Antonio Alcami

Vaccinia virus encodes a soluble type I interferon receptor of novel structure and broad species soecificity

Vaccinia virus (VV) and other orthopoxviruses express a soluble type I interferon (IFN) receptor that for VV strain Western Reserve is encoded by gene B18R. The 60-65 kDa glycoprotein is related to the interleukin-1 receptors and is a member of the immunoglobulin superfamily, unlike other type I IFN receptors, which belong to the class II cytokine receptor family. The receptor has high affinity (KD, 174 pM) for human IFN alpha and, unlike other type I IFN receptors, has broad species specificity, binding to human, rabbit, bovine, rat, and mouse type I IFNs. This may have aided VV replication in multiple host species during evolution. A VV B18R deletion mutant is attenuated in a murine intranasal model. This type I IFN receptor represents the fourth VV protein that interferes with IFN and the fourth soluble cytokine receptor expressed by poxviruses.

A soluble receptor for interleukin-1β encoded by vaccinia virus: A novel mechanism of virus modulation of the host response to infection

Vaccinia virus gene B15R is shown to encode an abundant, secretory glycoprotein that functions as a soluble interleukin-1 (IL-1) receptor. This IL-1 receptor has novel specificity since, in contrast with cellular counterparts, it binds only IL-1 beta and not IL-1 alpha or the natural competitor IL-1 receptor antagonist. The vaccinia IL-1 beta receptor is secreted when expressed in a baculovirus system and competitively inhibited binding of IL-1 beta to the natural receptor on T cells. Deletion of B15R from vaccinia virus accelerated the appearance of symptoms of illness and mortality in intranasally infected mice, suggesting that the blockade of IL-1 beta by vaccinia virus can diminish the systemic acute phase response to infection and modulate the severity of the disease. The IL-1 beta binding activity is present in other orthopoxviruses.

Vaccinia virus immune evasion

Vaccinia virus and other poxviruses express a wide variety of proteins which are nonessential for virus replication in culture but help the virus to evade the host response to infection. Examples include proteins which oppose apoptosis. Synthesise steroids, capture chemokines, counteract complement, interfere with interferon and intercept interleukins. This review provides an overview of such proteins, with an emphasis on work from our laboratory, and illustrates how the study of these proteins can increase our understanding of virus pathogenesis, the function of the immune system and how to make safer and more immunogenic poxvirus‐based vaccines.

Vaccinia virus serpin B13R (SPI-2) inhibits interleukin-1beta-converting enzyme and protects virus-infected cells from TNF- and Fas-mediated apoptosis, but does not prevent IL-1beta-induced fever.

The vaccinia virus (VV) strain Western Reserve B13R gene encodes a 38.5 kDa intracellular polypeptide that is non-essential for virus replication in vitro and does not affect virus virulence in a murine intranasal model. The protein has 92% amino acid identity with the cowpox virus cytokine response modifier A (crmA) protein which inhibits the interleukin (IL)-1beta converting enzyme (ICE). Here, we show that extracts from THP-1 cells infected with VV strains expressing B13R prevent the cleavage of in vitro transcribed and translated pro-IL-1beta into mature IL-1beta. Similarly, THP-1 cells infected with VVs expressing B13R process pro-IL-1beta into mature IL-1beta inefficiently in situ. Despite its inhibition of ICE, B13R does not prevent fever in infected mice, a systemic effect mediated by IL-1beta. Instead, fever is controlled by the VV IL-1beta receptor, encoded by gene B15R, and deletion of both the B13R and B15R genes did not increase the febrile response compared to deletion of B15R alone. The B13R protein does, however, block apoptosis mediated by anti-Fas antibodies or by tumour necrosis factor (TNF) and cycloheximide. Using DNA fragmentation, chromium release and microscopic analyses it was shown that cells infected with wild-type VV strain WR, or a revertant virus in which the B13R gene had been re-inserted into the B13R deletion mutant, are more resistant than uninfected cells or deletion mutant-infected cells to apoptosis mediated by anti-Fas and TNF.

Impaired Antiviral Response and Alpha/Beta Interferon Induction in Mice Lacking Beta Interferon

ABSTRACT We have generated mice lacking the gene for beta interferon and report that they are highly susceptible to vaccinia virus infection. Furthermore, in cultured embryo fibroblasts, viral induction of alpha interferon and of 2-5A synthetase genes is impaired. We also show that beta interferon does not prime its own expression.

Vaccinia virus strains Lister, USSR and Evans express soluble and cell-surface tumour necrosis factor receptors

Poxviruses encode a broad range of proteins that interfere with host immune functions such as soluble versions of cytokine receptors. Soluble virus tumour necrosis factor receptors (vTNFRs) were described originally in myxoma and Shope fibroma viruses. Cowpox virus (CPV) encodes three vTNFRs (CrmB, CrmC and CrmD). The genes equivalent to CrmB and CrmC in vaccinia virus (VV) Copenhagen are mutated and are named B28R/C22L and A53R, respectively. CrmD was identified recently in CPV and ectromelia virus but the gene is absent in VV Copenhagen. We have tested for expression of soluble binding activity for human TNF in cultures infected with 18 orthopoxviruses and have found that TNFRs are mostly absent but are produced by VV strains Lister, USSR and Evans, by the CPV elephantpox and by camelpox virus. Interestingly, we also found TNFR activity on the surface of cells infected with VV Lister, USSR and Evans. Sequence analysis of the relevant regions in VV Lister identified an intact A53R gene and an inactive B28R gene. Expression of VV Lister A53R in baculovirus and VV Western Reserve demonstrated that gene A53R encodes an active soluble vTNFR of 22 kDa. Expression and characterization of recombinant vTNFRs from VV Lister (A53R) and CPV (CrmB and CrmC) showed a similar binding specificity, with each receptor binding TNF from man, mouse and rat, but not human lymphotoxin-alpha. Lastly, the VV Lister and CPV vTNFRs bind human TNF with high affinity and prevent the binding of TNF to cellular receptors.

Cytokine receptors encoded by poxviruses: a lesson in cytokine biology

Poxviruses encode soluble versions of cytokine receptors, which are secreted from the infected cell to block the activity of the cognate cytokine. These viruses offer a unique model system to study the contribution of cytokines to the host response against infection. As discussed here by Antonio Alcamí and Geoffrey Smith, characterization of poxvirus proteins that counteract the immune response may lead to the identification of novel cytokines or cytokine receptors, as well as novel strategies to modulate the inflammatory response.

Expression of Secreted Cytokine and Chemokine Inhibitors by Ectromelia Virus

ABSTRACT The production of secreted proteins that bind cytokines and block their activity has been well characterized as an immune evasion strategy of the orthopoxviruses vaccinia virus (VV) and cowpox virus (CPV). However, very limited information is available on the expression of similar cytokine inhibitors by ectromelia virus (EV), a virulent natural mouse pathogen that causes mousepox. We have characterized the expression and binding properties of three major secreted immunomodulatory activities in 12 EV strains and isolates. Eleven of the 12 EVs expressed a soluble, secreted 35-kDa viral chemokine binding protein with properties similar to those of homologous proteins from VV and CPV. All of the EVs expressed soluble, secreted receptors that bound to mouse, human, and rat tumor necrosis factor alpha. We also detected the expression of a soluble, secreted interleukin-1β (IL-1β) receptor (vIL-1βR) by all of the EVs. EV differed from VV and CPV in that binding of human 125I-IL-1β to the EV vIL-1βR could not be detected. Nevertheless, the EV vIL-1βR prevented the interaction of human and mouse IL-1β with cellular receptors. There are significant differences in amino acid sequence between the EV vIL-1βR and its VV and CPV homologs which may account for the results of the binding studies. The conservation of these activities in EV suggests evolutionary pressure to maintain them in a natural poxvirus infection. Mousepox represents a useful model for the study of poxvirus pathogenesis and immune evasion. These findings will facilitate future study of the role of EV immunomodulatory factors in the pathogenesis of mousepox.

Vaccinia Virus-Mediated Inhibition of Type I Interferon Responses Is a Multifactorial Process Involving the Soluble Type I Interferon Receptor B18 and Intracellular Components

ABSTRACT Poxviruses such as virulent vaccinia virus (VACV) strain Western Reserve encode a broad range of immune modulators that interfere with host responses to infection. Upon more than 570 in vitro passages in chicken embryo fibroblasts (CEF), chorioallantois VACV Ankara (CVA) accumulated mutations that resulted in highly attenuated modified vaccinia virus Ankara (MVA). MVA infection of mice and of dendritic cells (DC) induced significant type I interferon (IFN) responses, whereas infection with VACV alone or in combination with MVA did not. These results implied that VACV expressed an IFN inhibitor(s) that was functionally deleted in MVA. To further characterize the IFN inhibitor(s), infection experiments were carried out with CVA strains isolated after 152 (CVA152) and 386 CEF passages (CVA386). Interestingly, neither CVA152 nor CVA386 induced IFN-α, whereas the latter variant did induce IFN-β. This pattern suggested a consecutive loss of inhibitors during MVA attenuation. Similar to supernatants of VACV- and CVA152-infected DC cultures, recombinantly expressed soluble IFN decoy receptor B18, which is encoded in the VACV genome, inhibited MVA-induced IFN-α but not IFN-β. In the same direction, a B18R-deficient VACV variant triggered only IFN-α, confirming B18 as the soluble IFN-α inhibitor. Interestingly, VACV infection inhibited IFN responses induced by a multitude of different stimuli, including oligodeoxynucleotides containing CpG motifs, poly(I:C), and vesicular stomatitis virus. Collectively, the data presented show that VACV-mediated IFN inhibition is a multistep process involving secreted factors such as B18 plus intracellular components that cooperate to efficiently shut off systemic IFN-α and IFN-β responses.

Inhibition of Interferons by Ectromelia Virus

ABSTRACT Ectromelia virus (EV) is an orthopoxvirus (OPV) that causes mousepox, a severe disease of laboratory mice. Mousepox is a useful model of OPV infection because EV is likely to be a natural mouse pathogen, unlike its close relatives vaccinia virus (VV) and variola virus. Several studies have highlighted the importance of mouse interferons (IFNs) in resistance to and recovery from EV infection, but little is known of the anti-IFN strategies encoded by the virus itself. We have determined that 12 distinct strains and isolates of EV encode soluble, secreted receptors for IFN-γ (vIFN-γR) and IFN-α/β (vIFN-α/βR) that are homologous to those identified in other OPVs. We demonstrate for the first time that the EV vIFN-γR has the unique ability to inhibit the biological activity of mouse IFN-γ. The EV vIFN-α/βR was a potent inhibitor of human and mouse IFN-α and human IFN-β but, surprisingly, was unable to inhibit mouse IFN-β. The replication of all of the EVs included in our study and of cowpox virus was more resistant than VV to the antiviral effects induced in mouse L-929 cells by IFN-α/β and IFN-γ. Sequencing studies showed that this EV resistance is likely to be partly mediated by the double-stranded-RNA-binding protein encoded by an intact EV homolog of the VV E3L gene. The absence of a functional K3L gene, which encodes a viral eIF-2α homolog, in EV suggests that the virus encodes a novel mechanism to counteract the IFN response. These findings will facilitate future studies of the role of viral anti-IFN strategies in mousepox pathogenesis. Their significance in the light of earlier data on the role of IFNs in mousepox is discussed.