Difference between revisions of "Recycling Corner/Alpha Helix Generator"
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Creates an alpha helix from a user input string. | Creates an alpha helix from a user input string. | ||
| − | Jmol script by Ron Mignery with help from [[User:AngelHerraez|Angel | + | Jmol script by Ron Mignery with help from [[User:AngelHerraez|Angel Herráez]] |
__TOC__ | __TOC__ | ||
Latest revision as of 19:34, 9 October 2019
RIBOZOME - a Polypeptide Alpha Helix Generator script
Creates an alpha helix from a user input string.
Jmol script by Ron Mignery with help from Angel Herráez
Contents
Script for the Jmol application
The top-level function plico_gen_pp asks user for a peptide sequence in a pop-up.
The top-level function plico_gen_alpha accepts a sequence string as a parameter.
With this script you can generate a polypeptide alpha helix chain from a sequence string in 1-char amino-acid coding. You can optionally give it a chain label other than the default :A or start at a residue number other than the default 1. You can also add to an existing chain, add new chains to an existing model or now create the chain in a new frame by prepending a '+' to the sequence string.
Chains start from the origin and extend along the Z-axis as they are built. If a chain with the same chain label as the new chain is at the origin, the new sequence is added to the old. If a chain with a different chain label is at the origin, all existing chains are shifted 20 angstroms to the right along the X axis until the origin is clear.
Ribozome is a member of the Plico suite of protein folding tools described here. It may be installed and accessed as a macro with the file:
Title=PLICO Generate Polypeptide Script=script <path to your script folder>/ribozome.spt;plico_gen_pp
saved as ribozome.macro in your .jmol/macros directory as described in Macro.
Copy and paste the following into a text editor and save in your scripts directory as ribozome.spt.
# RIBOZOME - Jmol script by Ron Mignery
# v1.19 beta 4/12/2016 -axis is now a reserved word
#
# RIBOZOME takes a string message encoding an amino acid (aa) sequence
# and generates a corresponding alpha helix one aa at a time from the
# N terminus to the C terminus rotating the emerging helix as it goes.
#
# The message is a string entered by the user at a prompt. <+A:><n...>[A-Z]...
# It may be typed in or pasted in and be of any length
# If the message is prepended with "+" then the chain is created in a new
# frame. Otherwise it is added to the current frame
# If the message is then prepended with <C>: (where C is any single letter)
# then the chain is so labeled and separated from existing chains
# if different from the first chain.
# If the message is then prepended with digits (-0-9), that number becomes
# the first resno (even if negative). Otherwise the first is 1.
#
# The IUPAC/IUBMB 1 letter code is used:
# A=ALAnine B=GLutam?X* C=CYSteine D=ASPartate E=GLUtamate
# F=PHEnylalanine G=GLYcine H=HIStidine I=IsoLEucine K=LYSine
# L=LEUcine M=METhionine N=ASparagiNe O=PYrroLysine*** P=PROline
# Q=GLutamiNe R=ARGinine S=SERine T=THReonine U=SElenoCysteine
# V=VALine W=TRyPtophan X=UNKnown Y=TYRosine Z=ASpar?X**
# *Either GLU or GLN: drawn as GLN with chi3 flipped
# **Either ASP or ASN: drawn as ASN with chi3 flipped
# ***Not supported: drawn as ALA
# The following constant values determine the pitch of the alpha helix
kPHI = -64 # Dihedral angle of N-CA bond (nominally -64)
kPSI = -39 # Dihedral angle of CA-C bond (nominally -39)
kOMEGA = 180 # Dihedral angle of the peptide bond (nominally 180)
kPEPTIDE_ANGLE = 120 # C-N-CA angle (nominally 120)
kPRO_BUMP = -10 # Psi angle change increment to N-3psi when N is Pro
gCHAIN = 'A' # The chain id
gA = ""
gPdbAddHydrogens = false
gAppendNew = true
gNewFrame = false
gSeq = ""
# Lookup 3 letter code from 1 letter code
g3from1 = {"A":"ALA", "B":"GLX","C":"CYS", "D":"ASP","E":"GLU", "F":"PHE",
"G":"GLY", "H":"HIS","I":"ILE", "K":"LYS","L":"LEU", "M":"MET",
"N":"ASN", "O":"PYL","P":"PRO", "Q":"GLN","R":"ARG", "S":"SER",
"T":"THR", "U":"SEC","V":"VAL", "W":"TRP","X":"UNK", "Y":"TYR", "Z":"ASX"}
# Generate PDB atom record
function gen_atom(e, aa, i, xyz) {
gA = format("ATOM %5d %4s %3s ", gN, e, aa )
gA += format("%s%4d %8.3f", gCHAIN, i, xyz[1] )
gA += format("%8.3f%8.3f\n", xyz[2], xyz[3] )
gN++
return gA
};
# Generate a PDB amino acid record set
function gen_aa(i, aa) { # Writes globals gA and gN
# From constructed AAs
var N0 = [0.0, 0.0, 0.0]
var CA = [ 0.200, 1.174, 0.911 ]
var C = [ -1.110, 1.668, 1.425 ]
var O = [ -1.320, 1.693, 2.62 ]
var CB = [ 1.062, 2.1950, 0.230 ]
var G1 = [ 2.359, 1.607, -0.344]
var G2 = [ 1.363, 3.336, 1.157 ]
var D1 = [ 3.222, 2.656, -1.048 ]
var D2 = [ 3.143, 0.904, 0.725 ]
var E1 = [ 3.645, 3.749, -0.167 ]
var E2 = [ 2.491, 3.234, -2.249 ]
var Z = [ 4.474, 4.857, -0.565 ]
var H1 = [ 4.090, 6.173, -0.166 ]
var H2 = [ 5.565, 4.707, -1.229 ]
var D1dn = [ 2.955, 2.229, -1.250 ]
var D2dn = [ 2.859, 0.552, 0.102 ]
var E1eq = [ 3.821, 3.528, -0.382 ]
var E2eq = [ 3.337, 2.634, -2.293 ]
var Gp = [ 2.008, 1.24, -0.46 ]
var Dp = [ 1.022, 0.213, -1.031 ]
var Gfy = [ 2.368, 1.471, -0.0152 ]
var D1fy = [ 3.346, 1.524, 0.921 ]
var D2fy = [ 2.493, 0.516, -1.151 ]
var E1fy = [ 4.513, 0.615, 0.8244 ]
var E2fy = [ 3.528, -0.336, -1.206 ]
var Zfy = [ 4.588, -0.285, -0.168 ]
var Hfy = [ 5.738, -1.245, -0.233 ]
var Ghw = [ 2.406, 1.626, -0.134 ]
var D1hw = [3.498, 1.936, 0.675]
var D2hw = [ 2.713, 0.901, -1.211 ]
var E1hw = [ 4.160, 0.518, -1.178 ]
var E2hw = [ 4.622, 1.160, 0.0816 ]
var E3hw = [ 3.789, 2.523, 1.944 ]
var Z2hw = [ 5.973, 1.177, 0.689 ]
var Z3hw = [ 5.014, 2.550, 2.503 ]
var H2hw = [ 6.153, 1.846, 1.844 ]
#N1 = [ 2.069, -2.122, -0.554]
# Build PDB atom records common to all AAs
var a3 = g3from1[aa]
if (a3 = "") {
a3 = "UNK"
}
print format("+ %s%d/%d", a3, i, gSeq.count + gResno)
gA = gen_atom(" N ", a3, i, N0)
gA += gen_atom(" CA ", a3, i, CA)
gA += gen_atom(" C ", a3, i, C)
gA += gen_atom(" O ", a3, i, O)
if ((aa != 'G') && (aa != 'X')) {
gA += gen_atom(" CB ", a3, i, CB)
}
# Now add AA specific atom records
switch (aa) {
case 'A' :
break;
case 'B' :
gA += gen_atom(" CG ", a3, i, G1)
gA += gen_atom(" CD ", a3, i, D1)
gA += gen_atom(" OE1", a3, i, E2eq) # GLN with Es switched
gA += gen_atom(" NE2", a3, i, E1eq)
break;
case 'C' :
gA += gen_atom(" SG ", a3, i, G2)
break;
case 'D' :
gA += gen_atom(" CG ", a3, i, G1)
gA += gen_atom(" OD1", a3, i, D1dn)
gA += gen_atom(" OD2", a3, i, D2dn)
break;
case 'E' :
gA += gen_atom(" CG ", a3, i, G1)
gA += gen_atom(" CD ", a3, i, D1)
gA += gen_atom(" OE1", a3, i, E1eq)
gA += gen_atom(" OE2", a3, i, E2eq)
break;
case 'F' :
gA += gen_atom(" CG ", a3, i, Gfy)
gA += gen_atom(" CD1", a3, i, D1fy)
gA += gen_atom(" CD2", a3, i, D2fy)
gA += gen_atom(" CE1", a3, i, E1fy)
gA += gen_atom(" CE2", a3, i, E2fy)
gA += gen_atom(" CZ ", a3, i, Zfy)
break;
case 'G' :
break;
case 'H' :
gA += gen_atom(" CG ", a3, i, Ghw)
gA += gen_atom(" ND1", a3, i, D1hw)
gA += gen_atom(" CD2", a3, i, D2hw)
gA += gen_atom(" CE1", a3, i, E2hw)
gA += gen_atom(" NE2", a3, i, E1hw)
break;
case 'I' :
gA += gen_atom(" CG1", a3, i, G1)
gA += gen_atom(" CG2", a3, i, G2)
gA += gen_atom(" CD1", a3, i, D1)
break;
case 'K' :
gA += gen_atom(" CG ", a3, i, G1)
gA += gen_atom(" CD ", a3, i, D1)
gA += gen_atom(" CE ", a3, i, E1)
gA += gen_atom(" NZ ", a3, i, Z)
break;
case 'L' :
gA += gen_atom(" CG ", a3, i, G1)
gA += gen_atom(" CD1", a3, i, D1)
gA += gen_atom(" CD2", a3, i, D2)
break;
case 'M' :
gA += gen_atom(" CG ", a3, i, G1)
gA += gen_atom(" SD ", a3, i, D1)
gA += gen_atom(" CE ", a3, i, E1)
break;
case 'N' :
gA += gen_atom(" CG ", a3, i, G1)
gA += gen_atom(" OD1", a3, i, D1dn)
gA += gen_atom(" ND2", a3, i, D2dn)
break;
case 'P' :
gA += gen_atom(" CG ", a3, i, GP)
gA += gen_atom(" CD ", a3, i, DP)
break;
case 'Q' :
gA += gen_atom(" CG ", a3, i, G1)
gA += gen_atom(" CD ", a3, i, D1)
gA += gen_atom(" OE1", a3, i, E1eq)
gA += gen_atom(" NE2", a3, i, E2eq)
break;
case 'R' :
gA += gen_atom(" CG ", a3, i, G1)
gA += gen_atom(" CD ", a3, i, D1)
gA += gen_atom(" NE ", a3, i, E1)
gA += gen_atom(" CZ ", a3, i, Z)
gA += gen_atom(" NH1", a3, i, H1)
gA += gen_atom(" NH2", a3, i, H2)
break;
case 'S' :
gA += gen_atom(" OG ", a3, i, G1)
break;
case 'T' :
gA += gen_atom(" OG1", a3, i, G1)
gA += gen_atom(" CG2", a3, i, G2)
break;
case 'U' :
gA += gen_atom("SeG ", a3, i, G1)
break;
case 'V' :
gA += gen_atom(" CG1", a3, i, G1)
gA += gen_atom(" CG2", a3, i, G2)
break;
case 'W' :
gA += gen_atom(" CG ", a3, i, Ghw)
gA += gen_atom(" CD2", a3, i, D1hw)
gA += gen_atom(" CD1", a3, i, D2hw)
gA += gen_atom(" CE2", a3, i, E2hw)
gA += gen_atom(" NE1", a3, i, E1hw)
gA += gen_atom(" CE3", a3, i, E3hw)
gA += gen_atom(" CZ2", a3, i, Z2hw)
gA += gen_atom(" CZ3", a3, i, Z3hw)
gA += gen_atom(" CH2", a3, i, H2hw)
break;
case 'X' :
gA += gen_atom(" Xx ", a3, i, CB)
break;
case 'Y' :
gA += gen_atom(" CG ", a3, i, Gfy)
gA += gen_atom(" CD1", a3, i, D1fy)
gA += gen_atom(" CD2", a3, i, D2fy)
gA += gen_atom(" CE1", a3, i, E1fy)
gA += gen_atom(" CE2", a3, i, E2fy)
gA += gen_atom(" CZ ", a3, i, Zfy)
gA += gen_atom(" OH ", a3, i, Hfy)
break;
case 'Z' :
gA += gen_atom(" CG ", a3, i, G1)
gA += gen_atom(" OD1", a3, i, D2dn) # ASN with Ds switched
gA += gen_atom(" ND2", a3, i, D1dn)
break;
default :
break;
}
return gA
};
# Generate an alpha helix
function plico_gen_alpha(seq) {
try {
gPdbAddHydrogens = pdbAddHydrogens
set pdbAddHydrogens false
if (gPlicoRecord != "") {
var g = format("show file \"%s\"", gPlicoRecord)
var ls = script(g)
if (ls.find("FileNotFoundException")) {
ls = ""
}
ls += format("plico_gen_alpha(\"%s\");", seq)
write var ls @gPlicoRecord
}
seq = seq%9999%0
gNewFrame = false
if (seq[1] == '+') {
gNewFrame = true
seq = seq[2][9999]
}
if (seq[2] == ':') {
gCHAIN = seq[1]
seq = seq[3][9999]
}
var resStart = ""
while ("_0123456789-".find(seq[1]) > 0) {
resStart += ""+seq[1]
seq = seq[2][9999]
}
gSeq = seq
var c = gCHAIN
if (resStart.size > 0) {
gResno = -1 + resStart # global pre-existing AA count
}
else {
gResno = 0 # global pre-existing AA count
}
var pn = 1 # previous gN
gAppendNew = appendNew
gN = 1
if (gNewFrame) {
appendNew = true
}
else {
appendNew = false
# If not new
if (m > 0) {
# Get the largest atomno in frame
gN = {thisModel}.atomno.max
# While there is an atom at the origin
while (true) {
var ai = {within(0.1, {0 0 0}) and thisModel}
if (ai) {
# If on the same chain
if (ai[1].chain = c) {
# Delete OXT
delete {(atomName="OXT") and thisModel
and (chain=c)}
gResno = ai.resno
pn = ai.atomno
break
}
# Else move all from the new chain rightward on X axis
else {
select {thisModel and (chain!=c)}
translateselected {20, 0, 0 }
gN++
}
}
else {
break
}
} # endwhile
}
}
# For each aa
var nn = gN # new N
for (var i = 1; i <= gSeq.count; i++) {
if ((m > 0) and not appendNew) {
# Move polypeptide C to bond distance from new AA N
select {thisModel and (chain=c)}
fix none
translateselected {2.069, -2.122, -0.554 } #N1
}
# Gen AA
gA = "data \"append aa\"\n" # global PDB atom record
gA += gen_aa(i + gResno, gSeq[i]) # gN is updated in subroutine
gA += "end \"append aa\""
script inline @{gA}
var f = (_frameID/1000000)
var m = (_frameID%1000000)
appendNew = false
# If PRO ahead
var pb = 0
if ((gSeq.count - i) >= 2) {
if (gSeq[i + 2] == 'P') {
pb = kPRO_BUMP
}
}
# If not first AA
if (nn > 1) {
# Gen axis on new N perpendicular to the plane
# containing atoms nn, pn+2 and nn+1
var aNn = {(atomno=nn) and thisModel and (chain=c)}
var aNn1 = {(atomno=@{nn+1}) and thisModel and (chain=c)}
var aPn1 = {(atomno=@{pn+1}) and thisModel and (chain=c)}
var aPn2 = {(atomno=@{pn+2}) and thisModel and (chain=c)}
var aPn3 = {(atomno=@{pn+3}) and thisModel and (chain=c)}
var v1=aPn2.xyz - aNn.xyz
var v2=aNn1.xyz - aNn.xyz
var caxis = cross(v1, v2)
# Center on atom previous C
caxis += aPn2.xyz
# Rotate the polypeptide N on the new AA C to tetrahedral (nominally 110)
select {(atomno < nn) and thisModel and (chain=c)}
fix {(atomno >= nn) and thisModel and (chain=c)}
rotateselected @caxis @aNn @{kPEPTIDE_ANGLE - 65.5}
# Make omega dihedral = kOMEGA (nominally 180)
rotateselected @aPn2 @aNn @{kOMEGA - 157.8}
# Make the new phi dihedral = kPHI (nominally -60)
rotateselected @aNn @aNn1 @{-kPHI - 116.5}
# Make the old psi dihedral = kPSI (nominally -50)
select {(atomno < nn) and thisModel and (chain=c)
and not aPn2 and not aPn3}
rotateselected @aPn1 @aPn2 @{-kPSI - 60.6 + pb}
# Make the peptide bond
connect @aNn @aPn2
refresh
}
# Step new and previous N
pn = nn
nn = gN
} # endfor i
# Add terminal O
gA = "data \"append aa\"\n" # global PDB atom record
gA += gen_atom(" OXT", g3from1[gSeq[gResno+gSeq.count]],
gResno+gSeq.count, [ -2.142, 2.057, 0.574])
gA += "end \"append aa\""
script inline @{gA}
refresh
connect
var xx = {(element="Xx") and thisModel and (chain=c)}
for (var i = 1; i <= xx.size; i++) {
connect 1.8 {(atomindex=@{xx[i].atomIndex}) and thisModel and (chain=c)}
}
# Clean up
connect ([UNK].CA) ([UNK].Xx and within(group, _1) and thisModel and (chain=c))
select (thisModel)
fix none
print format("%d atoms generated", gN-1)
appendNew = gAppendNew
pdbAddHydrogens = gPdbAddHydrogens
}
catch {
print "error"
}
}
function plico_gen_pp {
print "Generating Alpha Helix..."
# Get the sequence from the user
gSeq = prompt("Enter AA sequence (<+A:><n...>[A-Z]...)", "")%9999%0
if ((gSeq != "NULL") and (gSeq.count > 0)) {
print format ("Sequence=%s phi=%d psi=%d", gSeq, kPHI, kPSI)
plico_gen_alpha(gSeq)
}
}
# end of ribozome.spt
In a webpage
(Updated to RIBOZOME v1.16 script, now works both in Jmol-Java and JSmol-HTML5)
Sequence input is managed from the webpage. In addition, the helix parameters (which are fixed in the original script) may be changed in the page by a user. The model is generated and displayed in a Jmol object within the page (JmolApplet or JSmol HTML5 object).
See it in action
