posted on 2007-04-11, 00:00authored byAdam Lucas, Liang Huang, Aravind Joshi, Ken A. Dill
Despite much study, biomolecule folding cooperativity is not well understood. There are
quantitative models for helix-coil transitions and for coil-to-globule transitions, but no accurate models yet
treat both chain collapse and secondary structure formation together. We develop here a dynamic
programming approach to statistical mechanical partition functions of foldamer chain molecules. We call it
the ascending levels model. We apply it to helix-coil and helix-bundle folding and cooperativity. For 14- to
50-mer Baldwin peptides, the model gives good predictions for the heat capacity and helicity versus
temperature and urea. The model also gives good fits for the denaturation of Oas's three-helix bundle B
domain of protein A (F13W*) and synthetic protein α3C by temperature and guanidine. The model predicts
the conformational distributions. It shows that these proteins fold with transitions that are two-state, although
the transitions in the Baldwin helices are nearly higher order. The model shows that the recently developed
three-helix bundle polypeptoids of Lee et al. fold anti-cooperatively, with a predicted value of ΔHvH/ΔHcal =
0.72. The model also predicts that two-helix bundles are unstable in proteins but stable in peptoids. Our
dynamic programming approach provides a general way to explore cooperativity in complex foldable
polymers.