| Effect of finite size on cooperativity and rates of protein folding (2006) | |||||||||
Abstract | |||||||||
| We analyze the dependence of cooperativity of the thermal denaturation transition and folding rates of globular proteins on the number of amino acid residues, $N$, using lattice models with side chains,off-lattice Go models and the available experimental data. A dimensionless measure of cooperativity, $\Omega_c$ ($0 < \Omega_c < \infty$), scales as $\Omega_c \sim N^{\zeta}$. The results of simulations and the analysis of experimental data further confirm the earlier prediction that $\zeta$ is universal with $\zeta = 1 +\gamma$, where exponent $\gamma$ characterizes the susceptibility of a self-avoiding walk. This finding suggests that the structural characteristics in the denaturated state are manifested in the folding cooperativity at the transition temperature. The folding rates $k_F$ for the Go models and a dataset of 69 proteins can be fit using $k_F = k_F^0 \exp(-cN^\beta)$. Both $\beta = 1/2$ and 2/3 provide a good fit of the data. We find that $k_F = k_F^0 \exp(-cN^{{1/2}})$, with the average (over the dataset of proteins) $k_F^0 \approx (0.2\mu s)^{-1}$ and $c \approx 1.1$, can be used to estimate folding rates to within an order of magnitude in most cases. The minimal models give identical $N$ dependence with $c \approx 1$. The prefactor for off-lattice Go models is nearly four orders of magnitude larger than the experimental value.. Comment: 17 pages, 3 figures, 2 tables | |||||||||
Publication details | |||||||||
| |||||||||