Effects of mutations on hydrogen exchange kinetics, structure, and sta
bility suggest that the slow exchange core is a key element in protein
folding. Single amino acid variants of bovine pancreatic trypsin inhi
bitor (BPTI) have been made with glycine or alanine replacement of res
idues Tyr 35, Gly 37, Asn 43, and Asn 44. The crystal structures of Y3
5G and N43G are reported [Housset, D., Kim, K.-S., Fuchs, J., & Woodwa
rd, C. (1991) J. Mol. Biol. 220,757-770; Danishefsky, A. T., Housset,
D., Kim, K.-S., Tao, F., Fuchs, J., Woodward, C., & Wlodawer, A. (I 99
3) Protein Sci. 2, 577-587; Kim, K.-S., Tao, F., Fuchs, J. A., Danishe
fsky, A. T., Housset, D., Wlodawer, A., & Woodward, C. (1993a) Protein
Sci. 2, 588-596]. NMR chemical shifts indicate few changes from the w
ild type (WT) in G37A and N44G. Stabilities of the four mutants were m
easured by calorimetry and by hydrogen exchange. Values of DELTADELTAG
(WT-->mut), the difference in DELTAG of folding/unfolding between the
wild type and mutant, estimated by both methods are in good agreement
and are in the range 4.7-6.0 kcal/mol. There is no general correlation
between stability and hydrogen exchange rates at pH 3.5 and 30-degree
s-C. Exchange occurs by two parallel pathways, one involving small non
cooperative fluctuations of the native state, and the other involving
cooperative, global unfolding. In the mutant proteins, the rates for e
xchange by the unfolding mechanism are accelerated by a factor corresp
onding to the increase in the unfolding/folding equilibrium constant.
Rates for exchange by the native-state mechanism either are not affect
ed or are accelerated to varying degrees. NH protons with accelerated
exchange rates are primarily in the vicinity of the replacement, which
in these mutants corresponds to the flexible loops. The overall effec
ts of destabilizing mutations on hydrogen exchange are similar to thos
e resulting from the addition of 8 M urea (Kim & Woodward, 1993). Moti
onal domains defined by exchange rates are the slow exchange core, fle
xible loops, and secondary structure not in the core. In BPTI, the slo
w exchange core is the folding core, peptides corresponding to the slo
w exchange core have native-like structure, and the presence or absenc
e of local structural relaxation around mutation sites reflects the in
trinsic local flexibility measured by hydrogen exchange. We propose th
at this is general for proteins, that the protein segments in the slow
exchange core determine the basic fold, and that in compact nonnative
states the collapsed region corresponds to the slow exchange core.