.alpha.-Helix to random-coil transition of two-chain, coiled coils: experiments on the thermal denaturation of doubly crosslinked dimeric .beta.-tropomyosin

Coiled coils possess a quaternary structure comprised of the side-by-side arrangement of ␣-helices. Due their inherent structural simplicity, they are ideal model systems for both theoretical and experimental studies. Among the coiled coils are the leucine zippers, which play an important role in the activation of DNA transcription. In contrast to the large amount of available experimental data, an overview of which is presented, there are very few theoretical studies. To address this need, the status of existing theoretical approaches to predict coiled coil quaternary structure is described. Furthermore, to treat the conformational equilibria inherent in these systems, an extension of entropy sampling Monte Carlo simulations is developed that can treat multimers. Here, the approach is applied to GCN4 leucine zippers in the context of a reduced protein model. Not only is the native conformation successfully predicted, but the model also reproduces the experimentally observed helix content in the denatured state and the observed two-state thermodynamic behavior. Such two-state behavior arises from the dissociation of highly helical dimeric chains to form monomers of low, isolated chain helix content.

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De novo predictions of the quaternary structure of leucine zippers and other coiled coils

Skolnick

Koliński

Mohanty

1999

Int. J. Quant. Chem.

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α‐Helix‐to‐random‐coil transitions of two‐chain coiled coils: Experiments on the thermal denaturation of ββ tropomyosin cross‐linked selectively at C‐190

et al. 1988

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SynopsisA method is described for preparation of a species of 88 tropomyosin that is sulfhydryl-blocked at C36 and disulfide-cross-linked at C190. Five steps are involved: (1) Rabbit skeletal muscle tropomywin, comprising aa and a8 species, is oxidized with ferricyanide, &sulfide-cross-linking both species at C190. (2) The product is treated with iodoacetamide, blocking the only remaining free sulfhydryl, i.e., C36 of the 8-chains. (3) The C36-blocked, C190-cross-linked product is reduced with dithiothreitol (D"), unfolded in urea, and a and 8 chains separated by ionexchange chromatography. (4) The C36-blocked 8 chains are refolded by dialysis. (5) The refolded, C36-blocked 88 species are cross-linked at C190 by ferricyanide oxidation. The resulting C36-blocked, ClSO-cross-linked 88 product is separated from contaminating species-mostly completely blocked 8-chains and multichain cross-linked molecules-by size-exclusion chromatography in denaturing (guanidinium chloride) solvent. The five-step process and the final product were monitored by titration of free sulfhydryls and by NaD&O4/poIyacrylamide gel electrophoresis (PAGE). Thermal unfolding curves from CD are reported for the resulting pure, C36-blocked, C190-cross-linked 88 species and for its D"-reduction product, the noncross-linked C36-blocked species. The latter shows almost the same thermal unfolding transition as intact, noncross-linked 88 species. The former shows a pretransition similar to, but larger in extent than, the one well known to occur in the analogous case of Cl90-cross-linked aa tropomydn. These unfolding transitions are compared with one another and with that previously reported for doubly cross-linked (at C36 and C190) 88 species. These comparisons are made in the light of current physical models for coiled-coil unfolding equilibria. I t is concluded that although no extent model is demonstrably satisfactory, any successful model must include strain at the cross-link, loop entropy, and regional nonuniformities as essential parts of the pbysics. tion of particular local conformational transitions in various biological processes in the muscle tissue in which these proteins reside?-" Their struc-'To whom reprint requests should be a d d r d .

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The CD of two‐chain coiled coils: Experiments on tropomyosin and tropomyosin segments in the tyrosin/disulfide spectral region

et al. 1989

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CD experiments are reported for several coiled-coil species in the tyrosine/disulfide (approximately 250-350-nm) region. Intact noncross-linked tropomyosin (approximately 3 degrees C) shows a negative nonsymmetric band maximal at 280 nm. This spectrum is the sum over six tyrosines/chain, and has conformational significance, since it disappears on denaturation. Experiments on an excised coiled-coil segment, each of whose chains comprise residues 11-127 of the tropomyosin sequence and only one tyrosine (Y60), reveal that not all tyrosines are alike. The spectrum at 3 degrees C shows a small negative maximum at approximately 285 nm and a substantial, hitherto unknown, positive band at approximately 270 nm, the latter masked in the parent protein by the negative contribution from the other tyrosines. A noncross-linked coiled-coil segment comprising residues 142-281, in which Y60 is absent, shows no such positive band. This peculiarity of Y60 is confirmed by absorbance spectra, with the extinction coefficient of Y60 larger in benign media than the average of the other tyrosines. Intact (3 degrees C) C190 cross-linked tropomyosin is known to yield, besides tyrosine contributions, a positive maximum at approximately 300 nm. Subtracting the corresponding data for noncross-linked tropomyosin shows that the disulfide spectrum itself actually has two equal, partly resolved bands at, respectively, 250 and 280 nm. The existence of a chiral disulfide argues for a relatively rigid, perhaps strained, local coiled coil. A C190 cross-linked segment comprising residues 142-281 shows a chiral disulfide spectrum like tropomyosin's, but another segment, comprising residues 168-284, shows none; thus removal of residues 142-167 causes loss of chirality at C190, over 20 residues away. These spectra thus contain important information on the subtle local differences in coiled-coil structures.

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.alpha.-Helix to random-coil transition of two-chain, coiled coils: experiments on the thermal denaturation of doubly crosslinked dimeric .beta.-tropomyosin

Cited by 25 publications

References 32 publications

De novo predictions of the quaternary structure of leucine zippers and other coiled coils

De novo predictions of the quaternary structure of leucine zippers and other coiled coils

α‐Helix‐to‐random‐coil transitions of two‐chain coiled coils: Experiments on the thermal denaturation of ββ tropomyosin cross‐linked selectively at C‐190

The CD of two‐chain coiled coils: Experiments on tropomyosin and tropomyosin segments in the tyrosin/disulfide spectral region

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