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(New page: <source> from pymol.cgo import * # get constants from math import * from pymol import cmd def pucker(selection): # Author: Sean Law # Institute: Michigan State University # E-mail...) |
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{{Infobox script-repo | |||
|type = script | |||
|filename = pucker.py | |||
|author = [[User:Slaw|Sean M. Law]] | |||
|license = - | |||
}} | |||
<source> | ===DESCRIPTION=== | ||
'''pucker.py''' is a PyMol script that returns the sugar pucker information (phase, amplitude, pucker) for a given selection. | |||
This script uses its own dihedral calculation scheme rather than the get_dihedral command. Thus, it is lightning fast! | |||
If a selection does not contain any ribose sugars then an error message is returned. | |||
===USAGE=== | |||
load the script using the [[run]] command | |||
<source lang="python"> | |||
pucker selection | |||
#Calculates the sugar information for the given selection | |||
pucker selection, state=1 | |||
#Calculates the sugar information for the given selection in state 1 | |||
pucker selection, state=0 | |||
#Iterates over all states and calculates the sugar information for the given selection | |||
</source> | |||
===EXAMPLES=== | |||
<source lang="python"> | |||
#fetch 1BNA.pdb | |||
fetch 1bna | |||
#Select DNA only | |||
#Otherwise, you will get an error for water not having sugars | |||
select DNA, not solvent | |||
#Execute pucker command | |||
pucker DNA | |||
#The output should look like this | |||
Phase Amp Pucker Residue | |||
161.22 55.32 C2'-endo A 1 | |||
139.52 41.67 C1'-exo A 2 | |||
92.82 38.31 O4'-endo A 3 | |||
166.35 48.47 C2'-endo A 4 | |||
128.57 46.30 C1'-exo A 5 | |||
126.92 49.75 C1'-exo A 6 | |||
101.30 47.32 O4'-endo A 7 | |||
115.62 49.23 C1'-exo A 8 | |||
140.44 46.37 C1'-exo A 9 | |||
145.79 53.36 C2'-endo A 10 | |||
147.47 47.04 C2'-endo A 11 | |||
113.80 51.69 C1'-exo A 12 | |||
Phase Amp Pucker Residue | |||
153.24 43.15 C2'-endo B 13 | |||
128.49 45.01 C1'-exo B 14 | |||
67.74 43.84 C4'-exo B 15 | |||
149.33 41.01 C2'-endo B 16 | |||
169.27 42.30 C2'-endo B 17 | |||
147.03 42.30 C2'-endo B 18 | |||
116.29 47.52 C1'-exo B 19 | |||
129.62 49.92 C1'-exo B 20 | |||
113.61 42.93 C1'-exo B 21 | |||
156.34 50.98 C2'-endo B 22 | |||
116.89 44.21 C1'-exo B 23 | |||
34.70 45.55 C3'-endo B 24 | |||
</source> | |||
===PYMOL API=== | |||
<source lang=python> | |||
from pymol.cgo import * # get constants | from pymol.cgo import * # get constants | ||
from math import * | from math import * | ||
from pymol import cmd | from pymol import cmd | ||
def pucker(selection): | def pucker(selection,state=1): | ||
# Author: Sean Law | # Author: Sean Law | ||
# Institute: Michigan | # Institute: University of Michigan | ||
# E-mail: | # E-mail: seanlaw@umich.edu | ||
#Comparison to output from 3DNA is identical | |||
#Note that the 3DNA output has the second chain | |||
for | #printed out in reverse order | ||
state=int(state) | |||
if state == 0: | |||
sel=cmd.get_model(selection) | for state in range(1,cmd.count_states()+1): | ||
sel=cmd.get_model(selection,state) | |||
if state == 1: | |||
print " " #Blank line to separate chain output | |||
print "%5s %6s %6s %8s Residue" % ("State","Phase","Amp", "Pucker") | |||
get_pucker(sel,iterate=state) | |||
else: | |||
sel=cmd.get_model(selection,state) | |||
get_pucker(sel,iterate=0) | |||
return | |||
def get_pucker (sel,iterate=0): | |||
iterate=int(iterate) | |||
first=1 | first=1 | ||
old=" " | old=" " | ||
Line 26: | Line 111: | ||
new=atom.chain+" "+str(atom.resi) | new=atom.chain+" "+str(atom.resi) | ||
newchain=atom.chain+" "+atom.segi | newchain=atom.chain+" "+atom.segi | ||
if | if oldchain != newchain and first: | ||
print " " #Blank line to separate chain output | if iterate == 0: | ||
print " " #Blank line to separate chain output | |||
if | print "%6s %6s %8s Residue" % ("Phase", "Amp", "Pucker") | ||
if new != old and not first: | |||
#Check that all 5 atoms exist | #Check that all 5 atoms exist | ||
if | if len(residue) == 15: | ||
#Construct planes | #Construct planes | ||
get_dihedrals(residue,theta) | get_dihedrals(residue,theta) | ||
Line 39: | Line 125: | ||
else: | else: | ||
print "There is no sugar in this residue" | print "There is no sugar in this residue" | ||
if | if oldchain != newchain: | ||
print " " #Blank line to separate chain output | print " " #Blank line to separate chain output | ||
print "%6s %6s %8s Residue" % ("Phase", "Amp", "Pucker") | print "%6s %6s %8s Residue" % ("Phase", "Amp", "Pucker") | ||
Line 55: | Line 141: | ||
#Final Residue | #Final Residue | ||
#Calculate dihedrals for final residue | #Calculate dihedrals for final residue | ||
if | if len(residue) == 15: | ||
#Construct planes | #Construct planes | ||
get_dihedrals(residue,theta) | get_dihedrals(residue,theta) | ||
#Calculate pucker for final residue | #Calculate pucker for final residue | ||
info = pseudo(residue,theta) | info = pseudo(residue,theta) | ||
print info+" "+old | if iterate == 0: | ||
print info+" "+old | |||
else: | |||
print "%5d %s" % (iterate,info+" "+old) | |||
else: | else: | ||
print "There is no sugar in this residue" | print "There is no sugar in this residue" | ||
Line 75: | Line 164: | ||
amplitude=theta['2']/cos(phase) | amplitude=theta['2']/cos(phase) | ||
phase=math.degrees(phase) | phase=math.degrees(phase) | ||
if | if phase < 0: | ||
phase= | phase+=360 # 0 <= Phase < 360 | ||
#Determine pucker | #Determine pucker | ||
if | if phase < 36: | ||
pucker = "C3'-endo" | pucker = "C3'-endo" | ||
elif | elif phase < 72: | ||
pucker = "C4'-exo" | pucker = "C4'-exo" | ||
elif | elif phase < 108: | ||
pucker = "O4'-endo" | pucker = "O4'-endo" | ||
elif | elif phase < 144: | ||
pucker = "C1'-exo" | pucker = "C1'-exo" | ||
elif | elif phase < 180: | ||
pucker = "C2'-endo" | pucker = "C2'-endo" | ||
elif | elif phase < 216: | ||
pucker = "C3'-exo" | pucker = "C3'-exo" | ||
elif | elif phase < 252: | ||
pucker = "C4'-endo" | pucker = "C4'-endo" | ||
elif | elif phase < 288: | ||
pucker = "O4'-exo" | pucker = "O4'-exo" | ||
elif | elif phase < 324: | ||
pucker = "C1'-endo" | pucker = "C1'-endo" | ||
elif | elif phase < 360: | ||
pucker = "C2'-exo" | pucker = "C2'-exo" | ||
else: | else: | ||
Line 105: | Line 194: | ||
def store_atom(atom,residue): | def store_atom(atom,residue): | ||
if | if atom.name == "O4'" or atom.name == "O4*": | ||
residue['O4*X'] = atom.coord[0] | residue['O4*X'] = atom.coord[0] | ||
residue['O4*Y'] = atom.coord[1] | residue['O4*Y'] = atom.coord[1] | ||
residue['O4*Z'] = atom.coord[2] | residue['O4*Z'] = atom.coord[2] | ||
elif | elif atom.name == "C1'" or atom.name == "C1*": | ||
residue['C1*X'] = atom.coord[0] | residue['C1*X'] = atom.coord[0] | ||
residue['C1*Y'] = atom.coord[1] | residue['C1*Y'] = atom.coord[1] | ||
residue['C1*Z'] = atom.coord[2] | residue['C1*Z'] = atom.coord[2] | ||
elif | elif atom.name == "C2'" or atom.name == "C2*": | ||
residue['C2*X'] = atom.coord[0] | residue['C2*X'] = atom.coord[0] | ||
residue['C2*Y'] = atom.coord[1] | residue['C2*Y'] = atom.coord[1] | ||
residue['C2*Z'] = atom.coord[2] | residue['C2*Z'] = atom.coord[2] | ||
elif | elif atom.name == "C3'" or atom.name == "C3*": | ||
residue['C3*X'] = atom.coord[0] | residue['C3*X'] = atom.coord[0] | ||
residue['C3*Y'] = atom.coord[1] | residue['C3*Y'] = atom.coord[1] | ||
residue['C3*Z'] = atom.coord[2] | residue['C3*Z'] = atom.coord[2] | ||
elif | elif atom.name == "C4'" or atom.name == "C4*": | ||
residue['C4*X'] = atom.coord[0] | residue['C4*X'] = atom.coord[0] | ||
residue['C4*Y'] = atom.coord[1] | residue['C4*Y'] = atom.coord[1] | ||
Line 136: | Line 225: | ||
for i in range (0,12): | for i in range (0,12): | ||
C.append(residue[ribose[i]]) | C.append(residue[ribose[i]]) | ||
theta['0']= | theta['0']=calcdihedral(C) | ||
C = [] | C = [] | ||
Line 142: | Line 231: | ||
for i in range (0,12): | for i in range (0,12): | ||
C.append(residue[ribose[i]]) | C.append(residue[ribose[i]]) | ||
theta['1']= | theta['1']=calcdihedral(C) | ||
Line 149: | Line 238: | ||
for i in range (0,12): | for i in range (0,12): | ||
C.append(residue[ribose[i]]) | C.append(residue[ribose[i]]) | ||
theta['2']= | theta['2']=calcdihedral(C) | ||
Line 156: | Line 245: | ||
for i in range (0,12): | for i in range (0,12): | ||
C.append(residue[ribose[i]]) | C.append(residue[ribose[i]]) | ||
theta['3']= | theta['3']=calcdihedral(C) | ||
C = [] | C = [] | ||
Line 162: | Line 251: | ||
for i in range (0,12): | for i in range (0,12): | ||
C.append(residue[ribose[i]]) | C.append(residue[ribose[i]]) | ||
theta['4']= | theta['4']=calcdihedral(C) | ||
return | return | ||
Line 173: | Line 262: | ||
def shift_down(list,value): | def shift_down(list,value): | ||
for i in range (0,value): | for i in range (0,value): | ||
list. | list.append(list.pop(0)) | ||
return | return | ||
def | def calcdihedral(C): | ||
DX12=C[0]-C[3] | DX12=C[0]-C[3] | ||
Line 216: | Line 305: | ||
TS=1.0-DP12*DP12 | TS=1.0-DP12*DP12 | ||
if | if TS < 0: | ||
TS=0 | TS=0 | ||
else: | else: | ||
Line 229: | Line 318: | ||
DP233=PX3*DX23+PY3*DY23+PZ3*DZ23 | DP233=PX3*DX23+PY3*DY23+PZ3*DZ23 | ||
if | if DP233 > 0: | ||
ANGLE=-ANGLE | ANGLE=-ANGLE | ||
ANGLE=math.degrees(ANGLE) | ANGLE=math.degrees(ANGLE) | ||
if | if ANGLE > 180: | ||
ANGLE= | ANGLE-=360 | ||
if | if ANGLE < -180: | ||
ANGLE= | ANGLE+=360 | ||
return ANGLE | return ANGLE | ||
cmd.extend("pucker",pucker) | cmd.extend("pucker",pucker) | ||
</source> | </source> | ||
[[Category:Script_Library]] | |||
[[Category:Biochemical_Properties]] | |||
[[Category:Biochemical_Scripts]] |
Latest revision as of 08:52, 19 March 2013
Type | Python Script |
---|---|
Download | pucker.py |
Author(s) | Sean M. Law |
License | - |
This code has been put under version control in the project Pymol-script-repo |
DESCRIPTION
pucker.py is a PyMol script that returns the sugar pucker information (phase, amplitude, pucker) for a given selection.
This script uses its own dihedral calculation scheme rather than the get_dihedral command. Thus, it is lightning fast!
If a selection does not contain any ribose sugars then an error message is returned.
USAGE
load the script using the run command
pucker selection
#Calculates the sugar information for the given selection
pucker selection, state=1
#Calculates the sugar information for the given selection in state 1
pucker selection, state=0
#Iterates over all states and calculates the sugar information for the given selection
EXAMPLES
#fetch 1BNA.pdb
fetch 1bna
#Select DNA only
#Otherwise, you will get an error for water not having sugars
select DNA, not solvent
#Execute pucker command
pucker DNA
#The output should look like this
Phase Amp Pucker Residue
161.22 55.32 C2'-endo A 1
139.52 41.67 C1'-exo A 2
92.82 38.31 O4'-endo A 3
166.35 48.47 C2'-endo A 4
128.57 46.30 C1'-exo A 5
126.92 49.75 C1'-exo A 6
101.30 47.32 O4'-endo A 7
115.62 49.23 C1'-exo A 8
140.44 46.37 C1'-exo A 9
145.79 53.36 C2'-endo A 10
147.47 47.04 C2'-endo A 11
113.80 51.69 C1'-exo A 12
Phase Amp Pucker Residue
153.24 43.15 C2'-endo B 13
128.49 45.01 C1'-exo B 14
67.74 43.84 C4'-exo B 15
149.33 41.01 C2'-endo B 16
169.27 42.30 C2'-endo B 17
147.03 42.30 C2'-endo B 18
116.29 47.52 C1'-exo B 19
129.62 49.92 C1'-exo B 20
113.61 42.93 C1'-exo B 21
156.34 50.98 C2'-endo B 22
116.89 44.21 C1'-exo B 23
34.70 45.55 C3'-endo B 24
PYMOL API
from pymol.cgo import * # get constants
from math import *
from pymol import cmd
def pucker(selection,state=1):
# Author: Sean Law
# Institute: University of Michigan
# E-mail: seanlaw@umich.edu
#Comparison to output from 3DNA is identical
#Note that the 3DNA output has the second chain
#printed out in reverse order
state=int(state)
if state == 0:
for state in range(1,cmd.count_states()+1):
sel=cmd.get_model(selection,state)
if state == 1:
print " " #Blank line to separate chain output
print "%5s %6s %6s %8s Residue" % ("State","Phase","Amp", "Pucker")
get_pucker(sel,iterate=state)
else:
sel=cmd.get_model(selection,state)
get_pucker(sel,iterate=0)
return
def get_pucker (sel,iterate=0):
iterate=int(iterate)
first=1
old=" "
oldchain=" "
residue={}
theta={}
count=0
for atom in sel.atom:
new=atom.chain+" "+str(atom.resi)
newchain=atom.chain+" "+atom.segi
if oldchain != newchain and first:
if iterate == 0:
print " " #Blank line to separate chain output
print "%6s %6s %8s Residue" % ("Phase", "Amp", "Pucker")
if new != old and not first:
#Check that all 5 atoms exist
if len(residue) == 15:
#Construct planes
get_dihedrals(residue,theta)
#Calculate pucker
info = pseudo(residue,theta)
print info+" "+old
else:
print "There is no sugar in this residue"
if oldchain != newchain:
print " " #Blank line to separate chain output
print "%6s %6s %8s Residue" % ("Phase", "Amp", "Pucker")
#Clear values
residue={}
dihedrals={}
theta={}
#Store new value
store_atom(atom,residue)
else:
store_atom(atom,residue)
first=0
old=new
oldchain=newchain
#Final Residue
#Calculate dihedrals for final residue
if len(residue) == 15:
#Construct planes
get_dihedrals(residue,theta)
#Calculate pucker for final residue
info = pseudo(residue,theta)
if iterate == 0:
print info+" "+old
else:
print "%5d %s" % (iterate,info+" "+old)
else:
print "There is no sugar in this residue"
return
def sele_exists(sele):
return sele in cmd.get_names("selections");
def pseudo(residue,theta):
other=2*(sin(math.radians(36.0))+sin(math.radians(72.0)))
#phase=atan2((theta4+theta1)-(theta3+theta0),2*theta2*(sin(math.radians(36.0))+sin(math.radians(72.0))))
phase=atan2((theta['4']+theta['1'])-(theta['3']+theta['0']),theta['2']*other)
amplitude=theta['2']/cos(phase)
phase=math.degrees(phase)
if phase < 0:
phase+=360 # 0 <= Phase < 360
#Determine pucker
if phase < 36:
pucker = "C3'-endo"
elif phase < 72:
pucker = "C4'-exo"
elif phase < 108:
pucker = "O4'-endo"
elif phase < 144:
pucker = "C1'-exo"
elif phase < 180:
pucker = "C2'-endo"
elif phase < 216:
pucker = "C3'-exo"
elif phase < 252:
pucker = "C4'-endo"
elif phase < 288:
pucker = "O4'-exo"
elif phase < 324:
pucker = "C1'-endo"
elif phase < 360:
pucker = "C2'-exo"
else:
pucker = "Phase is out of range"
info = "%6.2f %6.2f %8s" % (phase, amplitude, pucker)
return info
def store_atom(atom,residue):
if atom.name == "O4'" or atom.name == "O4*":
residue['O4*X'] = atom.coord[0]
residue['O4*Y'] = atom.coord[1]
residue['O4*Z'] = atom.coord[2]
elif atom.name == "C1'" or atom.name == "C1*":
residue['C1*X'] = atom.coord[0]
residue['C1*Y'] = atom.coord[1]
residue['C1*Z'] = atom.coord[2]
elif atom.name == "C2'" or atom.name == "C2*":
residue['C2*X'] = atom.coord[0]
residue['C2*Y'] = atom.coord[1]
residue['C2*Z'] = atom.coord[2]
elif atom.name == "C3'" or atom.name == "C3*":
residue['C3*X'] = atom.coord[0]
residue['C3*Y'] = atom.coord[1]
residue['C3*Z'] = atom.coord[2]
elif atom.name == "C4'" or atom.name == "C4*":
residue['C4*X'] = atom.coord[0]
residue['C4*Y'] = atom.coord[1]
residue['C4*Z'] = atom.coord[2]
return
def get_dihedrals(residue,theta):
C = []
ribose = residue.keys()
ribose.sort()
shift_up(ribose,6)
for i in range (0,12):
C.append(residue[ribose[i]])
theta['0']=calcdihedral(C)
C = []
shift_down(ribose,3)
for i in range (0,12):
C.append(residue[ribose[i]])
theta['1']=calcdihedral(C)
C = []
shift_down(ribose,3)
for i in range (0,12):
C.append(residue[ribose[i]])
theta['2']=calcdihedral(C)
C = []
shift_down(ribose,3)
for i in range (0,12):
C.append(residue[ribose[i]])
theta['3']=calcdihedral(C)
C = []
shift_down(ribose,3)
for i in range (0,12):
C.append(residue[ribose[i]])
theta['4']=calcdihedral(C)
return
def shift_up(list,value):
for i in range (0,value):
list.insert(0,list.pop())
return
def shift_down(list,value):
for i in range (0,value):
list.append(list.pop(0))
return
def calcdihedral(C):
DX12=C[0]-C[3]
DY12=C[1]-C[4]
DZ12=C[2]-C[5]
DX23=C[3]-C[6]
DY23=C[4]-C[7]
DZ23=C[5]-C[8]
DX43=C[9]-C[6];
DY43=C[10]-C[7];
DZ43=C[11]-C[8];
#Cross product to get normal
PX1=DY12*DZ23-DY23*DZ12;
PY1=DZ12*DX23-DZ23*DX12;
PZ1=DX12*DY23-DX23*DY12;
NP1=sqrt(PX1*PX1+PY1*PY1+PZ1*PZ1);
PX1=PX1/NP1
PY1=PY1/NP1
PZ1=PZ1/NP1
PX2=DY43*DZ23-DY23*DZ43;
PY2=DZ43*DX23-DZ23*DX43;
PZ2=DX43*DY23-DX23*DY43;
NP2=sqrt(PX2*PX2+PY2*PY2+PZ2*PZ2);
PX2=PX2/NP2
PY2=PY2/NP2
PZ2=PZ2/NP2
DP12=PX1*PX2+PY1*PY2+PZ1*PZ2
TS=1.0-DP12*DP12
if TS < 0:
TS=0
else:
TS=sqrt(TS)
ANGLE=math.pi/2.0-atan2(DP12,TS)
PX3=PY1*PZ2-PY2*PZ1
PY3=PZ1*PX2-PZ2*PX1
PZ3=PX1*PY2-PX2*PY1
DP233=PX3*DX23+PY3*DY23+PZ3*DZ23
if DP233 > 0:
ANGLE=-ANGLE
ANGLE=math.degrees(ANGLE)
if ANGLE > 180:
ANGLE-=360
if ANGLE < -180:
ANGLE+=360
return ANGLE
cmd.extend("pucker",pucker)