Local structure involving histidine-12 in reduced S-sulfonated ribonuclease A detected by proton NMR spectroscopy under folding conditions.

Swadesh, Joel K.; Montelione, Gaetano T.; Thannhauser, Theodore W.; Scheraga, Harold A.

doi:10.1073/pnas.81.14.4606

Cited by 16 publications

(17 citation statements)

References 55 publications

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“…Experimental results from a combined sample of RNase A and the S-peptide, residues 1-20, demonstrated that resonance D belongs to the C'H of His-12 (see following section). The chemical shift of peak C is very similar to the chemical shift of C'H His-105 in disulfide-reduced and sulfonated RNase A (Swadesh et al, 1984). The C'H His resonances of sulfo-nated RNase A (8S032~-RNase A) were assigned by selective deuteriation procedures.…”

Section: Resultsmentioning

confidence: 82%

“…In order to examine the formation of structure in the refolding ensemble in greater detail, ID NMR spectra of the nonnative forms of RNase A were taken from 11 to 70 °C. This approach has been used by several investigators to study the formation of compact structures in chemically modified, nonfolding forms of RNase A (Rico et al, 1983(Rico et al, , 1986; Kim & Baldwin, 1984;Swadesh et al, 1984). The term nonnative RNase A refers to conformations found in both the refolding ensemble and the heat-denatured protein.…”

Section: Resultsmentioning

confidence: 99%

“…These difficulties could be surmounted if it were possible to trap the folding intermediate. Several groups have investigated the folding of RNase A where complete refolding was inhibited by chemical modification Rico et al, 1983Rico et al, , 1986; Kim & Baldwin,1984;Swadesh et al, 1984;Haas et al, 1987). These compounds have been very useful in studying the formation of structures in specific regions of the protein, such as the N-terminal -helix.…”

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confidence: 99%

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Structural studies of a folding intermediate of bovine pancreatic ribonuclease A by continuous recycled flow

Adler¹,

Scheraga²

1988

Biochemistry

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A new technique, continuous recycled flow (CRF) spectroscopy, has been developed for observing intermediates of any thermally induced, reversible reaction with a half-life of 10 s or longer. The structure can be probed by any spectroscopic method which does not perturb the system. Prolonged signal acquisitions of 8 h for ribonuclease A are possible. CRF was used to investigate the structure of the slow-folding intermediates of chemically intact ribonuclease A (RNase A) during thermal unfolding/folding under acidic conditions. The following conclusions were reached on the basis of the proton nuclear magnetic resonance and far-ultraviolet circular dichroism spectra of a folding intermediate(s): (A) The conformation of the detected folding intermediate(s) is similar to that of the heat-denatured protein. There is only limited formation of new structures. (B) The N-terminal alpha-helix is partially stable under these conditions and is in rapid (less than 10 ms) equilibrium with the denatured conformation. (C) There are long-range interactions between the hydrophobic residues of the N-terminal alpha-helix and the rest of the protein. These interactions persist well above the melting point. (D) An aliphatic methyl group reports on the formation of a new structure(s) that lie(s) outside of the N-terminal region. (E) The structures detected in chemically modified, nonfolding forms of the RNase A are also present in the folding intermediate(s). There are, however, additional interactions that are unique to chemically intact RNase A.

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Section: Resultsmentioning

confidence: 82%

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

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Structural studies of a folding intermediate of bovine pancreatic ribonuclease A by continuous recycled flow

Adler¹,

Scheraga²

1988

Biochemistry

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“…The unfolded state ensembles of a number of proteins have been characterized by NMR and other spectroscopic methods. Depending on solution conditions, the unfolded states may show conformational preferences for native-like or non-native residual structure (Swadesh et al, 1984;Dill and Shortle, 1991;Neri et al, 1992;Sosnick and Trewhella, 1992;Shortle, 1993;Logan et al, 1994;Arcus et al, 1995;Buckler et al, 1995;Ittah and Haas, 1995;Dyson and Wright, 1998;Navon et al, 2001;Yao et al, 2001;Schwarzinger et al, 2002). But there are relatively few proteins whose folding transition states have been characterized in detail.…”

Section: Discussionmentioning

confidence: 99%

Implementation of a k/k0 Method to Identify Long-Range Structure in Transition States during Conformational Folding/Unfolding of Proteins

et al. 2007

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A previously introduced kinetic-rate constant (k/k(0)) method, where k and k(0) are the folding (unfolding) rate constants in the mutant and the wild-type forms, respectively, of a protein, has been applied to obtain qualitative information about structure in the transition state ensemble (TSE) of bovine pancreatic ribonuclease A (RNase A), which contains four native disulfide bonds. The method compares the folding (unfolding) kinetics of RNase A, with and without a covalent crosslink and tests whether the crosslinked residues are associated in the folding (unfolding) transition state (TS) of the noncrosslinked version. To confirm that the fifth disulfide bond has not introduced a significant structural perturbation, we solved the crystal structure of the V43C-R85C mutant to 1.6 A resolution. Our findings suggest that residues Val43 and Arg85 are not associated, and that residues Ala4 and Val118 may form nonnative contacts, in the folding (unfolding) TSE of RNase A.

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“…By monitoring the chemical shifts of the His C 1 H resonances, we identified the local structure in the vicinity of His 12 in reduced S-sulfonated RNase A (Swadesh et al, 1984) and in the disulfide-intact guanidine-denatured protein (Bierzynski & Baldwin, 1982). Predictions, based on hydrophobic interactions in the wild-type protein, have determined that the C-terminal region including residues 105-124 is the primary region of initial structure formation or CFIS (Matheson & Scheraga, 1978).…”

Section: Evidence Of Local Structure Involving a His Residuementioning

confidence: 99%

Regeneration Studies of an Analog of Ribonuclease A Missing Disulfide Bonds 65−72 and 40−95

et al. 1997

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Mutants of bovine pancreatic ribonuclease A (RNase A) that contain four of the eight cysteine residues found in the wild-type protein were prepared. Cysteine residues 40, 65, 72, and 95 were replaced by serine to form [C40S,C65S,C72S,C95S] RNase A or by alanine to form [C40A,C65A,C72A,C95A] RNase A, which contain the following four cysteine residues: 26, 58, 84, and 110. The substitutions resulted in deletion of wild-type disulfide bonds, 65-72 and 40-95. These mutants were prepared to investigate interactions that may be important for the folding and unfolding of the wild-type protein. The mutant protein was expressed and purified in an unfolded sulfonated form. Upon regeneration of the native form from the reduced mutant with DTTox, all three of the possible two-disulfide pairings, including the native one, formed. One-dimensional 1H NMR spectra demonstrated that the conformations of these three species are similar and are predominantly disordered; however, there is evidence of local structure in the vicinity of one histidine residue. It was also shown that disulfide pairing is not completely random and that both entropic factors and enthalpic interactions contribute to the formation of the native-disulfide bonds. The presence of more than a statistical population of native-disulfide pairings indicates that specific local interactions present in the reduced protein direct the preferential formation of native-disulfide bonds in the two-disulfide mutant.

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Local structure involving histidine-12 in reduced S-sulfonated ribonuclease A detected by proton NMR spectroscopy under folding conditions.

Cited by 16 publications

References 55 publications

Structural studies of a folding intermediate of bovine pancreatic ribonuclease A by continuous recycled flow

Structural studies of a folding intermediate of bovine pancreatic ribonuclease A by continuous recycled flow

Implementation of a k/k0 Method to Identify Long-Range Structure in Transition States during Conformational Folding/Unfolding of Proteins

Regeneration Studies of an Analog of Ribonuclease A Missing Disulfide Bonds 65−72 and 40−95

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