Insight into the secondary structure of non-native proteins bound to a molecular chaperone alpha-crystallin. An isotope-edited infrared spectroscopic study

alpha-Crystallin, the major lens protein, acts as a molecular chaperone by preventing the aggregation of proteins damaged by heat and other stress conditions. To characterize the backbone conformation of protein folding intermediates that are recognized by the chaperone, we prepared the uniformly (13)C-labeled alphaA-crystallin. The labeling greatly reduced the overlapping between the conformation-sensitive amide I bands of alpha-crystallin and unlabeled substrate proteins. This procedure has allowed us to gain insight into the secondary structure of alpha-crystallin-bound species, an understanding which has previously been unattainable. Analysis of the infrared spectra of two substrate proteins (gamma- and beta(L)-crystallins) indicates that heat-destabilized conformers captured by alpha-crystallin are characterized by a high proportion of native-like secondary structure. In contrast to the chaperone-bound species, the same proteins subjected to heat treatment in the absence of alpha-crystallin preserve very little native secondary structure. These data show that alpha-crystallin specifically recognizes very early intermediates on the denaturation pathway of proteins. These aggregation-prone species are characterized by native-like secondary structure but compromised tertiary interactions. The experimental approach described in this study can be further applied to probe the backbone conformation of proteins bound to chaperones other than alpha-crystallin.