Abstract
Crystal structures of hen egg-white lysozyme (HEWL) determined under pressures ranging from ambient pressure to 950 MPa are presented. From 0.1 to 710 MPa, the molecular and internal cavity volumes are monotonically compressed. However, from 710 to 890 MPa the internal cavity volume remains almost constant. Moreover, as the pressure increases to 950 MPa, the tetragonal crystal of HEWL undergoes a phase transition from P43212 to P43. Under high pressure, the crystal structure of the enzyme undergoes several local and global changes accompanied by changes in hydration structure. For example, water molecules penetrate into an internal cavity neighbouring the active site and induce an alternate conformation of one of the catalytic residues, Glu35. These phenomena have not been detected by conventional X-ray crystal structure analysis and might play an important role in the catalytic activity of HEWL.
Highlights
High pressure induces structural changes in proteins, such as the dissociation of oligomers, conformational changes and denaturation
Our group developed a HPPX environment at the Photon Factory, Japan (Chavas et al, 2013), with which we studied the pressure-induced structural changes of 3-isopropylmalate dehydrogenase (IPMDH) up to 650 MPa (Nagae et al, 2012)
The results for superoxide dismutase (SOD) and IPMDH show that the pressure-induced structural changes observed by HPPX are directly related to protein activity or function
Summary
High pressure induces structural changes in proteins, such as the dissociation of oligomers, conformational changes and denaturation. For this reason, high-pressure structural analysis has been widely used to study important characteristics of proteins such as their stability, folding and aggregation (see, for example, Balny, 2006). In the development of high-pressure X-ray protein crystallography (HPPX), the introduction of the diamond anvil cell (DAC) was a key step (Katrusiak & Dauter, 1996; Fourme et al, 2001; Girard et al, 2007). The results for SOD and IPMDH show that the pressure-induced structural changes observed by HPPX are directly related to protein activity or function
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