Hetero-α-helical,two-chain coiled-coils. Clam–worm hybrid paramyosins

The specificity of the interaction between the α-helices in two-chain coiled-coils is investigated by studying the formation of hybrid molecules in which one α-helix is a clam paramyosin chain and the other a worm paramyosin chain. Hybrids are formed by mixing, denaturation, and subsequent renaturation. Comparison is made with a blank solution in which renaturation precedes mixing, thus precluding hybridization. Hybrids are detected by a ruse based on the presence of free sulfhydryl functions on calm chains. This allows molecules comprising two clam chains to be covalently crosslinked by oxidation with 5,5′-dithiobis(2-nitrobenzoate). Worm paramyosin chains have no sulfhydryl, so molecules comprising two worm chains or hybrid molecules comprising one chain of each type cannot crosslink. When run on sodium dodecyl sulfate polyacrylamide gel electrophoresis, therefore, the protein separates into two well-resolved regions, one containing one-chain species and the other two-chain species. When the gels are scanned and quantitated, the hybrids show up as an increase in the fraction of material in the one-chain band compared with the fraction in the blank solution. When renaturation is direct, we find that the fraction of renaturated molecules that are hybrids varies from ～10% at 5°C to ～5% at 25°C. These are judged to be nonequilibrium (quenched) values. When renaturation is by slow annealing, the equilibrium fraction hybrids are ～4% and show a modest, but measurable, increase with increasing temperature. These data allow calculation of the equilibrium constant K_h and standard free energy for the hybridization reaction: (1/2)CC + (½)WW = CW, in which C(W) stands for an α-helical clam (worm) polypeptide chain. The temperature dependence gives the standard enthalpy and entropy of the reaction. We find ΔH ? 1800 cal mol^?1 and ΔH ? 1.4 cal mol^?1 K^?1, using molarity concentration units and the infinitely dilute solution in NaCl/phosphate buffer as reference state. The possible molecular significance of these values is discussed, and it is concluded that the observed standard entropy arises essentially entirely from the rotational dissymmetry of the hybrids.