Differential lipid binding of truncation mutants of Galleria mellonella apolipophorin III

Apolipophorin III (apoLp-III) is a prototype exchangeable apolipoprotein that is amenable to structure-function studies. The protein folds as a bundle of five amphipathic alpha-helices and undergoes a dramatic conformational change upon lipid binding. Recently, we have shown that a truncation mutant of Galleria mellonella apoLp-III comprising helices 1-3 is stable in solution and able to bind to lipid surfaces Dettloff, M., Weers, P. M. M., Niere, M., Kay, C. M., Ryan, R. O., and Wiesner, A. (2001) Biochemistry 40, 3150-3157]. To investigate the role of the C-terminal helices in apoLp-III structure and function, two additional 3-helix mutants were designed: a core fragment comprising helix (H) 2-4, and a C-terminal fragment (H3-5). Each truncation mutant retained the ability to associate spontaneously with dimyristoylphosphatidylcholine (DMPC) vesicles, transforming them into discoidal complexes. The rate of apolipoprotein-dependent DMPC vesicle transformation decreased in the order H1-3 > H2-4 > H3-5. Truncation of two helices led to a significant decrease in alpha-helical content in buffer in each case, from 86% (wild-type) to 50% (H1-3), 28% (H2-4), and 24% alpha-helical content (H3-5). On the other hand, trifluoroethanol or complexation with DMPC induced the truncation mutants to adopt a high alpha-helical structure similar to that of wild-type protein (84-100% alpha-helical structure). ApoLp-III(H1-3) and apoLp-III(H2-4), but not apoLp-III(H3-5), were able to prevent phospholipase-C-induced low density lipoprotein aggregation, indicating that interaction of the C-terminal fragment with spherical lipoprotein surfaces was impaired. As lipoprotein binding is significantly affected and DMPC transformation rates are relatively slow upon removal of N-terminal helices, the data indicate that structural elements necessary for lipid interaction reside in the N-terminal part of the protein.