The clostridial collagenases G and H are multidomain proteins. For collagen digestion, the domain arrangement is likely to play an important role in collagen binding and hydrolysis. In this study, the full-length collagenase H protein from Clostridium histolyticum was expressed in Escherichia coli and purified. The N-terminal amino acid of the purified protein was Ala31. The expressed protein showed enzymatic activity against azocoll as a substrate. To investigate the role of Ca~(2+) in providing structural stability to the full-length collagenase H, biophysical measurements were conducted using the recombinant protein. Size exclusion chromatography revealed that the Ca~(2+) chelation by EGTA induced interdomain conformational changes. Dynamic light scattering measurements showed an increase in the percent polydispersity as the Ca~(2+) was chelated, suggesting an increase in protein flexibility. In addition to these conformational changes, differential scanning fluorimetry measurements revealed that the thermostability was decreased by Ca~(2+) chelation, in comparison with the thermal melting point ( T_(m) ). The melting point changed from 54 to 49°C by the Ca~(2+) chelation, and it was restored to 54°C by the addition of excess Ca~(2+). These results indicated that the interdomain flexibility and the domain arrangement of full-length collagenase H are reversibly regulated by Ca~(2+).
展开▼
