Ehrhardt Mr scite author profile

Ehrhardt Mr

3Publications

101Citation Statements Received

98Citation Statements Given

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University of Pennsylvania, University of Illinois Urbana-Champaign

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Energetics and dynamics of molecular recognition by calmodulin

Mr¹,

Jl²,

Aj³

1995

Biochemistry

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Amide hydrogen exchange has been used to examine the structural dynamics and energetics of the interaction of a peptide corresponding to the calmodulin binding domain of smooth muscle myosin light chain kinase with calcium-saturated calmodulin. Heteronuclear NMR 15N-1H correlation techniques were used to quantitate amide proton exchange rates of both 15N-labeled and unlabeled amide protons of the smMLCK peptide complexed to calmodulin. Hydrogen exchange slowing factors were determined for 18 of the 19 amide hydrogens and found to span 6 orders of magnitude. The first six residues of the bound peptide were found to have slowing factors near 1 and are considered not to be hydrogen bonded, consistent with the previously reported model for the structure of the peptide. The pattern of hydrogen exchange of hydrogen-bonded amide hydrogens is indicative of end-fraying behavior characteristic of helix-coil transitions. The effective statistical mechanical parameters revealed by the end fraying are consistent with exchange from a highly solvated state. However, the slowing factors of the first hydrogen-bonded amide hydrogens are large, indicating the requirement for a reorganization of the calmodulin-peptide complex before the helix-coil transitions leading to exchange can occur. Taken together, these observations suggest that the collapsed complex reorganizes with an associated free energy change of 5.5 kcal/mol to a more open state where the helical peptide is highly solvated and undergoes helix-coil transitions leading to exchange. The free energy difference between the most and least stable intrahelical amide hydrogen bonds of the bound peptide is estimated to be approximately 2.5 kcal/mol.(ABSTRACT TRUNCATED AT 250 WORDS)

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Untitled

1999

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The majority of proteins are too large to be comprehensively examined by solution NMR methods, primarily because they tumble too slowly in solution. One potential approach to making the NMR relaxation properties of large proteins amenable to modern solution NMR techniques is to encapsulate them in a reverse micelle which is dissolved in a low viscosity fluid. Unfortunately, promising low viscosity fluids such as the short chain alkanes, supercritical carbon dioxide, and various halocarbon refrigerants all require the application of significant pressure to be kept liquefied at room temperature. Here we describe the design and use of a simple cost effective NMR tube suitable for the preparation of solutions of proteins encapsulated in reverse micelles dissolved in such fluids.

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Molecular Recognition by Calmodulin: Pressure-Induced Reorganization of a Novel Calmodulin−Peptide Complex

Erijman

Weber

et al. 1996

Biochemistry

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The interaction of apocalmodulin (apoCaM) with a peptide (Neurop) based on the primary sequence of the calmodulin-binding domain of neuromodulin has been studied by fluorescence spectroscopy. The 1:1 complex (12 microM) formed between apoCaM and the Neurop peptide is extremely sensitive to salt and is half dissociated in less than 0.1 M KCl, suggesting that electrostatic interactions contribute strongly to complex formation. Ion pair interactions are frequently sensitive to high hydrostatic pressure due to electrostriction effects in the solvated ion state. Application of high pressure to the apoCaM.Neurop complex causes a red shift of the Neurop tryptophan emission center of mass and a reduced residual anisotropy but with insignificant reduction in quantum yield. The transition is smooth, reversible, and apparently two-state with a midpoint pressure of approximately 0.8 kbar. The residual anisotropy, quantum yield, and center of mass of the emission spectrum are consistent with the movement of the tryptophan side chain to a more solvated, slightly less restricted environment upon the pressure-induced transition. The pressure effect is independent of the concentration of the complex. These and other data are consistent with the pressure-induced reorganization being a unimolecular event not requiring dissociation of the complex. A volume change of approximately 66 mL mol-1 and a free energy change of approximately 1.7 kcal mol-1 are associated with the reorganization. The residual interactions maintaining the complex under high pressure are characterized by low standard molar volume and/or high standard free energy changes upon disruption but are destroyed by 200 mM KCl. It is postulated that the main effect of salt on the complex at high pressure is to drive the collapse of the hydrophobic pocket to which the peptide is binding.

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Ehrhardt Mr

Energetics and dynamics of molecular recognition by calmodulin

Untitled

Molecular Recognition by Calmodulin: Pressure-Induced Reorganization of a Novel Calmodulin−Peptide Complex

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