BACKGROUND: Cowpox virus expresses the serpin CrmA (cytokine response modifier A) in order to avoid inflammatory and apoptotic responses of infected host cells. The targets of CrmA are members of the caspase family of proteases that either initiate the extrinsic pathway of apoptosis (caspases 8 and 10) or trigger activation of the pro-inflammatory cytokines interleukin-1beta and interleukin-18 (caspase 1). RESULTS: We have determined the structure of a cleaved form of CrmA to 2.26 A resolution. CrmA has the typical fold of a cleaved serpin, even though it lacks the N-terminal half of the A helix, the entire D helix, and a portion of the E helix that are present in all other known serpins. The reactive-site loop of CrmA was mutated to contain the optimal substrate recognition sequence for caspase 3; however, the mutation only marginally increased the ability of CrmA to inhibit caspase 3. Superposition of the reactive-site loop of alpha1-proteinase inhibitor on the cleaved CrmA structure provides a model for virgin CrmA that can be docked to caspase 1, but not to caspase 3. CONCLUSIONS: CrmA exemplifies viral economy, selective pressure having resulted in a 'minimal' serpin that lacks the regions not needed for structural integrity or inhibitory activity. The docking model provides an explanation for the selectivity of CrmA. Our demonstration that engineering optimal substrate recognition sequences into the CrmA reactive-site loop fails to generate a good caspase 3 inhibitor is consistent with the docking model.
BACKGROUND:Cowpox virus expresses the serpin CrmA (cytokine response modifier A) in order to avoid inflammatory and apoptotic responses of infected host cells. The targets of CrmA are members of the caspase family of proteases that either initiate the extrinsic pathway of apoptosis (caspases 8 and 10) or trigger activation of the pro-inflammatory cytokines interleukin-1beta and interleukin-18 (caspase 1). RESULTS: We have determined the structure of a cleaved form of CrmA to 2.26 A resolution. CrmA has the typical fold of a cleaved serpin, even though it lacks the N-terminal half of the A helix, the entire D helix, and a portion of the E helix that are present in all other known serpins. The reactive-site loop of CrmA was mutated to contain the optimal substrate recognition sequence for caspase 3; however, the mutation only marginally increased the ability of CrmA to inhibit caspase 3. Superposition of the reactive-site loop of alpha1-proteinase inhibitor on the cleaved CrmA structure provides a model for virgin CrmA that can be docked to caspase 1, but not to caspase 3. CONCLUSIONS:CrmA exemplifies viral economy, selective pressure having resulted in a 'minimal' serpin that lacks the regions not needed for structural integrity or inhibitory activity. The docking model provides an explanation for the selectivity of CrmA. Our demonstration that engineering optimal substrate recognition sequences into the CrmA reactive-site loop fails to generate a good caspase 3 inhibitor is consistent with the docking model.
Authors: Lisa D Tesch; Manikanahally P Raghavendra; Tina Bedsted-Faarvang; Peter G W Gettins; Steven T Olson Journal: Protein Sci Date: 2005-01-04 Impact factor: 6.725
Authors: Thomas H Roberts; Jorn Hejgaard; Neil F W Saunders; Ricardo Cavicchioli; Paul M G Curmi Journal: J Mol Evol Date: 2004-10 Impact factor: 2.395
Authors: Ciara A Ryan; Henning R Stennicke; Victor E Nava; Jennifer B Burch; J Marie Hardwick; Guy S Salvesen Journal: Biochem J Date: 2002-09-01 Impact factor: 3.857
Authors: Ruby H P Law; Qingwei Zhang; Sheena McGowan; Ashley M Buckle; Gary A Silverman; Wilson Wong; Carlos J Rosado; Chris G Langendorf; Rob N Pike; Philip I Bird; James C Whisstock Journal: Genome Biol Date: 2006-05-30 Impact factor: 13.583