The T1/35kDa family of poxvirus-secreted proteins bind chemokines and modulate leukocyte influx into virus-infected tissues.

Immunomodulatory proteins encoded by the larger DNA viruses interact with a wide spectrum of immune effector molecules that regulate the antiviral response in the infected host. Here we show that certain poxviruses, including myxoma virus. Shope fibroma virus, rabbitpox virus, vaccinia virus (strain Lister), cowpox virus, and raccoonpox virus, express a new family of secreted proteins which interact with members of both the CC and CXC superfamilies of chemokines. However, swinepox virus and vaccinia virus (strain WR) do not express this activity Using a recombinant poxviruses, the myxoma M-T1 and rabbitpox virus 35kDa secreted proteins were identified as prototypic members of this family of chemokine binding proteins. Members of this T1/35kDa family of poxvirus-secreted proteins share multiple stretches of identical sequence motifs, including eight conserved cysteine residues, but are otherwise unrelated to any cellular genes in the database. The affinity of the CC chemokine RANTES interaction with M-T1 was assessed by Scatchard analysis and yielded a Kd of approximately 73 nM. In rabbits infected with a mutant rabbitpox virus, in which the 35kDa gene is deleted, there was an increased number of extravasating leukocytes in the deep dermis during the early phases of infection. These observations suggest that members of the T1/35kDa class of secreted viral proteins bind multiple members of the chemokine superfamily in vitro and modulate the influx of inflammatory cells into virus-infected tissues in vivo.

Differential inhibition of the Fas- and granule-mediated cytolysis pathways by the orthopoxvirus cytokine response modifier A/SPI-2 and SPI-1 protein.

Cytotoxic T lymphocytes are important effectors of antiviral immunity, and they induce target cell death either by secretion of cytoplasmic granules containing perforin and granzymes or by signaling through the Fas cell surface antigen. Although it is not known whether the granule-mediated and Fas-mediated cytolytic mechanisms share common components, proteinase activity has been implicated as an important feature of both pathways. The orthopoxviruses cowpox virus and rabbitpox virus each encode three members of the serpin family of proteinase inhibitors, designated SPI-1, SPI-2, and SPI-3. Of these, SPI-2 (also referred to as cytokine response modifier A in cowpox virus) has been shown to inhibit the proteolytic activity of both members of the interleukin 1 beta converting enzyme family and granzyme B. We report here that cells infected with cowpox or rabbitpox viruses exhibit resistance to cytolysis by either cytolytic mechanism. Whereas mutation of the cytokine response modifier A/SPI-2 gene was necessary to relieve inhibition of Fasmediated cytolysis, in some cell types mutation of SPI-1, in addition to cytokine response modifier A/SPI-2, was necessary to completely abrogate inhibition. In contrast, viral inhibition of granule-mediated killing was unaffected by mutation of cytokine response modifier A/SPI-2 alone, and it was relieved only when both the cytokine response modifier A/SPI-2 and SPI-1 genes were inactivated. These results suggest that an interleukin 1 beta converting enzyme-like enzymatic activity is involved in both killing mechanisms and indicate that two viral proteins, SPI-1 and cytokine response modifier A/SPI-2, are necessary to inhibit both cytolysis pathways.

Expression of the myxoma virus tumor necrosis factor receptor homologue and M11L genes is required to prevent virus-induced apoptosis in infected rabbit T lymphocytes.

Myxoma virus is a leporipoxvirus that causes a highly lethal virulent disease known as myxomatosis in the European rabbit. An important aspect of myxoma virus pathogenesis is the ability of the virus to productively infect lymphocytes and spread to secondary sites via lymphatic channels. We investigated the infection of the CD4+ T lymphoma cell line RL-5 with myxoma virus and Shope fibroma virus, a related but benign leporipoxvirus, and observed that myxoma virus, but not Shope fibroma virus, was able to productively infect RL-5 cells. We also discovered that infection of RL-5 cells with Shope fibroma virus or attenuated myxoma virus mutants containing disruptions in either the T2 or the M11L gene resulted in the rapid induction of DNA fragmentation, followed by morphological changes and loss in cell integrity characteristic of cell death by apoptosis. Purified exogenous T2 protein was unable to prevent apoptosis, suggesting that T2 functions intracellularly. Thus, myxoma virus T2, originally described as a secreted homologue of the tumor necrosis factor receptor, and M11L, a novel transmembrane species with no known cellular homologue, function to extend virus host range for replication in rabbit T lymphocytes through the inhibition of apoptosis in infected T lymphocytes.

SERP1, a serine proteinase inhibitor encoded by myxoma virus, is a secreted glycoprotein that interferes with inflammation.

Myxoma virus is a leporipoxvirus that causes a rapidly lethal, generalized infection known as myxomatosis in the European rabbit (Oryctolagus cuniculus). A characteristic feature of myxomatosis is the specific downregulation of key pathways important for numerous host defenses against the viral infection. The SERP1 gene has significant sequence similarity to the serpin superfamily of serine proteinase inhibitors and is one of many virulence factor genes located within the terminal regions of the myxoma virus genome. Transcriptional analysis of the SERP1 gene in myxoma virus (strain Lausanne) indicates that it is expressed as a late gene and studies using a polyclonal anti-SERP1 antiserum indicate that it encodes a secreted protein with an apparent molecular weight of 55 kDa. Using myxoma virus and recombinant vaccinia virus constructs for experiments with tunicamycin and peptide N-glycosidase F, it is shown that the secreted SERP1 protein is modified by N-linked glycosylation. Mutation of both copies of the SERP1 gene in myxoma virus results in a significant attenuation of the virus, such that more than 50% of infected animals are able to recover from the otherwise lethal infection. Histological analyses of lesions taken from infected animals suggest that in the absence of the SERP1 protein, a more effective inflammatory response occurs, allowing a more rapid resolution of the infection. This suggests that SERP1 contributes to viral pathogenesis by interacting with cellular component(s) involved in the regulation of inflammation.

Virus-induced loss of class I MHC antigens from the surface of cells infected with myxoma virus and malignant rabbit fibroma virus.

Shope fibroma virus (SFV) is a leporipoxvirus that causes localized benign fibromas in immunocompetent adult rabbits that spontaneously regress due, in part, to a cell-mediated immune response. Myxoma virus (MYX) and malignant rabbit fibroma virus (MRV) are related leporipoxviruses that induce rapidly lethal generalized infections accompanied by tumors and immunosuppression. Because only these latter two viruses are known to compromise cell-mediated antiviral responses, cell surface levels of class I MHC molecules in SFV-, MRV-, and MYX-infected cells were investigated by fluorescent activated cell sorting analysis using a variety of different anti-HLA mAb. After infection with MYX or MRV there is a rapid decrease in the levels of detectable surface class I epitopes as detected by each antibody and by 24 h postinfection class I MHC Ag levels at the cell surface approach the level of background fluorescence observed with control antibodies. In contrast, only a moderate class I decrease is seen during infection with either SFV or vaccinia virus, an orthopoxvirus that is neither tumorigenic nor immunosuppressive. Surface class I marker loss induced by MYX and MRV is not simply due to nonspecific inhibition of total cellular protein synthesis by the viruses because class I levels decrease much further than the extent measured by estimating surface marker turnover in the presence of the protein synthesis inhibitor cycloheximide. Thus the loss of cellular surface class I molecules greatly exceeds the drop in level caused by complete blockage of host cell gene expression, and must involve removal or masking of preexisting class I epitopes from the cell surface by MRV/MYX. Cell surface levels of the transferrin receptor are unaffected by MYX and MRV infection, suggesting the observed class I decrease is not a nonspecific effect on total cell surface glycoproteins. Analysis of cells infected with MRV/MYX in the presence of cycloheximide or of cytosine arabinoside, an inhibitor of poxviral DNA replication, indicates that the class I marker loss is mediated in part by one or more viral late gene products. A probable explanation is that MRV/MYX late protein(s) interact with the class I MHC complex to either physically sequester these away from the cell surface and inhibit their recycling or else induce a conformational change that precludes recognition by all class I antibodies tested. In either event, we propose that such a major perturbation of the class I MHC complex would likely downregulate the class I-mediated presentation of viral Ag required to initiate cell-mediated immunity to these viruses.

Myxoma virus expresses a secreted protein with homology to the tumor necrosis factor receptor gene family that contributes to viral virulence.

Poxviruses are known to contain a large number of open reading frames, particularly near the termini of the viral genome, that are not required for growth in tissue culture. However, many of these gene products are believed to play important roles in determining the virulence of the virus by modulating the host immune response to the infection. Recently it has been shown that Shope fibroma virus encodes, within the terminal inverted repeats, a protein (T2) related to the cellular tumor necrosis factor receptor (TNFR) and which specifically binds both TNF alpha and TNF beta. We have sequenced the terminal regions of two other Leporipoxviruses (myxoma virus and malignant rabbit fibroma virus) that are extremely invasive and capable of inducing extensive immunosuppression in rabbits and demonstrate that they also encode a closely related T2 homolog with all the structural motifs predicted for a secreted TNF binding protein. To investigate the biological role of the T2 protein, we have inactivated the myxoma virus T2 gene within each copy of the viral TIR by the insertion of a dominant selectable marker (Escherichia coli guanosine phosphoribosyltransferase) and selection of the recombinant virus in the presence of mycophenolic acid. The success of the inactivation of both copies of T2 was confirmed by the loss a broad protein band (52-56 kDa) of the predicted size for T2 from the profile of proteins secreted from mutant virus-infected BGMK cells at early times after infection. Although the T2-minus recombinant myxoma virus grew normally in tissue culture, upon infection of susceptible rabbits the viral disease was observed to be significantly attenuated. The majority of infected rabbits were able to mount an effective immune response to the infection and completely recovered. These survivor rabbits became immune to subsequent challenge with wild type myxoma virus. We conclude that the T2 viral protein is an important secreted virulence factor and that it in all likelihood functions by compromising the antiviral effects of TNF. We propose the term "viroceptor" to describe viral-encoded homologs of cellular lymphokine receptors whose function is to intercept the activity of the cognate lymphokine in order to short circuit the host immune response to the viral infection.

Myxoma virus and malignant rabbit fibroma virus encode a serpin-like protein important for virus virulence.

The leporipoxviruses Shope fibroma virus (SFV), the myxoma virus (MYX), and the SFV/MYX recombinant malignant rabbit fibroma virus (MRV) are closely related yet induce profoundly different diseases in the European rabbit. SFV, which produces a benign tumor at the site of inoculation, is cleared by the immune system after approximately 2 weeks whereas MYX and MRV induce a rapidly lethal systemic infection characterized by generalized suppression of host immune functions. DNA sequencing studies reveal that MRV and MYX possess homologous gene members of the T6/T8/T9 family originally described in the terminal inverted repeat (TIR) of SFV. We also describe a gene present in both MYX and MRV genomes, but which has apparently evolved in the SFV genome into a fragmented pseudogene that appears to contribute to the aggressive nature of MYX and MRV infections. Translation of this open reading frame, designated MYXOMA SERPIN 1 (SERP1), reveals a protein sequence with highly significant homology to the super-family of serine protease inhibitors (serpins) which also includes a number of other poxviral proteins. In the MYX genome the SERP1 gene lies entirely within the TIR sequences and is thus present as two copies, while in the MRV genome SERP1 is present in the unique sequences adjacent to the TIR boundary and hence is a single copy. The amino acid homology between the putative active site of SERP1 and those of other serpins predicts that the target enzyme will be different from the known catalog of serine antiprotease substrates. Deletion of this gene from MRV significantly attenuates the disease spectrum induced by the normally lethal virus. Although the MRV-S1 deletion construct (MRV with SERP1 gene deleted) grows in all tissue culture cells tested in a fashion identical to the MRV parent, the majority of rabbits infected with MRV-S1 are able to mount an effective immune response and totally recover from the virus infection to become resistant to subsequent challenge by MRV or MYX.

Tumorigenic poxviruses: fine analysis of the recombination junctions in malignant rabbit fibroma virus, a recombinant between Shope fibroma virus and myxoma virus.

Malignant rabbit fibroma virus (MRV) has been shown to be a lethal tumorigenic poxvirus of rabbits derived from a recombination event between Shope fibroma virus (SFV), which induces benign fibromas in rabbits, and myxoma virus, the agent of myxomatosis. We have cloned and sequenced all of the MRV recombination junctions, which are located near the left and right terminal inverted repeat (TIR) regions, and present a composite map of the MRV genome with respect to the relevant gene products. The two junctions closet to the MRV termini, at identical positions at the left and right ends, are at nucleotide 5272 and result in an in-frame fusion protein (ORF T-5) in which the N-terminal 232 aa are derived from an SFV sequence linked to a C-terminus derived from myxoma. At the left MRV TIR the recombination junction distal from the terminus maps to nucleotide 9946 but leaves the adjacent gene virtually unchanged from its SFV homolog. At the right terminus, the relevant junction sequences from MRV and myxoma could not be cloned in wild-type Escherichia coli but were maintained stably in a recA recBC sbcB host. The SFV/myxoma junction at this location maps 5' to a growth factor gene (SFGF) which is related to those encoding epidermal growth factor and transforming growth factor-alpha. As a result, the myxoma growth factor gene has been deleted in MRV and replaced in toto by the SFV gene. The recombination junction upstream from the SFGF gene creates an in-frame fusion in ORF T11-R in which the N-terminal amino acids are derived from myxoma and the remainder from SFV. In summary, MRV has received the following ORFs from SFV: at the left terminus T5 (fusion), T6, T7, and T8; at the right terminus, T5 (fusion), T6, T7, T8, T9-R, SFGF, and T11-R (fusion).

Mapping and sequencing of a gene from myxoma virus that is related to those encoding epidermal growth factor and transforming growth factor alpha.

Myxoma virus, a Leporipoxvirus and agent of myxomatosis, was shown to possess a gene with the potential to encode an epidermal growth factorlike factor. Its relationship to other members of this family, including the poxvirus growth factors from Shope fibroma virus and vaccinia virus, was analyzed. Alignment of DNA sequences and related open reading frames of myxoma virus and Shope fibroma virus indicated colinearity of genes between these poxviruses.