PLoS: Difference between revisions
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===<div style="background-color:#eeecde; margin-top:0px;border-bottom: 1px dotted #999999; padding-top:3px;font-weight:normal;">'''Case 3:''' Structure alignment (≥ novice/intermediate)</div>=== | ===<div style="background-color:#eeecde; margin-top:0px;border-bottom: 1px dotted #999999; padding-top:3px;font-weight:normal;">'''Case 3:''' Structure alignment (≥ novice/intermediate)</div>=== | ||
[[File:Overlay03.png|200px|thumb|left|Overlay of alpha-carbon traces]] | [[File:Overlay03.png|200px|thumb|left|Overlay of aligned alpha-carbon traces]] | ||
An overlay of five simvastatin synthetase crystal structures illustrating degrees of hinge closing imparted by ligand binding (PDB IDs 3HLB, 3HLC, 3HLE, 3HLF, and 3HLG). Hinge motion in this two-domain enzyme is highlighted by superimposing only atoms in one of the domains (depicted in gray in this figure). The range of motion is highlighted by the rainbow colors assigned to the upper domain. The orientation of the molecule is chosen to make the range of motion evident (hinge axis is normal to the plane of the page). Each of the structures is labeled explicitly in the figure, rather than burying the information in the figure legend. Color coding the labels makes it easier to comprehend how each ligand affects the hinge motion. The structures are represented as a alpha-carbon trace rather than a cartoon ribbon because the motion is relatively small and the alpha carbon trace allows a more exact representation of the position of the atoms. | An overlay of five simvastatin synthetase crystal structures illustrating degrees of hinge closing imparted by ligand binding (PDB IDs 3HLB, 3HLC, 3HLE, 3HLF, and 3HLG). Hinge motion in this two-domain enzyme is highlighted by superimposing only atoms in one of the domains (depicted in gray in this figure). The range of motion is highlighted by the rainbow colors assigned to the upper domain. The orientation of the molecule is chosen to make the range of motion evident (hinge axis is normal to the plane of the page). Each of the structures is labeled explicitly in the figure, rather than burying the information in the figure legend. Color coding the labels makes it easier to comprehend how each ligand affects the hinge motion. The structures are represented as a alpha-carbon trace rather than a cartoon ribbon because the motion is relatively small and the alpha carbon trace allows a more exact representation of the position of the atoms. | ||
Revision as of 19:02, 30 December 2009
Biomolecular Graphics: In Principle and in Practice
Overview, general notes
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Figures
This section illustrates the figure-creation process, from initial conception → final multi-panel figure ready for publication. Organized as various "case studies" that are representative of the tasks typically faced by structural or computational biologists, this section provides several step-by-step examples. These examples are entirely self-contained, and the materials include everything from (i) raw, starting data (e.g., PDB files) to (ii) actual, working PyMOL or Python scripts and (iii) final output image files.
Case 1: Overall fold / domain level (≥ novice/intermediate)
Illustration of the overall fold of carbonic anhydrase, CsoS3, from Halothiobacillus neapolitanus.(PDB ID 2G13). The three domains that compose this enzyme are distinguished by coloring each domain separately (blue, yellow, red). The orientation was chosen to feature the location of the active site (outlined by side chains and zinc ion), and to show the two-fold symmetry relationship between the active domain (yellow) and homologous but defunct domain (red). SSEs are labeled directly on the individual SSEs. Domain labels are colored to correspond to the domains they are labeling. Labels in the active site are given an “outer glow” to make them legible in a region of the figure that is dense in detail. Depth is conveyed by use of fog, veiling less important structural features in the back of the enzyme.
#BEGIN PYMOL SCRIPT for left half of stereo image # antialias =1 smooths jagged edges, 0 turns it off set antialias = 1 # Larger values of ambient make the image brighter set ambient=0.3 # Larger values of direct eliminates shadows set direct=1.0 set ribbon_radius =0.2 # cartoon_highlight_color will give a separate color to edges of secondary structural elements. set cartoon_highlight_color =grey50 # ray_trace_mode=1 makes a black outline around the secondary structural elements set ray_trace_mode=1 # stick_radius -adjust thickness of atomic bonds set stick_radius = 0.2 # mesh_radius -to adjust thickness of electron density contours set mesh_radius = 0.02 # bg_color --set the background color bg_color white # load pdb file and give it an object name load csos3_18o_nobreak.pdb, csos3 # hide nonbonded atoms (i.e. waters) hide nonbonded # show cartoon ribbons show cartoon # Hide the default line representation of atomic bonds hide lines # Use standard helix, strand, and loop representations # other possibilities: cartoon loop, cartoon rect, # cartoon oval, and cartoon tube set cartoon_tube_radius, 0.2 # If you dont have secondary structure assignments # in the PDB header then get secondary structure assignments # from dssp http://swift.cmbi.kun.nl/gv/dssp/ # Then convert assignments into a PDB header # http://structure.usc.edu/dssp2pdb/ # If you want to define secondary structure manually, # Use the following syntax 'S'=strand 'H'=helix # alter B/753:758/, ss='S' # Make fancy helices with ridge on the edges like # molscript does # 1 is on. 0 is off. set cartoon_fancy_helices=1 set cartoon_cylindrical_helices=0 # Make the strands flat=1 or pass through CA positions=0 # Set to 0 when showing side chains from a strand set cartoon_flat_sheets = 1.0 # Draw the loops smooth=1 or pass through CA positions=0 # Set to 0 when showing side chains from a loop set cartoon_smooth_loops = 0 # Set the color of the residues # to find the names of the colors available # click on the rainbow colored square in the # upper right corner of the graphics window # Here I make some customized colors as mixtures of red,green,blue set_color maarine= [0.3, 0.8, 1.0] set_color graay=[0.8,0.8,0.8] set_color greeen=[0.0,0.5,0.0] color gray50, elem C color greeen, elem ZN color blue, resid 38:147 and name ca color yellow, resid 148:397 and name ca color red, resid 398:514 and name ca # Show spheres for chloride ions show spheres, elem ZN # Show sticks for bonds show sticks, (resid 173 or resid 175 or resid 177 or resid 242 or resid 253) and not (name n or name c or name o) set_view (\ 0.091340274, -0.606698275, 0.789650559,\ -0.991202235, -0.131515890, 0.013612081,\ 0.095602803, -0.783963323, -0.613382638,\ 0.001799395, 0.001679182, -246.492980957,\ 12.976243019, 41.245639801, 62.928291321,\ 187.538497925, 249.492980957, 0.000000000 ) turn y, 3.5 viewport 1200,1500 ray png csos3-left.png
Case 2: Ligand-binding sites (≥ novice/intermediate)
Illustration of the active site of dUTPase from Mycobacterium tuberculosis (PDB ID 1SIX). The orientation of the active site was chosen to feature the geometry of the chemical reaction catalyzed by this enzyme, specifically the in-line nucleophilic attack of water 212 on the alpha-phosphate of dUTP. Fine tuning of the orientation was made to eliminate overlap of side chains and to make all hydrogen bonds (dashed lines) visible. Only side chains directly involved in catalysis are depicted. Carbons are colored according to five conserved motifs of the dUTPase family. Non-conserved residues are given an undistracting gray color and are veiled in fog. Labels were colored to correspond to the side chains they are labeling.
#BEGIN PYMOL SCRIPT for Active Site set mesh_radius = 0.01 set antialias = 1 set stick_radius = 0.22 set dash_radius=0.07 set sphere_scale= 0.22 set ribbon_radius =0.1 set direct =0.0 set cartoon_fancy_helices=1 bg_color white set gamma=1.5 util.ray_shadows('none') set ray_trace_mode=1 # load pdb and map file load dumpnpp_10t.pdb, mtb cartoon automatic show cartoon hide nonbonded hide lines color white, (chain A or chain B or chain C) and (n;ca) color yellow, (resid 171) or (n;PA) or (n;PB) or (n;PG) color white, (elem C) #magnesium show sphere, (resid 171) color green, (resid 171) #waters show sphere, (resid 173:175 or resid 212) show sticks, (chain C and resid 170) color marine, (resid 22:32 and elem C) and chain C color green, (resid 57:76 and elem C) and chain C color yellow, (resid 77:93 and elem C) and chain A color orange, (resid 102:115 and elem C) and chain C color red, (resid 134:145 and elem C ) and chain B show sticks, (chain A and resid 83 and not n;n,c,o ) show sticks, (chain A and resid 86 and not n;n,c,o ) show sticks, (chain A and resid 77 and not n;n,c,o ) show sticks, (chain C and resid 24 and not n;n,c,o) show sticks, (chain C and resid 28 and not n;n,c,o) show sticks, (chain B and resid 140 and not n;n,c,o) show sticks, (chain C and resid 64 and not n;n,c,o) show sticks, (chain C and resid 113 and not n;n,c,o) show sticks, (chain C and resid 64:66 ) hide sticks, (chain C and resid 64 and n;n,c,o) show sticks, (chain A and resid 91 and n;n,c,o,ca) distance (resid 171 and chain C), (resid 173 and chain C) color green, dist01 distance (resid 171 and chain C), (resid 174 and chain C) color green , dist02 distance (resid 171 and chain C), (resid 175 and chain C) color green , dist03 distance (resid 171 and chain C), (resid 170 and chain C and n;O1A) color green , dist04 distance (resid 171 and chain C), (resid 170 and chain C and n;O1B) color green , dist05 distance (resid 171 and chain C), (resid 170 and chain C and n;O1G) color green , dist06 distance (resid 173 and chain C), (resid 28 and chain C and n;OD2) color marine, dist07 distance (resid 174 and chain C), (resid 28 and chain C and n;OD1) color marine, dist08 distance (resid 175 and chain C), (resid 24 and chain C and n;OD2) color marine, dist09 distance (resid 212 and chain A), (resid 170 and chain C and n;PA) color red, dist10 distance (resid 212 and chain A), (resid 113 and chain C and n;OE1) color orange, dist11 distance (resid 212 and chain A), (resid 83 and chain A and n;OD2) color yellow, dist12 distance (resid 113 and chain C and n;ne2), (resid 170 and chain C and n;O3A) color orange, dist13 distance (resid 65 and chain C and n;N), (resid 170 and chain C and n;O3A) color green, dist14 distance (resid 65 and chain C and n;OG), (resid 170 and chain C and n;N2A) color green, dist15 distance (resid 66 and chain C and n;N), (resid 170 and chain C and n;O3B) color green, dist16 distance (resid 64 and chain C and n;NH2), (resid 170 and chain C and n;O1B) color green, dist17 distance (resid 64 and chain C and n;NE), (resid 170 and chain C and n;O1B) color green, dist18 distance (resid 83 and chain A and n;OD2), (resid 170 and chain C and n;O3') color yellow, dist19 distance (resid 140 and chain B and n;NH1), (resid 170 and chain C and n;O2G) color red, dist20 distance (resid 140 and chain B and n;NH2), (resid 170 and chain C and n;O1G) color red, dist21 distance (resid 140 and chain B and n;NE), (resid 24 and chain C and n;OD1) color red, dist22 distance (resid 140 and chain B and n;NH2), (resid 24 and chain C and n;OD2) color red, dist23 distance (resid 170 and chain C and n;O4), (resid 77 and chain A and n;ND2) color yellow, dist24 distance (resid 170 and chain C and n;N3), (resid 91 and chain A and n;O) color yellow, dist24 distance (resid 170 and chain C and n;O2), (resid 91 and chain A and n;N) color yellow, dist24 hide labels set cartoon_flat_sheets = 1.0 set cartoon_smooth_loops = 0 set_view (\ 0.045321193, 0.677332938, -0.734195530,\ 0.631984174, -0.588606596, -0.504004478,\ -0.773574233, -0.441189915, -0.454773396,\ 0.000917640, 0.000133177, -65.177696228,\ 14.812702179, 8.131608009, 17.861175537,\ 54.978454590, 79.653022766, 0.000000000 ) # ray 1500,1500 viewport 700,800
Case 3: Structure alignment (≥ novice/intermediate)
An overlay of five simvastatin synthetase crystal structures illustrating degrees of hinge closing imparted by ligand binding (PDB IDs 3HLB, 3HLC, 3HLE, 3HLF, and 3HLG). Hinge motion in this two-domain enzyme is highlighted by superimposing only atoms in one of the domains (depicted in gray in this figure). The range of motion is highlighted by the rainbow colors assigned to the upper domain. The orientation of the molecule is chosen to make the range of motion evident (hinge axis is normal to the plane of the page). Each of the structures is labeled explicitly in the figure, rather than burying the information in the figure legend. Color coding the labels makes it easier to comprehend how each ligand affects the hinge motion. The structures are represented as a alpha-carbon trace rather than a cartoon ribbon because the motion is relatively small and the alpha carbon trace allows a more exact representation of the position of the atoms.
#BEGIN PYMOL SCRIPT for Overlay of Aligned Molecules #Load the individual, superimposed molecules load lovd_c2_refmac10-b_lsq.pdb, G0-Se load lovd-gx27_refmac11_lsq.pdb, G5 load lovd_gx27-s76a-mja_aps-refmac3_lsq.pdb, G5-S76-MJA load lovd-gx27-s76a-sim-aps_refmac6_lsq.pdb, G5-S76-Sim load lovd-gx27-s76a-lov-aps_refmac6.pdb, G5-S76-Lov hide everything show ribbon set ray_trace_mode=0 color red, G0-Se color orange, G5 color yellow, G5-S76-MJA color limegreen, G5-S76-Sim color blue, G5-S76-Lov color gray, resid 1:92 or resid 204:413 set ribbon_radius=0.3 show sticks, resid 134 and not (name C or name N or name O) show sticks, resid 86 and not (name C or name N or name O) show sticks, resn 803 show sticks, G5-MJA and resid 501 show sticks, resid 320 and not (name C or name N or name O) and ( G5-S76-Sim or G5-S76-Lov) show sticks, resid 334 and not (name C or name N or name O) and ( G5-S76-Sim or G5-S76-Lov) show spheres, resid 320 and (name od1 or name od2) and G5-S76-Sim show spheres, resid 334 and (name cg1 or name cg2) and G5-S76-Sim color red, elem o set sphere_transparency=0.5 set ray_shadow=off bg_color white viewport 1071,1051 set_view (\ 0.836338997, 0.441327691, -0.325210959,\ 0.390257686, -0.062672906, 0.918569088,\ 0.385009199, -0.895153403, -0.224648848,\ -0.000003189, 0.000000304, -189.126144409,\ 1.563406944, 17.993612289, -24.687477112,\ 171.387252808, 203.264083862, 0.000000000 ) ~
Case 4: Volumetric data (≥ intermediate)
Case 5: Interfaces (≥ intermediate)
Case 6: Higher-order structures (≥ intermediate/advanced)
Case 7: Animations (≥ intermediate/advanced)
See the Animations section below.
Case 8: Best-fit planes (≥ advanced)
Animations
A classification scheme
MsVs
These are just 'ordinary', static figures, as illustrated by the case studied above.
MsVd
MdVs
MdVd
Useful links
A compilation of links and other online resources that were helpful in creating these examples. Please edit as you see fit.