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Protein structure Ramachandran plot

G. N. Ramachandran and his coworkers in Madras, India, first showed that it was convenient to plot (p values against i/t values to show the distribution of allowed values in a protein or in a family of proteins. A typical Ramachandran plot is shown in Figure 6.4. Note the clustering of (p and i/t values in a few regions of the plot. Most combinations of (p and i/t are sterically forbidden, and the corresponding regions of the Ramachandran plot are sparsely populated. The combinations that are sterically allowed represent the subclasses of structure described in the remainder of this section. [Pg.162]

Fig. 8. A Ramachandran plot (37) indicating the overall geometrical quality of the structure of the Fepr protein from D. vulgaris at 1.7 A resolution. Some 94% of the residues lie within the most favored regions, 5.5% in the additional allowed regions, and only one residue, N303 on the border of a disallowed region. The electron density of this residue is very well defined (see text). Fig. 8. A Ramachandran plot (37) indicating the overall geometrical quality of the structure of the Fepr protein from D. vulgaris at 1.7 A resolution. Some 94% of the residues lie within the most favored regions, 5.5% in the additional allowed regions, and only one residue, N303 on the border of a disallowed region. The electron density of this residue is very well defined (see text).
Figure 5-1. Ramachandran plot of the main chain phi (< ) and psi (T) angles for approximately 1000 nonglycine residues in eight proteins whose structures were solved at high resolution. The dots represent allowable combinations and the spaces prohibited combinations of phi and psi angles. (Reproduced, with permission, from Richardson JS The anatomy and taxonomy of protein structures. Adv Protein Chem 1981 34 167.)... Figure 5-1. Ramachandran plot of the main chain phi (< ) and psi (T) angles for approximately 1000 nonglycine residues in eight proteins whose structures were solved at high resolution. The dots represent allowable combinations and the spaces prohibited combinations of phi and psi angles. (Reproduced, with permission, from Richardson JS The anatomy and taxonomy of protein structures. Adv Protein Chem 1981 34 167.)...
Fig. 44. Distribution of Ala in the Ramachandran plot when using (A) all secondary structure conformations in the protein database or (B) only those Ala residues in a coil conformation. (From Serrano, 1995. 1995, with permission from Academic Press.)... Fig. 44. Distribution of Ala in the Ramachandran plot when using (A) all secondary structure conformations in the protein database or (B) only those Ala residues in a coil conformation. (From Serrano, 1995. 1995, with permission from Academic Press.)...
The favoured dihedral angles for protein main chains were derived from energy considerations of steric clashes in peptides giving the well known Ramachandran plot (Ramachandran and Sasisekharan, 1968). These phi/psi combinations characterize the elements of secondary structure. Accurate main chain models can be constructed from spare parts, that is short pieces of helices, sheets, turns, and random coils taken from highly refined structures, provided a series of C-alpha positions can be established from the electron density map... [Pg.191]

Ramachandran plots serve to answer the question of why the a-helical or the pleated sheet structures have the properties that they do however, the plots do not serve to predict whether a given polypeptide chain will assume the a-helical, the pleated sheet, or a random conformation. Anfinsen and his colleagues have proposed that it is the amino acid composition and sequence in a given peptide chain that determine the conformation the chain assumes. Ideally, we should be able to look at an amino acid sequence of a protein and then... [Pg.71]

Figure 10.1 Basic polypeptide geometry. The upper panel shows a short peptide sequence of three amino acids joined by two peptide bonds. A relatively rigid planar structure, indicated by dashed lines, is formed by each peptide bond. The relative positions of two adjacent peptide bond planes is determined by the rotational dihedral angles

, ip) values correspond to /3-sheets and right-handed o -helices. Left-handed a-helical conformations occur with lower frequency.

Figure 10.1 Basic polypeptide geometry. The upper panel shows a short peptide sequence of three amino acids joined by two peptide bonds. A relatively rigid planar structure, indicated by dashed lines, is formed by each peptide bond. The relative positions of two adjacent peptide bond planes is determined by the rotational dihedral angles <p and <// associated with the Ca of each peptide. The relative frequency of <p and ip angles occurring in proteins observed in a database of structures obtained from crystallography is illustrated in the lower panel. In this plot, called a Ramachandran plot, the shaded regions denote Up. ip) pairs that occur with some frequency in the database. The white region corresponds to (<p, ip) values not observed in crystal structures of proteins due to steric hindrance. The most commonly occurring (4>, ip) values correspond to /3-sheets and right-handed o -helices. Left-handed a-helical conformations occur with lower frequency.
The average of these converged structures is taken as the protein structure, whose precision can be assessed by the deviations of the individual structures from the average. The quality of the final structure can be described in terms of this root mean square deviation, for both the peptide backbone and side chains, and to some extent by the extent to which it conforms to limitations of dihedral bond angles and interatomic contacts anticipated from thousands of previously known structures (the Ramachandran plot ). By all criteria, NMR structures of proteins that are determined in this way are comparable to structures determined by x-ray crystallography. In addition, NMR methods can be applied to evaluate the... [Pg.359]

Ramachandran plot. The density of , y/ values for alanines, glycines, and prolines in 699 proteins of known structure. Proteins were selected from the PDB with... [Pg.220]

Hooft RWW, Sander C, Vriend G. Objectively judging the quality of a protein structure from a Ramachandran plot. Comput Appl Biosci 1997 13 425-430. [Pg.403]

This graph, called a Ramachandran Plot, illustrates the relatively small percentage of all theoretical and rotations that are stable for peptide bonds - at least ones involving only alanine (remember the assumption above). Real proteins, such as Bovine Pancreatic Trypsin Inhibitor have structures that... [Pg.1472]

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See also in sourсe #XX -- [ Pg.9 ]



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