Abstract
The prokaryotic molecular chaperone GroE is increasingly expressed under heat shock conditions. GroE protects cells by preventing the irreversible aggregation of thermally unfolding proteins. Here, the interaction of GroE with thermally unfolding citrate synthase (CS) was dissected into several steps that occur before irreversible aggregation, and the conformational states of the unfolding protein recognized by GroEL were determined. The kinetic analysis of CS unfolding revealed the formation of inactive dimeric and monomeric intermediates. GroEL binds both intermediates without affecting the unfolding pathway. Furthermore, the dimeric intermediates are not protected against dissociation in the presence of GroEL. Monomeric CS is stably associated with GroEL, thus preventing further irreversible unfolding steps and subsequent aggregation. During refolding, monomeric CS is encapsulated inside the cavity of GroEL. GroES complexes. Taken together our results suggest that for protection of cells against heat stress both the ability of GroEL to interact with a large variety of nonnative conformations of proteins and the active, GroES-dependent refolding of highly unfolded species are important.
Highlights
Sive conditions the co-chaperone GroES is essential for assisted folding (13)
GroEL Binds Thermal Unfolding Intermediates of citrate synthase (CS) without Influencing the Inactivation Kinetics—Mitochondrial CS is a dimer consisting of two identical 49-kDa subunits
We chose this substrate to investigate the influence of GroE on protein unfolding under heat shock conditions because its thermal unfolding has been used before to analyze the function of other chaperones (25, 26, 39, 40)
Summary
Sive conditions the co-chaperone GroES is essential for assisted folding (13). It is still not clear how GroE promotes the folding of polypeptides under conditions in which off-pathway reactions are preferred. Reactivation is possible by changing the folding environment to permissive conditions in the presence of GroES and ATP (21–24) These studies demonstrate the basic properties of GroE under heat shock conditions, little is known about the interaction of GroE with thermally unfolding, structured proteins. Mitochondrial CS from pig heart is a dimeric protein composed of two identical subunits with a molecular mass of 49 kDa each It catalyzes the first reaction in the citric acid cycle, the condensation of oxaloacetic acid and acetyl-CoA to citric acid. Addition of the substrates oxaloacetic acid and acetyl-CoA stabilize the enzyme (30, 31), shifting the midpoint of the thermal unfolding transition to 66.5 °C (29) This stabilization is due to huge conformational changes induced by substrate binding (28, 32, 33). These intermediates dissociate into monomers, which are stably associated with GroEL and held in a reactivatable state at elevated temperatures
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