MAPROT (CCP4: Supported Program)

NAME

maprot - map skewing, interpolating, rotating, averaging and correlation masking program

SYNOPSIS

maprot MAPIN foo.map [ WRKIN bar.map ] [ MSKIN bar.msk ] [ MAPOUT foobar.map ] [ WRKOUT foobar.map ] [ CUTOUT foobar.map ]
[Keyworded input]

DESCRIPTION

`maprot' is a general map skewing, interpolating, rotating and averaging program. It can be used to interpolate a map onto a coarser or finer grid, to skew density into a different unit cell, to rotate a map to allow plotting of arbitrary sections, to rotate fragments for molecular replacement or NCS searching, or as part of a single- or multi-crystal averaging calculation. It can also be used to generate `correlation maps' for the automatic determination of averaging masks (reference [1]). Finally, it may be used to 'cut' density from a map and transfer it into another cell with or without a rotation. This is a step in the identification of cross-crystal translations, and general 6-d ncs searches.

`maprot' works with two maps. The first is the `cell' map, which obeys the crystal symmetry and unit cell repeat. The second is 'work' map which does NOT have any symmetry or repeat. The input cell map (MAPIN) must generally cover exactly one unit cell. The work map may store density copied from the cell map, or supply density to be copied into the cell map.

Multiple transformation operators may be supplied. When copying density from the cell map into the work map, then all the related regions of the cell map are all averaged onto the work map. If a mask is specified for the work map, then it is only filled within this mask.

It is also possible to expand from the work map onto the crystal map. This allows a full map averaging calculation to be performed in two steps, or multi-xtal averaging to be performed by multiple runs of the program.

The correlation mode produces a `local correlation map' from the input density (either from the crystal-map in the case of a single crystal with NCS, or between the crystal- and work-maps in the multi-crystal case). This can be contoured in a graphics program to locate the NCS-related part of the unit cell, and/or used to generate an averaging mask using `mapmask'. Multiple correlation maps from different combinations of operators can be combined by summation in `mapmask' (Note: In the case of proper NCS, a correlation mask will show the multimer. In the case of improper NCS it will give just one monomer).

Finally, `maprot' can be used to cut a region of density out of a map and insert it into a blank map, as a step in a phased NCS determination or cross-crystal translation function. In this mode only the work map and mask are supplied. The crystal map cell and grid are set by program keywords. The masked density is transferred from the work map into the crystal map using `MODE TO' and the supplied operator (which may be the identity operator). Only that portion of the crystal map covering the masked density is output to `CUTOUT'.

Remember that "cell" maps will obey crystal symmetry and unit cell repeats; "work" maps do not. See the examples for the calculation you are performing.

INPUT/OUTPUT FILES

MAPIN

Input crystal map. This must cover the whole unit cell (not an asymmetric unit). A suitable map may be prepared using the `mapmask' with just the `XYZLIM CELL' keyword.

WRKIN

Optional starting density for the work map. If this map is not supplied, the density in the work map defaults to zero, and the grid sampling and extent will be determined from MSKIN or the user keywords (BE CAREFUL if you have created a "dummy" map using a set of atomic coordinates; it is important to scale that map by 0.00 to avoid transferring unwanted electron density into the output work map. See example). The values of WRKIN outside any input mask will remain unchanged in WRKOUT, the values inside a mask will be scale * (initial value + rotated density 1 + rotated density 2 + ...)

MSKIN

Optional mask for the work map. This can determine the grid and cell for the work map, and must be consistent with WRKIN. If neither WRKIN nor MSKIN are specified, then the work map must be described by the CELL, GRID, XYZLIM cards. If a mask is not specified, then the whole of the work map will be considered inside the mask and filled with rotated density.

MAPOUT

is the final crystal map. This will only differ from MAPIN if the MODE TO or MODE BOTH options are used.

WRKOUT

is the output work map, which will contain rotated density from the cell MAPIN plus density transferred from WRKIN.

CUTOUT

is the output map from density cutting, containing the rotated masked data. This map only covers the volume of the rotated mask.

Either MAPOUT or WRKOUT or both may be assigned.

KEYWORDED INPUT

Possible keywords are:

AVERAGE, CELL, GRID, INVERT, MODE, RADIUS, SCALE, SYMMETRY, XYZLIM

MODE FROM/TO/BOTH/CORR

Sets the mode of operation.
`FROM' signals that one or more copies of the electron density from a cell map (MAPIN) will be transferred to a work map (WRKOUT). The cell map is transformed by each set of operators in turn, and all copies are summed in the WRKOUT map.
`TO'' signals that density from a work map (WRKIN) will be transferred to a cell map (MAPOUT) using symmetry operators and unit cell repeats obtained from the MAPIN header. It overwrites the density in the input cell map with the masked density from the work map.
`BOTH' performs both operations in turn and is only useful if you have multiple copies of a molecule in the asymmetric unit. It first averages the electron density from the cell map (MAPIN) to WRKOUT, then recreates the cell map (MAPOUT) with the averaged and (hopefully improved) electron density. It requires a mask.
`CORR' calculates a local correlation over the whole of the work map. If two averaging operators are given, then the two regions of density mapped from the cell to the work map by those operators are correlated, otherwise the density of the input work map is correlated with the density of the cell map mapped by the one operator (the first case is used when identifying a non-crystallographic symmetry mask, the second can be used to identify correlated density between crystal forms).

CELL [ WORK | XTAL ] <a> <b> <c> <alpha> <beta> <gamma>

Set the unit cell parameters for the work map (CELL WORK) or the crystal map (CELL XTAL). CELL WORK should be specified if and only if neither MSKIN nor WRKIN are set. CELL XTAL should only be specified if MAPIN is not set.

GRID [ WORK | XTAL ] <nx> <ny> <nz>

Set the grid for the work map (GRID WORK) or the crystal map (GRID XTAL). GRID WORK should be specified if and only if neither MSKIN nor WRKIN are set. GRID XTAL should only be specified if MAPIN is not set.

XYZLIM <x1> <x2> <y1> <y2> <z1> <z2>

Set the work map extent. <x1>-<z2> are given in grid units or in fractional coordinates. This should be specified if and only if neither MSKIN nor WRKIN are set.

SYMMETRY [ WORK | XTAL ] <spacegroup name or number>

Set spacegroup symmetry of the work or crystal map. Unlike the normal SYMMETRY cards, the spacegroup MUST be given by number. Alternatively, the conventional SYMM <spacegroup name> keyword may be used to set the symmetry of the work map only.

SCALE <s>

Set scale factor to apply to the work map inside the mask between rotating FROM and TO the cell map.

RADIUS <r>

Set the radius of with the local correlation is performed in `MODE CORR'. Increase this if the correlation mask shows many spurious peaks. Default <r>=8.0 Angstrom.

AVERAGE

Set a density rotation and translation operator. This keyword is followed by a rotation/translation matrix on subsequent lines in either CCP4 or O/RAVE format. One AVERGE keyword, followed by the corresponding operator, is given for each rotation/translation operation to be performed. The format is the same as the `dm' and `ncsmask' `AVERAGE' cards).

CCP4 Formats: (see also the program `lsqkab')
ROTATE EULER <alpha> <beta> <gamma>     (Euler angles)
TRANSLATE <t1> <t2> <t3>
or
ROTATE POLAR <omega> <phi> <kappa>      (Polar angles)
TRANSLATE <t1> <t2> <t3>
or
ROTATE MATRIX <r11> <r12> <r13> <r21> <r22> <r23> <r31> <r32> <r33>
TRANSLATE <t1> <t2> <t3>
O/RAVE Format

OMAT
<r11> <r21> <r31>
<r12> <r22> <r32>
<r13> <r23> <r33>
<t1> <t2> <t3>
where
x' = <r11>x + <r12>y + <r13>z + <t1>
y' = <r21>x + <r22>y + <r23>z + <t2>
z' = <r31>x + <r32>y + <r33>z + <t3>
(note that the rotation matrix is transposed with respect to CCP4 matrix format.)

These are the operations which map the density in the region covered by the input mask onto the other equivalent regions. The first operator must be the identity matrix. The mask is input in CCP4 mask (mode 0) format on the input file label MSKIN, and should cover just one monomer or averaging domain, NOT the whole unit cell.

INVERT

Invert all the operators.

EXAMPLES

To interpolate a map to a different grid:

#
maprot mapin ins.map wrkout ins_fine.map << eof
MODE FROM
CELL WORK 82.5 82.5 34 90 90 120
GRID WORK 120 120 60
XYZLIM 0 119 0 119 0 59
SYMM WORK 146
AVER
ROTA POLAR 0 0 0
TRANS 0 0 0
eof

To rotate a map 30 degrees about z for plotting (note cell and symm are no longer useful)

#
maprot mapin ins.map wrkout ins_fine.map << eof
MODE FROM
CELL WORK 100 100 50 90 90 120
GRID WORK 180 180 90
XYZLIM 0 179 0 179 0 89
SYMM WORK P1
AVER
ROTA MATRIX  0.866  0.500  0.000  -
            -0.500  0.866  0.000  -
             0.000  0.000  1.000
TRANS    0.000  0.000  0.000
eof

To make an averaged copy of the molecule covered by MSKIN to look at on the graphics

#
maprot mapin chm.map mskin chm.msk wrkout chm_for_graf.map << eof
MODE FROM
AVER
OMAT
  1.000  0.000  0.000
  0.000  1.000  0.000
  0.000  0.000  1.000
  0.000  0.000  0.000
AVER
OMAT
 -0.43073    -0.62689    -0.64921
  0.04987     0.70173    -0.71070
  0.90110    -0.33850    -0.27099
  43.635 38.059 62.726
AVER
OMAT
 -0.43073     0.04987     0.90110
 -0.62689     0.70173    -0.33850
 -0.64921    -0.71070    -0.27099
  82.989 15.401 -8.928
eof

To make an averaged map which can be back-transformed for phase improvement

#
maprot mapin chm.map mskin chm.msk mapout chm_av.map << eof
MODE BOTH
SCALE 0.33333
AVER
ROTA POLAR  0.0  0.0  0.0
TRANS  0.0  0.0  0.0
AVER
ROTA POLAR  113.28130 103.41944 120.33858
TRANS  43.635 38.059 62.726
AVER
ROTA POLAR   66.58067 -76.78019 119.69176
TRANS  82.989 15.401 -8.928
eof

To make a correlation map, convert it to a mask, and tidy up the mask

#
maprot mapin $SCRATCH/chm_mir.map 
       wrkout $SCRATCH/chmcorrel.map << eof
SYMM WORK 1
CELL WORK 90.3 90.3 129.8 90 90 90
XYZLIM     -20 80 24 120 -60 48 
GRID WORK 80 80 120
RADI 6
MODE CORR
AVER
ROTA POLAR  0.0  0.0  0.0
TRANS  0.0  0.0  0.0
AVER
ROTA POLAR  113.28130 103.41944 120.33858
TRANS  43.635 38.059 62.726
END
eof
#
# now mask the multimer: multimer is 6% of unit cell
#
mapmask mapin $SCRATCH/chmcorrel.map 
        mskout $SCRATCH/chmcorrel.msk << eof
MASK VOLU 0.06
eof
#
# Now we might edit this mask by hand, or use ncsmask to get rid of
# all but the largest lump of mask
#
ncsmask mskin $SCRATCH/chmcorrel.msk 
        mskout $SCRATCH/cmncs.msk << eof
PEAK 1
eof

Density cutting: density is cut from one cell and placed in a new cell

#
# Cut density into a 100A virtual cell.
# The density could be moved by specifying a non-identity operator.
# For cross-crystal translation function, give the rotation
# operator and the cell from the alternate crystal form.
#
maprot wrkin gmtocut.map mskin gmtocut.msk cutout cut.map << eof
MODE TO
CELL XTAL 100. 100. 100. 90. 90. 90.
GRID XTAL 150 150 150
AVER
ROTA POLAR  0.0  0.0  0.0
TRANS  0.0  0.0  0.0
eof

BUGS

Since the work map will take the same grid as the mask, it is necessary to use a fine grid for the mask, especially when doing averaging calculations. The grid should be at least as fine as the cell map.

When performing density cutting, If the masked region is larger than the dimensions of the crystal map in any direction, the overlapped density will appear at the edges of the CUTOUT map.

REFERENCES

  1. Stein et al., Structure 2, 45-47 (1994)

SEE ALSO

mapmask, ncsmask, rotmat, dm