Kinetic study of folding and misfolding of diacylglycerol kinase in model membranes.

Despite the relevance of membrane protein misfolding to a number of common diseases, our understanding of the folding and misfolding of membrane proteins lags well behind soluble proteins. Here, the overall kinetics of membrane insertion and folding of the homotrimeric integral membrane protein diacylglycerol kinase (DAGK) is addressed. DAGK was purified into lipid/detergent-free urea and guanidinium solutions and subjected to general structural characterization. In urea, the enzyme was observed to be monomeric but maintained considerable tertiary structure. In guanidinium, it was also monomeric but exhibited much less tertiary structure. Aliquots of these DAGK stock solutions were diluted 200-fold into lipid vesicles or into detergent/lipid mixed micelles, and the rates and efficiencies of folding/insertion were monitored. Reactions were also carried out in which micellar DAGK solutions were diluted into vesicular solutions. Productive insertion of DAGK from denaturant solutions into mixed micelles occurred much more rapidly than into lipid vesicles, suggesting that bilayer transversal represents the rate-limiting step for DAGK assembly in vesicles. The efficiency of productive folding/insertion into vesicles was highest in reactions initiated with micellar DAGK stock solutions (where DAGK maintains a nativelike fold and oligomeric state) and lowest in reactions starting with guanidinium stocks (where DAGK is an unfolded monomer). Moreover, the final ratio of irreversibly misfolded DAGK to reversibly misfolded enzyme was highest following reactions initiated with guanidinium stock solutions and lowest when micellar stocks were used. Finally, it was also observed that very low concentrations of detergents were able to both enhance the bilayer insertion rate and suppress misfolding.

Reconstitutive refolding of diacylglycerol kinase, an integral membrane protein.

While the formation of kinetically trapped misfolded structural states by membrane proteins is related to a number of diseases, relatively few studies of misfolded membrane proteins in their purified state have been carried out and few methods for refolding such proteins have been reported. In this paper, misfolding of the trimeric integral membrane protein diacylglycerol kinase (DAGK) is documented and a method for refolding the protein is presented; 65 single-cysteine mutants of DAGK were examined. A majority were found to have lower-than-expected activities when purified into micellar solutions, with additional losses in activity often being observed following membrane reconstitution. A variety of evidence indicates that the low activities observed for most of these mutants results from kinetically based misfolding of the protein, with misfolding often being manifested by the formation of aberrant oligomeric states. A method referred to as "reconstitutive refolding" for correcting misfolded DAGK is presented. This method is based upon reconstituting DAGK into multilamellar POPC vesicles by dialyzing the detergent dodecylphosphocholine out of mixed micellar mixtures. For 55 of the 65 mutants tested, there was a gain of DAGK activity during reconstitutive refolding. In 33 of these cases, the gain in activity was greater than 2-fold. The refolding results for cysteine replacement mutants at DAGK sites known to be highly conserved provide teleological insight into whether sites are conserved, because they are critical for catalysis, for maintenance of the proper folding pathway, or for some other reason.