V. Villegas et al., STRUCTURE OF THE TRANSITION-STATE IN THE FOLDING PROCESS OF HUMAN PROCARBOXYPEPTIDASE A2 ACTIVATION DOMAIN, Journal of Molecular Biology, 283(5), 1998, pp. 1027-1036
The transition state for the folding pathway of the activation domain
of human procarboxypeptidase A2 (ADA2h) has been analyzed by the prote
in engineering approach. Recombinant ADA2h is an 81-residue globular d
omain with no disulfide bridges or cis-prolyl bonds, which follows a t
wo-state folding transition. Its native fold is arranged in two alpha-
helices packing against a four-stranded beta-sheet. Application of the
protein engineering analysis for 20 single-point mutants spread throu
ghout the whole sequence indicates that the transition state for this
molecule is quite compact, possessing some secondary structure and a h
ydrophobic core in the process of being consolidated. The core (foldin
g nucleus) is made by the packing of alpha-helix 2 and the two central
beta-strands. The other two strands, at the edges of the beta-sheet,
and alpha-helix 1 seem to be completely unfolded. These results, toget
her with previous analysis of ADA2h with either of its two alpha-helic
es stabilized through improved local interactions, suggest that alpha-
helix 1 does not contribute to the folding nucleus, even though it is
partially folded in the denatured state under native conditions. On th
e other hand, alpha-helix 2 folds partly in the transition state and i
s part of the folding nucleus. It is suggested that a good strategy to
improve folding speed in proteins would be to stabilize the helices t
hat are not folded in the denatured state but are partly present in th
e transition state. Comparison with other proteins shows that there is
no clear relationship between fold and/or size with folding speed and
level of structure in the transition state of proteins. (C) 1998 Acad
emic Press.