Tentative Rules (1969)

Continued from 2. The Sequence Rules and Choice of Torsion Angle

**Contents**

Continued with 4. Side Chains

Bonds between main-chain atoms are denoted by the symbols of the two atoms terminating them, e.g., _{i}-C_{i}^{α}_{i}^{α}-C_{i}* _{i}*-N

**3.2.1**. The principal torsion angle describing rotation about N-C^{α} is denoted by φ, that describing rotation about C^{α}-C is denoted by ψ, and that describing rotation about C-N is denoted by ω. The symbols φ* _{i}*, ψ

Figure 5: Perspective drawing of a section of polypeptide chain representing two peptide units. The limits of aresidueare indicated by dashed lines, and recommended notations for atoms and torsion angles are indicated. The chain is shown in a fully extended conformation (φ= ψ_{i}= ω_{i}= 180°), and the residue illustrated is L._{i}

(i) This convention differs from that proposed by Edsall *et al.* (1966). The new designation of angles may be derived from the old by adding 180° to, or subtracting 180° from, the latter. (This statement is precisely correct only if the peptide bond is exactly planar, which is not generally the case in experimentally determined structures).

(ii) Owing to the partial double-bond character of , it is normally possible for ω to assume values only in the A neighborhood of 0 or 180°. ω ~ 180° is the value which is generally found (i.e., the *trans* conformation),

(iii) A "fully extended" polypeptide chain is characterized by φ = ψ = ω = +180°. The case of φ = ψ = 0° would involve the relations indicated in Table I.

(iv) Table II gives values of φ and ψ for various well-known regular structures. It is noteworthy that a right-handed α helix has negative torsion angles.

(v) Figure 6 is a typical conformational map ( φ-ψ plot) using the rules enunciated above.

Table I Main-Chain Torsion Angles for Various Conformations in Peptides of L-Amino Acids.^{a,b}

φ (deg) | Rotation about N-C^{α} (to N-H) | ψ (deg) | Rotation about C^{α}-C (to C-O) |
---|---|---|---|

0 | C^{α}-C trans | 0 | C^{α}-N trans |

+60 | C^{α}-H cis | +60 | C^{α}-R cis |

+120 | C^{α}-R trans | +120 | C^{α}-H trans |

+180 | C^{α}-C cis | +180 | C^{α}-N cis |

-120 | C^{α}-H trans | -120 | C^{α}-R trans |

-60 | C^{α}-R cis | -60 | C^{α}-H cis |

b For the description of D-amino acids, interchange C^{α}-H and C^{α}-R in the table.

Table II: Approximate Torsion Angles for Some Regular Structures.^{a}

φ (deg) | ψ (deg) | ω (deg) | Reference | |
---|---|---|---|---|

Right handed α helix (α-poly(L-alanine)) | -57 | -47 | +180 | Arnott and Dover (1967) |

Left-handed α helix | +57 | +47 | +180 | Arnott and Dover (1967) |

Parallel-chain pleated sheet | -119 | +113 | +180 | Schellman and Schellman (1964) |

Antiparallel-chain pleated sheet (β-poly(L-alanine)) | -139 | +135 | -178 | Arnott et al. (1967) |

Polyglycine II | -80 | +150 | +180 | Ramachandran et al. (1966) |

Collagen | -51, -76, -45 | +153, +127, +148 | +180 | Yonath and Traub (1969) |

Poly(L-proline) I | -83 | +158 | 0 | Ramachandran and Sasisekharan (1968), calculated from Traub and Schmueli (1963) |

Poly(L-proline) II | -78 | +149 | +180 | Arnott and Dover (1968) |

Figure 6: Typical conformatial map (Ramachandranet al., 1963) transposed into the standard conventions. Note: this diagram is identical with that of Edsallet al.(1966) except that the origin is now at the center, instead of at the lower left hand corner. The solid lines enclose the freely allowed values of φ and ψ for an alanyl residue in a polypeptide; the dotted lines enclose "outer limit" values based on the shortest known van der Waals radii in related structures. Analogous diagrams for other residues, and for slightly different assumptions, are given by Ramachandran and Sasisekharan (1968; note that these authors used the earlier convention with the origin at the corner).

**3.3.1**. If the terminal amino group of the chain is protonated the three hydrogen atoms are denoted H_{1}^{1}, H_{1}^{2}, and H_{1}^{3}; the hydrogen atom giving the smallest (positive or negative) value of the principal torsion angle H-N-C^{α}-C is denoted H_{1}^{1} and the others are numbered in a clockwise sense when viewed in the direction C^{α}N. The corresponding torsion angles are denoted φ_{1}^{1}, φ_{1}^{2} and φ_{1}^{3}. If the terminal amino group is not protonated the hydrogen atoms are denoted H_{1}^{1} and H_{1}^{2} in accordance with Rule 2.2.2, and the corresponding torsion angles, φ_{1}^{1} and φ_{1}^{2}.

**3.3.2**. At the carboxyl terminus of the chain (*i* = T) the double-bonded oxygen is written as O' and the other oxygen as O", thus

The torsion angles about the C^{α}-C bond are written ψ_{T}^{1} and ψ_{T}^{2} (or ψ1(T), ψ2(T)); the torsion angle about the C-O" bond, defining the orientation of the hydrogen atom of the hydroxyl group relative to C^{α}, is written θ_{T}^{C} (or θC(T)). If the terminal carboxyl group is ionized the oxygen atoms are denoted O' and O", the precedence being determined by Rule 2.3.2, and the torsion angles are written as before.

*Note.* Instead of O' and O" the alternative notations O^{1} and O^{2} may be used. ψ_{T} may be used instead of ψ_{T}^{1}, in conformity with the convention for the middle of the chain, so long as confusion does not arise.

**3.3.3**. Substituted terminal groups. Natural extensions of the above rules may be devised, e.g.

(i) ** N-formyl group** H

(ii) ** N-acetyl group** C

(iii) *C*-amido group

Arnott, S., and Dover, S. D. (1967), *J. Mol. Biol.* **30**, 209.

Arnott, S., and Dover, S. D. (1968), *Acta Cryst.* **B24**, 599.

Arnott, S., Dover, S. D., and Elliott, A. (1967), *J. Mol. Biol.* **30**, 201.

Edsall, J. T., Flory, P. J., Kendrew, J. C., Liquori, A. M., Némethy, G., Ramachandran, G. N., and Scheraga, H. A. (1966), *J. Biol. Chem.* **241**, 1004; *Biopolymers* **4**, 130; *J. Mol. Biol.* **15**, 339.

Ramachandran, G. N., Ramakrishnan, C., and Sasisekharan, V. (1963), *J. Mol. Biol.* **7**, 95.

Ramachandran, G. N., and Sasisekharan, V. (1968), *Advan. Protein Chem.* **23**, 283.

Ramachandran, G. N., Sasisekharan, V., and Ramakrishnan, C. (1966), *Biochim. Biophys. Acta* **112**, 168.

Schellman, J. A., and Schellman, C. (1964), *Proteins 2*, 1.

Traub, W., and Schmueli, U. (1963), in *Aspects of Protein Structure*, Ramachandran, G. N., Ed., Academic Press, London, p 81.

Yonath, A.,and Traub, W. (1969), *J. Mol. Biol.* **43**, 461.

Continued with 4. Side Chains

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