Entropic benefit of a cross‐link in protein association

We introduce a method to estimate the loss of configurational entropy upon insertion of a cross‐link to a dimeric system. First, a clear distinction is established between the loss of entropy upon tethering and binding, two quantities that are often considered to be equivalent. By comparing the probability distribution of the center‐to‐center distances for untethered and cross‐linked versions, we are able to calculate the loss of translational entropy upon cross‐linking. The distribution function for the untethered helices is calculated from the probability that a given helix is closer to its partner than to all other helices, the “Nearest Neighbor” method. This method requires no assumptions about the nature of the solvent, and hence resolves difficulties normally associated with calculations for systems in liquids. Analysis of the restriction of angular freedom upon tethering indicates that the loss of rotational entropy is negligible. The method is applied in the context of the folding of a ten turn helical coiled coil with the tether modeled as a Gaussian chain or a flexible amino acid chain. After correcting for loop closure entropy in the docked state, we estimate the introduction of a six‐residue tether in the coiled coil results in an effective concentration of the chain to be about 4 or 100 mM, depending upon whether the helices are denatured or pre‐folded prior to their association. Thus, tethering results in significant stabilization for systems with millimolar or stronger dissociation constants. Proteins 2002;48:341–351. © 2002 Wiley‐Liss, Inc.