Myxoma Virus M083 Is a Virulence Factor Which Mediates Systemic Dissemination.

Poxviruses are large, DNA viruses whose protein capsid is surrounded by one or more lipid envelopes. Embedded into these lipid envelopes are three conserved viral proteins which are thought to mediate binding of virions to target cells. While the function of these proteins has been studied in vitro, their specific roles during the pathogenesis of poxviral disease remain largely unclear. Here we present data demonstrating that the putative chondroitin binding protein M083 from the leporipoxvirus myxoma virus is a significant virulence factor during infection of susceptible Oryctolagus rabbits. Removal of M083 results in a reduced capacity of virus to spread beyond the regional lymph nodes and completely eliminates infection-mediated mortality. In vitro, removal of M083 results in only minor intracellular replication defects but causes a significant reduction in the ability of myxoma virus to spread from infected epithelial cells onto primary lymphocytes. We hypothesize that the physiological role of M083 is therefore to mediate the spread of myxoma virus onto rabbit lymphocytes, allowing these cells to disseminate virus throughout infected rabbits.IMPORTANCE Poxviruses represent both a class of human pathogens and potential therapeutic agents for the treatment of human malignancy. Understanding the basic biology of these agents is therefore significant to human health in a variety of ways. While the mechanisms mediating poxviral binding have been well studied in vitro, how these mechanisms impact poxviral pathogenesis in vivo remains unclear. The current study advances our understanding of how poxviral binding impacts viral pathogenesis by demonstrating that the putative chondroitin binding protein M083 plays a critical role during the pathogenesis of myxoma virus in susceptible Oryctolagus rabbits by impacting viral dissemination through changes in the transfer of virions onto primary splenocytes.

Defining the anti-inflammatory activity of a potent myxomaviral chemokine modulating protein, M-T7, through site directed mutagenesis.

Viral chemokine modulating proteins provide new and extensive sources for therapeutics. Purified M-T7, a poxvirus-derived secreted immunomodulatory protein, reduces mononuclear cell invasion and atheroma in rodent models of angioplasty injury as well as aortic and renal transplant, improving renal allograft survival. M-T7 is a rabbit species-specific interferon gamma receptor (IFNγR) homolog, but also inhibits chemokine/glycosaminoglycan (GAG) interactions for C, CC and CXC chemokines, with cross-species specific inhibitory activity. M-T7 anti-atheroma activity is blunted in GAG deficient mouse aortic transplants, but not in CC chemokine receptor deficient transplants, supporting M-T7 interference in chemokine/GAG interactions as the basis of the atheroma-inhibitory activity. We have assessed point mutants of M-T7 both in vivo in a mouse angioplasty model and in vitro in tissue culture and binding assays, in order to better define the primary mechanism of anti-atheroma activity. Of these M-T7 mutants, the R(171)E and E(209)I M-T7 mutants lost inhibitory activity for plaque growth in hyperlipidemic ApoE(-/-) mice after angioplasty injury and R(171)E, moreover, greatly exacerbated plaque growth and inflammation. F(137)D retained some inhibitory activity for plaque growth. In contrast, for cell migration assays, M-T7-His6X, F(137)D, R(171)E, and E(209)I all inhibited CC chemokine (RANTES) mediated cell migration. For the ligand binding assays, R(171)E and E(209)I had significantly reduced binding to RANTES and IFNγ, whereas F(137)D retained wild-type binding activity. Heparin treatment further reduced RANTES binding of all three M-T7 mutants. In summary, point mutations of M-T7, R(171)E and E(209)I, exhibited reduced anti-inflammatory properties in vivo after mouse angioplasty with a loss of in vitro binding to RANTES and IFNγ, indicating these point mutations partially disrupt M-T7 ligand-binding activities. Unexpectedly, the M-T7 mutants all retained inhibitory activity for human monocyte THP-1 cell migration ex vivo, suggesting additional inhibitory properties against human monocyte THP-1 cells that are independent of chemokine inhibition.