Effect of catenation on protein folding stability.

Building on previous studies of the effects of covalent linking and backbone cyclization on protein folding stability, a theory is developed for the stabilization effect of catenating a dimeric protein. Relative to covalent linking, catenation is up to 1000-fold more powerful in stabilizing the folded structure. This dramatic stabilization derives from the dual effects of backbone cyclization and constrained relative motion between the subunits afforded by the catenane topology.

Comparison of calculation and experiment implicates significant electrostatic contributions to the binding stability of barnase and barstar.

The contributions of electrostatic interactions to the binding stability of barnase and barstar were studied by the Poisson-Boltzmann model with three different protocols: a), the dielectric boundary specified as the van der Waals (vdW) surface of the protein along with a protein dielectric constant (epsilon (p)) of 4; b), the dielectric boundary specified as the molecular (i.e., solvent-exclusion (SE)) surface along with epsilon (p) = 4; and c), "SE + epsilon (p) = 20.

Quantitative account of the enhanced affinity of two linked scFvs specific for different epitopes on the same antigen.

Protein and other antigens typically have a number of different epitopes. This presents an opportunity for designing high-affinity antibodies by connecting via a flexible peptide linker two antibody fragments recognizing non-overlapping epitopes on the same antigen. The same strategy was employed in natural and designed DNA-binding proteins.

Electrostatic contributions to the stability of a thermophilic cold shock protein.

The thermophilic Bacillus caldolyticus cold shock protein (Bc-Csp) differs from the mesophilic Bacillus subtilis cold shock protein B (Bs-CspB) in 11 of the 66 residues. Stability measurements of Schmid and co-workers have implicated contributions of electrostatic interactions to the thermostability. To further elucidate the physical basis of the difference in stability, previously developed theoretical methods that treat electrostatic effects in both the folded and the unfolded states were used in this paper to study the effects of mutations, ionic strength, and temperature.

Direct test of the Gaussian-chain model for treating residual charge-charge interactions in the unfolded state of proteins.

The Gaussian-chain model for treating residual charge-charge interactions was critically tested by recent experimental pK(a) results for individual Asp, Glu, and His residues in the unfolded drkN SH3 domain. Predicted pK(a)'s were in good agreement with experiment. The clustering of Asp and Glu residues along the sequence was suggested to limit pK(a) shifts and contribute to the folding stability by destabilizing the unfolded state.

Toward the physical basis of thermophilic proteins: linking of enriched polar interactions and reduced heat capacity of unfolding.

The enrichment of salt bridges and hydrogen bonding in thermophilic proteins has long been recognized. Another tendency, featuring lower heat capacity of unfolding (DeltaC(p)) than found in mesophilic proteins, is emerging from the recent literature. Here we present a simple electrostatic model to illustrate that formation of a salt-bridge or hydrogen-bonding network around an ionized group in the folded state leads to increased folding stability and decreased DeltaC(p).

Residual charge interactions in unfolded staphylococcal nuclease can be explained by the Gaussian-chain model.

The discrepancy of the pH dependence of the unfolding free energy for staphylococcal nuclease from what is expected from an idealized model for the unfolded state is accounted for by the recently developed Gaussian-chain model. Residual electrostatic effects in the unfolded state are attributed to nonspecific interactions dominated by charges close along the sequence. The dominance of nonspecific local interactions appears to be supported by some experimental evidence.

Electrostatic contributions to T4 lysozyme stability: solvent-exposed charges versus semi-buried salt bridges.

We carried our Poisson-Boltzmann (PB) calculations for the effects of charge reversal at five exposed sites (K16E, R119E, K135E, K147E, and R154E) and charge neutralization and proton titration of the H31-D70 semi-buried salt bridge on the stability of T4 lysozyme. Instead of the widely used solvent-exclusion (SE) surface, we used the van der Waals (vdW) surface as the boundary between the protein and solvent dielectrics (a protocol established in our earlier study on charge mutations in barnase). By including residual charge-charge interactions in the unfolded state, the five charge reversal mutations were found to have DeltaDeltaG(unfold) from -1.

Residual electrostatic effects in the unfolded state of the N-terminal domain of L9 can be attributed to nonspecific nonlocal charge-charge interactions.

Residual electrostatic interactions in the unfolded state of the N-terminal domain of L9 (NTL9) were found by Kuhlman et al. [(1999) Biochemistry 38, 4896-4903]. These residual interactions are analyzed here by the Gaussian-chain model [Zhou, H.

A Gaussian-chain model for treating residual charge-charge interactions in the unfolded state of proteins.

Characterization of the unfolded state is essential for understanding the protein folding problem. In the unfolded state, a protein molecule samples vastly different conformations. Here I present a simple theoretical method for treating residual charge-charge interactions in the unfolded state.