F1L of Orf virus. Thereby the candidate vaccine with excellent antigenicity and biological activity provides new avenues for the prevention of contagious ecthyma and capripox.

Preparation of truncated orf virus entry fusion complex proteins by chemical synthesis.

Members of the Chordopoxvirinae subfamily possess an unusual 11 protein entry-fusion complex (EFC) that is highly conserved and present in all species. The mode of action of this EFC is unknown, and the interactions of the constituent proteins are uncharacterised. Here, we present the chemical synthesis of membrane domain truncated linear constructs of two EFC proteins in orf virus, ORFV036 and 049. By using Boc solid phase peptide synthesis and native chemical ligation methods, these truncated proteins have been readily prepared in milligram quantities. These robust synthetic protocols allow ready access to these polypeptides to facilitate biological studies.

Purification and functional motifs of the recombinant ATPase of orf virus.

Our previous study showed that the recombinant ATPase encoded by the A32L gene of orf virus displayed ATP hydrolysis activity as predicted from its amino acids sequence. This viral ATPase contains four known functional motifs (motifs I-IV) and a novel AYDG motif; they are essential for ATP hydrolysis reaction by binding ATP and magnesium ions. The motifs I and II correspond with the Walker A and B motifs of the typical ATPase, respectively. To examine the biochemical roles of these five conserved motifs, recombinant ATPases of five deletion mutants derived from the Taiping strain were expressed and purified. Their ATPase functions were assayed and compared with those of two wild type strains, Taiping and Nantou isolated in Taiwan. Our results showed that deletions at motifs I-III or IV exhibited lower activity than that of the wild type. Interestingly, deletion of AYDG motif decreased the ATPase activity more significantly than those of motifs I-IV deletions. Divalent ions such as magnesium and calcium were essential for ATPase activity. Moreover, our recombinant proteins of orf virus also demonstrated GTPase activity, though weaker than the original ATPase activity.

Crystallization and preliminary X-ray analysis of the chemokine-binding protein from orf virus (Poxviridae).

The parapoxvirus orf virus (ORFV) encodes a chemokine-binding protein (CBP) that functions to downregulate the host's immune response at the site of infection by blocking the chemokine-induced recruitment of immune cells. In order to shed light on the structural determinants of CBP-chemokine binding, ORFV CBP was crystallized as part of an ongoing structure-function study on this protein. ORFV CBP crystals were obtained by the sitting-drop vapour-diffusion technique using ammonium citrate as a precipitant. The crystal quality was greatly improved through the addition of small-molecule additives to the crystallization mother liquor. ORFV CBP crystals diffracted X-rays to 2.50 A resolution and belonged to the hexagonal space group P6(1)22 or its enantiomorph P6(5)22, with unit-cell parameters a = b = 75.62, c = 282.49 A, alpha = 90, beta = 90, gamma = 120 degrees.

Orf virus interleukin-10 inhibits cytokine synthesis in activated human THP-1 monocytes, but only partially impairs their proliferation.

The sheep parapoxvirus orf virus (ORFV) induces acute, pustular skin lesions in humans. ORFV encodes an orthologue of interleukin-10 (IL-10) that, whilst it closely resembles ovine IL-10 (91 % amino acid identity), shows only 75 % amino acid identity to human IL-10 (hIL-10). The anti-inflammatory potential of ORFV IL-10 in human ORFV infection was investigated by examining its immunosuppressive effects on THP-1 monocytes. ORFV IL-10 and hIL-10 were shown to have equivalent inhibitory effects on the synthesis of proinflammatory cytokines in lipopolysaccharide-activated monocytes, but differed in their abilities to inhibit monocyte proliferation. Structural modelling of ORFV IL-10 revealed differences from hIL-10 in residues predicted to interact with IL-10 co-receptor 2 (IL-10R2), whereas there were very few differences in the residues predicted to interact with IL-10R1. These findings suggest that the partial ability of ORFV IL-10 to inhibit THP-1 monocyte proliferation may be due to the absence of critical residues that mediate the interaction with human IL-10R2.

Molecular characterization of Brazilian isolates of orf virus.

Outbreaks of an epidermic disease suggesting parapox virus infections have been observed in all major herds of sheep and goats from different geographical areas of Brazil. Clinical samples (dried scabs) were collected and orf virus was isolated and characterized by electron microscopy in previous work. In order to characterize these viruses at the molecular level, a modified methodology for genomic DNA extraction directly from scabs was used and such DNA was used to derive the restriction enzyme digestion patterns for clinical samples from three distinct geographic origins. Pulsed field gel electrophoresis was used to separate restriction enzyme DNA fragments and heterogeneity among isolates from different geographic areas could be observed on stained gels. The HindIII-G DNA fragment from orf-A virus genome was cloned and hybridized to DNA of other orf virus isolates. Further heterogeneity was confirmed by these hybridizations.

The reactivity of monoclonal antibodies against orf virus with other parapoxviruses and the identification of a 39 kDa immunodominant protein.

A panel of 27 mouse monoclonal antibodies (Mabs) was raised against orf virus. Sixteen of these Mabs reacted with a protein with a molecular mass of 65 kDa, 8 reacted with a protein with a molecular mass of 39 kDa and three remain uncharacterised. Reactivity of the Mabs with a library of recombinant vaccinia viruses expressing various regions of the NZ-2 orf virus genome identified the approximate positions of the genes encoding these 2 immunodominant orf virus proteins. The gene encoding the 39 kDa protein was identified and sequenced. The protein was detected in an envelope fraction of orf virus and was shown to be homologous to the envelope protein encoded by the H3L gene of vaccinia virus. The 65 kDa protein has not been fully chracterised, but the gene encoding it has been localised to a 10 kbp region of the orf virus genome. The Mabs were used to discriminate 4 parapoxviruses derived from sheep, 2 from cattle and 1 each from a seal and squirrel. Eighteen Mabs reacted with all 4 sheep viruses, 19 Mabs reacted with both cattle viruses, 6 recognised seal parapoxvirus and 2 recognised the squirrel parapoxvirus. Only one of the 27 Mabs reacted with all 8 parapoxviruses suggesting it recognises a conserved epitope within the genus.

The establishment of a genetic map of orf virus reveals a pattern of genomic organization that is highly conserved among divergent poxviruses.

The large differences between the G+C content of the orf virus genome and those of other characterized poxviruses have precluded the use of DNA hybridization to establish a gene map of orf virus. Here we have sequenced the ends of cloned restriction endonuclease fragments of the nZ2 strain of orf virus (OV) and used the translated sequences to search protein data bases. Sequence from 15 points found high-scoring matches to data base entries, including 18 vaccinia virus (VAC) genes. We also present 2 kb of sequence from a region near the right terminus of the OV genome and show that it encodes homologs of VAC genes, F9L and F10L. The data presented here in conjunction with published and as yet unpublished data have allowed the construction of a gene map of OV on which 37 genes have been placed. Thirty-two of these genes have homologs in VAC. Alignment of the OV gene map with that of VAC revealed that each OV gene and its VAC counterpart occurred in the same order and orientation on their respective genomes. The intervals between many of the points of sequence were also found to be strikingly similar. The conserved spacing of genes between OV and VAC within the central 88.2 kb of the 139-kb OV genome is not maintained in the termini where insertion, deletion, and translocation have occurred. Parallels are drawn between the data presented here and related data from swinepox virus and capripox virus.