Joanne Macen

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.

Inhibitory specificity of the anti-inflammatory myxoma virus serpin, SERP-1.

SERP-1 is a myxoma virus-encoded serpin, secreted from infected cells, that is required for virulence and has anti-inflammatory activity. We report that purified recombinant SERP-1 forms SDS-stable complexes with urokinase-type plasminogen activator (uPA), tissue-type plasminogen activator (tPA), plasmin, thrombin, and factor Xa. N-terminal sequencing confirmed Arg319-Asn320 as the site of reaction. Mutation of these residues to Ala-Ala abolished inhibitory activity but had no effect on the specific cleavage at Thr315-Leu316 seen with elastase and with cathepsin G. Kinetic analysis of the reactions with uPA, tPA, plasmin, thrombin, Xa, and C1s showed second-order rate constants to vary over 3 logs, from k inh = 3 × 105 m −1 s−1 with thrombin to ∼600m −1 s−1 with C1s, while steady-state inhibition constants ranged from K I = 10 pm with thrombin to ∼100 nm with C1s. Stoichiometries of inhibition varied between SI = 1.4 ± 0.1 for uPA to SI = 13 ± 3 for thrombin. Analysis of the variations in inhibition kinetics shows that when serpins act at low concentrations, comparable with the target protease or with K I (as appears likely for SERP-1in vivo), inhibitory specificity becomes less dominated byk inh and is increasingly dependent on partitioning within the branched reaction mechanism and on the lifetime of the inhibited complex.