Structural analysis of phospholipase A2 from functional perspective. 2. Characterization of a molten globule-like state induced by site-specific mutagenesis.

Department of Chemistry, Campus Chemical Instrument Center, The Ohio State University, Columbus 43210, USA.

Previous NMR studies have shown that many phospholipase A2 (PLA2, from bovine pancreas, overexpressed in Escherichia coli) mutants display some properties reminiscent of a molten globule state. Further NMR analyses for some of the mutants indicated that formation of the "molten globule-like state" is a pH-dependent phenomenon. The mutants I9Y and I9F showed perturbed NMR properties throughout the pH range studied, while the mutants H48A and C44A/C105A displayed native-like spectra at neutral pH but molten globule-like ones under acidic conditions, with a "transition pH" around 4. On the other hand, wild-type PLA2 exhibits exceptional pH stability and turns into a similar molten globule-like state only under highly acidic conditions such as 1 M HCl. The H48A mutant was used to rigorously establish the property of the molten globule-like state of PLA2 mutants. The results of far-UV CD, near-UV CD, and ANS-binding fluorescence suggest that H48A retains native-like secondary structures but loses tertiary structure during the conformational transition. However, the tertiary structure is not completely lost, as evidenced by the retention of some long-range NOEs in two-dimensional NOESY spectra. The conclusion was further substantiated by three-dimensional NOESY-HSQC experiments on a 15N-labeled H48A sample. It was revealed that the molten globule-like state at mildly acidic pH retained some rigid tertiary structure, which consisted of partial alpha-helix II (Y52-L58), alpha-helix III (D59-V63), beta-wing (S74-S85) and partial alpha-helix IV (A90-N97). These residual tertiary structures grouped in half of the protein could be attributed to stabilization by some of the disulfide bonds. The extreme sensitivity of the PLA2 structure to site-directed mutagenesis is unprecedented. It is interesting to note that most of the functional residues (the active site, the hydrophobic channel, the interfacial binding site, and the calcium-binding loop) are located in the remainder of the protein, which is well disrupted in tertiary interactions.

PMID: 10074344 [PubMed - indexed for MEDLINE]