DSSP (algorithm)

The DSSP algorithm is the standard method for assigning secondary structure to the amino acids of a protein, given the atomic-resolution coordinates of the protein. The abbreviation is only mentioned once in the paper describing this algorithm,^[1] where it is the name of the Pascal program that implements the algorithm Define Secondary Structure of Proteins.

DSSP begins by identifying the hydrogen bonds of the protein using a purely electrostatic definition, assuming partial charges of -0.42 e and +0.20 e to the carbonyl oxygen and amide hydrogen respectively, their opposites assigned to the carbonyl carbon and amide nitrogen. A hydrogen bond is identified if E in the following equation is less than -0.5 kcal/mol:

${\displaystyle E=0.084\left\{{\frac {1}{r_{ON}}}+{\frac {1}{r_{CH}}}-{\frac {1}{r_{OH}}}-{\frac {1}{r_{CN}}}\right\}\cdot 332\,\mathrm {kcal/mol} }$

Based on this, eight types of secondary structure are assigned. The 3₁₀ helix, α helix and π helix have symbols G, H and I and are recognized by having a repetitive sequence of hydrogen bonds in which the residues are three, four, or five residues apart respectively. Two types of beta sheet structures exist; a beta bridge has symbol B while longer sets of hydrogen bonds and beta bulges have symbol E. T is used for turns, featuring hydrogen bonds typical of helices, S is used for regions of high curvature (where the angle between ${\displaystyle {\overrightarrow {C_{i}^{\alpha }C_{i+2}^{\alpha }}}}$ and ${\displaystyle {\overrightarrow {C_{i-2}^{\alpha }C_{i}^{\alpha }}}}$ is less than 70°), and a blank (or space) is used if no other rule applies, referring to loops.^[2] These eight types are usually grouped into three larger classes: helix (G, H and I), strand (E and B) and loop (all others).

• DSSP Analysis tool

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