Cammon B. Arrington scite author profile

Amide hydrogen (NH) exchange is one of the few experimental techniques with the potential for determining the thermodynamics and kinetics of conformational motions at nearly every residue in native proteins. Quantitative interpretation of NH exchange in terms of molecular motions relies on a simple two-state kinetic model: at any given slowly exchanging NH, a closed or exchange-incompetent conformation is in equilibrium with an open or exchange-competent conformation. Previous studies have demonstrated the accuracy of this model in measuring conformational equilibria by comparing exchange data with the thermodynamics of protein unfolding. We report here a test of the accuracy of the model in determining the kinetics of conformational changes in native proteins. The kinetics of folding and unfolding for ubiquitin have been measured by conventional methods and compared with those derived from a comprehensive analysis of the pH dependence of exchange in native ubiquitin. Rate constants for folding and unfolding from these two very different types of experiments show good agreement. The simple model for NH exchange thus appears to be a robust framework for obtaining quantitative information about molecular motions in native proteins.

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Microsecond Protein Folding Kinetics from Native-State Hydrogen Exchange

Arrington

Robertson

1997

Biochemistry

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Native-state amide proton (NH) exchange in turkey ovomucoid third domain (OMTKY3) has been used to determine rates of unfolding and folding at the 13 most slowly exchanging residues. Ten of the 13 NHs have previously been demonstrated to exchange via complete unfolding of OMTKY3 while the remaining three exchange more slowly than expected on the basis of thermal stability alone [Swint-Kruse, L., Robertson, A. D. (1996) Biochemistry 35, 171-180]. Rates of unfolding and folding have been determined by monitoring MH exchange over a range of pH where (1) the free energy of unfolding for third domain, about 7 kcal/mol, is insensitive to pH and (2) the mechanism of exchange changes from one governed by a rapid equilibrium preceding the chemistry of exchange (i.e., EX2 exchange) to one where exchange is limited by the rate of unfolding (i.e., EX1 exchange). The pH dependence of exchange has then been fit to a two-state model to obtain the unfolding and folding rates. Unfolding rates at these 13 NHs in native third domain range from 0.003 to >/= 0.03 s-1. No correlation is observed between opening rates and the free energies measured at the same NHs: for example, the slowest and most rapid opening rates occur at Leu 23 and Asn 33, respectively, and these two NHs show very similar free energies of 6.7 and 6.9 kcal/mol, respectively. In contrast, folding rates show a positive correlation (R2 = 0.90) with free energies, the most rapid folding occurring at the sites with the largest free energies. folding rates are most rapid, 10(3)-10(4) s-1, in the middle of the helix, intermediate rates of around 10(3) s-1 are found in the remainder of the helix and through much of the beta-sheet, and the slowest folding, 10(2)-10(3) s-1, occurs at the juncture between the helix and sheet. Overall, MH exchange from native proteins provides remarkable structural and temporal precision for measuring very rapid conformational fluctuations.

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Somatic mosaicism contributes to phenotypic variation in Timothy syndrome

Etheridge

Bowles

Arrington

et al. 2011

American J of Med Genetics Pt A

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Timothy syndrome type 1 (TS-1) is a rare disorder that affects multiple organ systems and has a high incidence of sudden death due to profound QT prolongation and resultant ventricular arrhythmias. All previously described cases of TS-1 are the result of a missense mutation in exon 8A (p.G406R), an alternatively spliced variant of the L-type calcium channel gene (Ca(v)1.2, CACNA1C). Most patients reported in the literature represent highly affected individuals who present early in life with severe cardiac and neurological manifestations. Here, we describe somatic mosaicism in TS-1 patients with less severe manifestations than the typical TS-1 patient. These findings suggest that the TS prognosis may not be as dismal as previously reported. Moreover, our findings have implications for genetic counseling in that previously described de novo TS mutations may represent cases of parental mosaicism and warrant careful genotyping of parental tissue other than peripheral blood lymphocytes.

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