Ruud M. Scheek scite author profile

A method is presented that generates random protein structures that fulfil a set of upper and lower interatomic distance limits. These limits depend on distances measured in experimental structures and the strength of the interatomic interaction. Structural differences between generated structures are similar to those obtained from experiment and from MD simulation. Although detailed aspects of dynamical mechanisms are not covered and the extent of variations are only estimated in a relative sense, applications to an IgG-binding domain, an SH3 binding domain, HPr, calmodulin, and lysozyme are presented which illustrate the use of the method as a fast and simple way to predict structural variability in proteins. The method may be used to support the design of mutants, when structural fluctuations for a large number of mutants are to be screened. The results suggest that motional freedom in proteins is ruled largely by a set of simple geometric constraints.

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A protein structure from nuclear magnetic resonance data

Kaptein

Zuiderweg

Scheek

et al. 1985

Journal of Molecular Biology

468

218

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Time-dependent distance restraints in molecular dynamics simulations

Torda

Scheek

Gunsteren

1989

Chemical Physics Letters

268

214

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Time-averaged nuclear overhauser effect distance restraints applied to tendamistat

Torda

Scheek

Gunsteren

1990

Journal of Molecular Biology

283

196

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Sequential resonance assignments in proton NMR spectra of oligonucleotides by two-dimensional NMR spectroscopy

Scheek¹,

Boelens²,

Russo³

et al. 1984

Biochemistry

267

174

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A sequential assignment procedure is outlined, based on two-dimensional NOE ( NOESY ) and two-dimensional J-correlated spectroscopy ( COSY ), for assigning the nonexchangeable proton resonances in NMR spectra of oligonucleotides. As presented here the method is generally applicable to right-handed helical oligonucleotides of intermediate size. We applied it to a lac operator DNA fragment consisting of d( TGAGCGG ) and d( CCGCTCA ) and obtained complete assignments for the adenine H8, guanine H8, cytosine H6 and H5, thymine H6 and 5-methyl, and the deoxyribose H1', H2', H2", H3', and H4' resonances, as well as some H5', H5" (pairwise) assignments. These assignments are required for the analysis of two-dimensional NOE and J-coupling data in terms of the solution structure of oligonucleotides.

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Ruud M. Scheek

Prediction of protein conformational freedom from distance constraints

A protein structure from nuclear magnetic resonance data

Time-dependent distance restraints in molecular dynamics simulations

Time-averaged nuclear overhauser effect distance restraints applied to tendamistat

Sequential resonance assignments in proton NMR spectra of oligonucleotides by two-dimensional NMR spectroscopy

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