Abstract
To test the roles of motif and amino acid sequence in the folding mechanisms of TIM barrel proteins, hydrogen-deuterium exchange was used to explore the structure of the stable folding intermediates for the of indole-3-glycerol phosphate synthase from Sulfolobus solfataricus (sIGPS). Previous studies of the urea denaturation of sIGPS revealed the presence of an intermediate that is highly populated at ∼4.5 M urea and contains ∼50% of the secondary structure of the native (N) state. Kinetic studies showed that this apparent equilibrium intermediate is actually comprised of two thermodynamically distinct species, I a and I b. To probe the location of the secondary structure in this pair of stable on-pathway intermediates, the equilibrium unfolding process of sIGPS was monitored by hydrogen-deuterium exchange mass spectrometry. The intact protein and pepsin-digested fragments were studied at various concentrations of urea by electrospray and matrix-assisted laser desorption ionization time-of-flight mass spectrometry, respectively. Intact sIGPS strongly protects at least 54 amide protons from hydrogen-deuterium exchange in the intermediate states, demonstrating the presence of stable folded cores. When the protection patterns and the exchange mechanisms for the peptides are considered with the proposed folding mechanism, the results can be interpreted to define the structural boundaries of I a and I b. Comparison of these results with previous hydrogen-deuterium exchange studies on another TIM barrel protein of low sequence identify, α-tryptophan synthase (αTS), indicates that the thermodynamic states corresponding to the folding intermediates are better conserved than their structures. Although the TIM barrel motif appears to define the basic features of the folding free energy surface, the structures of the partially folded states that appear during the folding reaction depend on the amino acid sequence. Markedly, the good correlation between the hydrogen-deuterium exchange patterns of sIGPS and αTS with the locations of hydrophobic clusters defined by isoleucine, leucine, and valine residues suggests that branch aliphatic side-chains play a critical role in defining the structures of the equilibrium intermediates.
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