Apoptosis is a highly regulated process that is crucial for normal development and homeostasis of multicellular organisms(1,2). The p35 protein from baculoviruses effectively prevents apoptosis by its broad-spectrum caspase inhibition(3-7). Here we report the crystal structure of p35 in complex with human caspase-8 at 3.0 Angstrom resolution, and biochemical and mutagenesis studies based on the structural information. The structure reveals that the caspase is inhibited in the active site through a covalent thioester linkage to p35, which we confirmed by gel electrophoresis, hydroxylamine treatment and mass spectrometry experiments. The p35 protein undergoes dramatic conformational changes on cleavage by the caspase. The repositioning of the amino terminus of p35 into the active site of the caspase eliminates solvent accessibility of the catalytic dyad. This may be crucial for preventing hydrolysis of the thioester intermediate, which is supported by the abrogation of inhibitory activity through mutations at the N terminus of p35. The p35 protein also makes conserved contacts with the caspase outside the active-site region, providing the molecular basis for the broad-spectrum inhibitory activity of this protein. We demonstrate a new molecular mechanism of caspase inhibition, as well as protease inhibition in general.

Covalent inhibition revealed by the crystal structure of the caspase-8/p35 complex

Cirilli M;
2001

Abstract

Apoptosis is a highly regulated process that is crucial for normal development and homeostasis of multicellular organisms(1,2). The p35 protein from baculoviruses effectively prevents apoptosis by its broad-spectrum caspase inhibition(3-7). Here we report the crystal structure of p35 in complex with human caspase-8 at 3.0 Angstrom resolution, and biochemical and mutagenesis studies based on the structural information. The structure reveals that the caspase is inhibited in the active site through a covalent thioester linkage to p35, which we confirmed by gel electrophoresis, hydroxylamine treatment and mass spectrometry experiments. The p35 protein undergoes dramatic conformational changes on cleavage by the caspase. The repositioning of the amino terminus of p35 into the active site of the caspase eliminates solvent accessibility of the catalytic dyad. This may be crucial for preventing hydrolysis of the thioester intermediate, which is supported by the abrogation of inhibitory activity through mutations at the N terminus of p35. The p35 protein also makes conserved contacts with the caspase outside the active-site region, providing the molecular basis for the broad-spectrum inhibitory activity of this protein. We demonstrate a new molecular mechanism of caspase inhibition, as well as protease inhibition in general.
2001
Structural Biology
Protein Crystallography
Caspase inhibition
Protein complex
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/353774
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