Adrianna Morris scite author profile

Methods have been developed to assess the stereochemical quality of any protein structure both globally and locally using various criteria. Several parameters can be derived from the coordinates of a given structure. Global parameters include the distribution of phi, psi and chi 1 torsion angles, and hydrogen bond energies. There are clear correlations between these parameters and resolution; as the resolution improves, the distribution of the parameters becomes more clustered. These features show a broad distribution about ideal values derived from high-resolution structures. Some structures have tightly clustered distributions even at relatively low resolutions, while others show abnormal scatter though the data go to high resolution. Additional indicators of local irregularity include proline phi angles, peptide bond planarities, disulfide bond lengths, and their chi 3 torsion angles. These stereochemical parameters have been used to generate measures of stereochemical quality which provide a simple guide as to the reliability of a structure, in addition to the most important measures, resolution and R-factor. The parameters used in this evaluation are not novel, and are easily calculated from structure coordinates. A program suite is currently being developed which will quickly check a given structure, highlighting unusual stereochemistry and possible errors.

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Consequence of β16 and β112 Replacements on the Kinetics of Hemoglobin Assembly

Adachi

Yang

Joshi

et al. 2001

Biochemical and Biophysical Research Communications

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Fluorescence Studies of Human Semi-β-Hemoglobin Assembly

Chiu

Vasudevan

Morris

et al. 1998

Biochemical and Biophysical Research Communications

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Soret Spectroscopic and Molecular Graphic Analysis of Human Semi-β-Hemoglobin Formation

et al. 2000

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The interaction of heme-free alpha (alpha(o)) and heme-containing beta (beta(h)) chains of human hemoglobin has been monitored in 0.1 M potassium phosphate buffer, pH 7 or 8, at 5 degrees C. Soret zero and first-derivative spectra were consistent with a uniform association reaction. Stopped-flow investigations demonstrated association rates on the order of 10(7) M(-1) s(-1). This was 100-fold more rapid than the reported rate of combination of alpha(h) and beta(h) proteins. This encounter-like rate of semi-beta-hemoglobin (alpha(o)beta(h)) formation was increased by raising the pH from 7 to 8. pH change is known to affect the spatial arrangement of AB-GH helical entities. Molecular graphic analysis of modeled alpha(o) protein superimposed over native alpha(h) protein revealed an apo Mb-like structure with well-defined AB-GH segments. Repositioning of these core helical segments, resulting in increased conformational freedom of the alpha1beta1 interface, was apparently responsible for the enhanced association properties of the alpha(o) protein.

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Adrianna Morris

Stereochemical quality of protein structure coordinates

Consequence of β16 and β112 Replacements on the Kinetics of Hemoglobin Assembly

Fluorescence Studies of Human Semi-β-Hemoglobin Assembly

Soret Spectroscopic and Molecular Graphic Analysis of Human Semi-β-Hemoglobin Formation

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