g_helixorient_d (1) - Linux Manuals
g_helixorient_d: calculates local pitch/bending/rotation/orientation inside helices
NAME
g_helixorient - calculates local pitch/bending/rotation/orientation inside helicesSYNOPSIS
g_helixorient -s topol.tpr -f traj.xtc -n index.ndx -oaxis helixaxis.dat -ocenter center.dat -orise rise.xvg -oradius radius.xvg -otwist twist.xvg -obending bending.xvg -otilt tilt.xvg -orot rotation.xvg -[no]h -nice int -b time -e time -dt time -[no]xvgr -[no]sidechain -[no]incrementalDESCRIPTION
g_helixorient calculates coordinates and direction of the average axis inside an alpha helix, and the direction/vectors of both the alpha carbon and (optionally) a sidechain atom relative to the axis.
As input, you need to specify an index group with alpha carbon atoms corresponding to an alpha helix of continuous residues. Sidechain directions require a second index group of the same size, containing the heavy atom in each residue that should represent the sidechain.
Note that this program does not do any fitting of structures.
We need four Calpha coordinates to define the local direction of the helix axis.
The tilt/rotation is calculated from Euler rotations, where we define the helix axis as the local X axis, the residues/CA-vector as Y, and the Z axis from their cross product. We use the Euler Y-Z-X rotation, meaning we first tilt the helix axis (1) around and (2) orthogonal to the residues vector, and finally apply the (3) rotation around it. For debugging or other purposes, we also write out the actual Euler rotation angles as theta1-3.xvg
FILES
-s topol.tpr Input
-f traj.xtc
Input
-n index.ndx
Input, Opt.
-oaxis helixaxis.dat
Output
-ocenter center.dat
Output
-orise rise.xvg
Output
-oradius radius.xvg
Output
-otwist twist.xvg
Output
-obending bending.xvg
Output
-otilt tilt.xvg
Output
-orot rotation.xvg
Output
-nice int 19
-b time 0
-e time 0
-dt time 0
-[no]xvgryes
-[no]sidechainno
-[no]incrementalno
OTHER OPTIONS
-[no]hno