OVERVIEW OF THE OPEN SOURCE MOLECULAR VIEWERS

E. MALIKOVA

National Research Nuclear University "MEPhI", Moscow, Russia

malikova@sv-journal.com

 

Contents:

• Introduction
• 1. PyMOL
  • 1.1. Overview
  • 1.2. Acceptable molecular file formats
  • 1.3. PyMOL Main Features
  • 1.4. Program integration, plugins and scripts
  • 1.5. Gallery
• 2. Jmol
  • 2.1. Overview
  • 2.2. Acceptable molecular file formats
  • 2.3. Jmol Main Features
  • 2.4. JmolApplet integration
  • 2.5. Gallery
• 3. OpenAstex
  • 3.1. Overview
  • 3.2. Acceptable molecular file formats
  • 3.3. Main Features
  • 3.4. Gallery
• 4. Molekel
  • 4.1. Overview
  • 4.2. Acceptable molecular file formats
  • 4.3. Main Features
  • 4.4. Gallery
• 5. MacMolPlt
  • 5.1. Overview
  • 5.2. Acceptable molecular file formats
  • 5.3. Main Features
  • 5.4. Integration
  • 5.5. Gallery
• 6. Conclusions
• 7. References

 

Introduction

In this short communication we offer you a brief overview over some open source molecular viewers. Some of this molecular viewers can be used for analyses of the results of computer modelling of nanostructures, obtained with help of quantum chemistry packages ( for example, the General Atomic and Molecular Electronic Structure System (GAMESS) - free for use a general ab initio quantum chemistry package). Some are good for not only vieweing molecular structures, but also for giving live 3D Presentations and sharing interactive visualizations. Some support exporting geometry to such well-known formats of 3d computer graphics as VRML, OBJ, Pov-Ray and so on, so the results obtained can be imported and used in such programms of 3ds Max, Maya, Pov-ray for producing high quality films, video and graphic content.

All this viewers take advantages of open source programms, so their users have the right to modify, improve them and use them in any way in their professional work.

Below are described some open source molecular viewers. Their main features are presented, results of molecular structures visualization obtained with them are presented.

1. PyMOL

Overview

PyMOL [1] is a molecular visualization program provides functionality not only for viewing molecules, but also is capable of generating high resolution images for publishing or printing, making movies, can be used for giving live 3D Presentations and sharing interactive visualizations. PyMOL is a free cross-platform molecular graphics system made possible through recent advances in hardware, internet, and software development technology.  PyMOL provides most of the capabilities and performance of traditional molecular graphics packages written in C or Fortran. However, its integrated Python interpreter endows it with features and expandability unmatched by any traditional package [2].

Here is what PyMOL's creator, Warren L. DeLano, Ph.D. wrote about it's advantages [3]:

"... In the long run, PyMOL aims to match the molecular graphics quality of Molscript/Raster3D, the molecular editing capabilities of MacroModel, the animations and performance of VMD, the electrostatic surfaces of Grasp, the macromolecular crystallography of O, the interactivity of Sculpt, and the programmability of M.O.E. (but using Python instead of SVL), all in one FREE & UNRESTRICTED OPEN-SOURCE package. If you haven't yet seen PyMOL in action recently, you will be surprised how far it has progressed toward this goal... "

PyMOL currently holds a large percentage of the high-quality images published in scholarly journals like Science and Nature (fig. 1) .

Fig.1

It should be remarked that a part of PyMOL's popularity comes from the fact that it is very flexible and it offers arbitrarily high-resolution images as output. This makes this program a great tool for making journal covers or any press-related images . Some of the known PyMOL-created Journal Covers of 2009-2008 year are represented at fig.2.

Crystal structure of the catalytic domain of the mitotic checkpoint kinase Mps1 in complex with SP600125. Chu ML, Chavas LM, Douglas KT, Eyers PA, Tabernero L. J Biol Chem. 2008 Aug 1;283(31):21495-500. Epub 2008 May 14.	Allosteric motions in structures of yeast NAD-specific isocitrate dehydrogenase. J. Biol. Chem.	How a multicopper oxidase chooses its electron transfer partner. Acc. Chem. Res.	Crystal structure of the yeast nicotinamidase Pnc1p. Arch. Biochem. Biophys.	Philosophical Transactions of The Royal Society, B : Biological Sciences Jan, 2009
MD simulation of protein-protein binding Pymol generated Movie is avialable inside pdf or high quality AVI format	J. Chem. Inf. Model., 2008, 48 (10)	Protein Dynamics	Targeting DNA, BIOCHEMIE, July 1, 2008 Cover, Vol. 90.	Harnessing Helices, Chemical & Engineering News, June 2, 2008 Cover, Vol. 86, Issue 22

 

Programm’s official site:

http://www.pymol.org/

Acceptable molecular file formats

Some of PyMOL supported file formats are:

• PDB - Protein Data Bank
• CIF - Crystallographic Information File
• CCP4 - The file format for electron densitym, a standard in X-ray crystallography and Cryo-electron microscopy where the result of the technique is a three-dimensional grid of voxels each with a value corresponding to density of electrons.
• XYZ - Minnesota Supercomputer Institute XMol file
• Gaussian CUBE
• MOL/MOL2 - Elsevier MDL structure
• MOE - Chemical computing Group M.O.E.
• SDF - Elsevier MDL structure
• GRD - Accelrys Insight II Grids

PyMOL Main Features

PyMol can be used for:

·        Viewing 3D Molecular Structures

·        Modeling and editing structures

·        Editing Atoms

·        Molecular sculpting

·        Homology modeling

·        Animating Molecules Dynamically

·        Making high quality images and movies

o       Image Manipulation

o       Labels

o       Photoshop/GIMP

o       Stereo Figures

o       Publication-quality images

 

Program integration, plugins and scripts

PyMOL supports geometry export in following formats: VRML, IDTF,   PovRay . So it can be used with such programms as 3ds Max and Pov-ray.

PyMOL can be integrated seamlessly with MS Powerpoint with help of Axpymol [4]- PyMOL ActiveX control.

PyMOL Plugins are user-developed modules that extend PyMOL's capabilities via the Tcl/Tk user interface. Among them are:

• CAVER

CAVER [5] provides rapid, accurate and fully automated calculation of pathways leading from buried cavities to outside solvent in protein structures. Study of these pathways is important in drug design and molecular enzymology. On the moment of writing this short communication CAVER wax available as online version or PyMOL plugin - CAVER Viewer that enables efficient visualization of calculated pathways and can be run online using Java Web Start technology.

• GPSSpyMOL

GPSSpyMOL plugin for visualizing surfaces and voids using the CASTp algorithm [6].
 

Gallery

Below are represented some results of molecular structures visualization (static and animation) obtained with Pymol.

Static

Animation

 

 

2. Jmol: an open-source Java viewer for chemical structures in 3D with features for chemicals, crystals, materials and biomolecules

 

Overview

On it's official site Jmol project programms [7] are described as a free, open source tools for molecule vieweing for students, educators, and researchers in chemistry and biochemistry. They are licensed under the GNU Lesser General Public License and are cross-platform, running on Windows, Mac OS X, and Linux/Unix systems. Jmol project offers 3 program tools (Applet, Application, and Systems Integration Component ):

• The JmolApplet is a web browser applet that can be integrated into web pages.
• The Jmol application is a standalone Java application that runs on the desktop.
• The JmolViewer is a development tool kit that can be integrated into other Java applications.

We'll stop on the first one - JmolApplet. The JmolApplet is a web browser applet that can be integrated into web pages. It should be remarked that this applet supports it's special scripting language - Jmol Scripting Language (JavaScript support library ) and also supports RasMol/Chime scripting language, what gives an opportunity to build complex graphical web interfaces on the base of this applet . This also means that the applet can be integrated into different web applications.

Program's official site:

http://jmol.sourceforge.net/

Acceptable molecular file formats

The list of supported by Jmol Applet files is quite impressive. Some of them:

• CIF/mmCIF - Crystallographic Information File and Macromolecular Crystallographic Information File, the standards from the International Union of Crystallography
• CML - Chemical Markup Language
• CSF - Fujitsu CAChe chemical structure, now Fujitsu Sygress
• CTFile - Elsevier MDL chemical table
• GAMESS - General Atomic and Molecular Electronic Structure System output, Gordon Research Group, Iowa State University
• Gaussian 94/98/03 output - Gaussian, Inc.
• HIN - HyperChem from Hypercube, Inc.
• Jaguar - Schrodinger, LLC
• MM1GP - Ghemical molecular mechanics
• MOL - Elsevier MDL structure
• MOLPRO - Molpro output
• NWCHEM - NWChem output, Pacific Northwest National Laboratory
• odydata - Odyssey data, WaveFunction, Inc.
• PDB - Protein Data Bank, Research Collaboratory for Structural Bioinformatics
• QOUT - Q-Chem, Inc.
• SDF - Elsevier MDL structure
• SHELX - Structural Chemistry Department, University of Göttingen ( Germany )
• SMOL - Spartan data, Wavefunction, Inc.
• spinput - Spartan data, Wavefunction, Inc.
• xodydata - Odyssey XML data, WaveFunction, Inc.
• XYZ - Minnesota Supercomputer Institute XMol file
• XYZ+vib - XYZ format files with added vibrational vector information
• XYZ-FAH - Folding@home XYZ file

 

Jmol Main Features

• Multi-language
• Translated into multiple languages: Catalan (ca), Czech (cs), Danish (da), Dutch (nl), Estonian (et), French (fr), German (de), Hungarian (hu), Italian (it), Korean (ko), Norwegian Bokmal (nb), Polish (pl), Portuguese (pt), Portuguese - Brazil (pt_BR), Russian (ru), Spanish (es), Swedish (sv), Turkish (tr) (in addition to the native English, en-US).
• Automatically adopts the language of the user's operating system, if it is among the translations available. You can change to another language if desired.
• Supports practically all major web browsers:
• Internet Explorer (Win32)
• Mozilla and Firefox (Win32, OSX, Linux, Unix)
• Safari (Mac OS X)
• Opera 7.5.4 (Win32 only)
• High-performance 3D rendering with no hardware requirements, including stereo rendering
• Animations

• Vibrations
• Basic support for unit cell and symmetry operations
• Schematic shapes for secondary structures in biomolecules
• Measurements
• distance
• angle
• torsion angle
• Exports to .jpg, .png, .ppm, .pdf

JmolApplet integrations

Jmol Applet can export it's graphical scenes in such formats as PovRay, VRML, Maya. So integration with 3DS Max, Maya and PovRay is possible.

Here are examples of it's integration in web-based courseware and web-accessible chemical databases:

• Moodle [8] is an open-source course management system. A third-party Jmol filter [9] automatically converts links to molecular model files (.mol, .csmol, .pdb, .xyz, .cml) in Moodle documents into embedded Jmol models. Jmol models can also be added as resources, or placed in searchable databases that students can edit.
• 3D-Structures in Organic Chemistry, of Achiral and Chiral Molecules and Animations in Vibrational Spectroscopy [10] - Models and structures related to teaching basic organic chemistry, structures visualizing different types of chirality and structures and animations used to visualize vibrational frequencies in IR spectroscopy (DE) - PD Dr. Stefan Immel
• CDK Web [11]- Show case for functionality in the Chemistry Development Kit. The website uses Jmol for generated rendering 3D structures.

 

Gallery

Small molecules

Acetic acid using CPK colors and spacefilled atoms.	A shaded rendering of caffeine, with some measurements shown (distance, angle, dihedral).
Display of bounding box and axes of coordinates space. Note the transparency of the yellow halo around selected atoms.

Macromolecules

.
A few residues with backbone in blue and vdw dots surface		Hemoglobin with backbone trace colored by chain and spacefilled hemes.

 

 

3. OpenAstexViewer 3.0 - Software for molecular visualisation.

Overview

OpenAstexViewer [12] can be used as an Applet in a web page or as a desktop application. It's written in Java and should run on most operating systems and in most internet browsers.AstexViewer™ was originally developed by Mike Hartshorn at Astex Therapeutics between 1999 and 2007. The software was shaped by the input of many people from the structural biology and computational chemistry groups at Astex Therapeutics:

• Version 1 was made available via the Astex Therapeutics web site and published in JCAMD from 2002.
• Version 2 was made available via the website from 2004.

 

OpenAstexViewer is distributed in Open Source form under the terms of the LGPL license.

It should be remarked that althogh program can be used as an applet it's quite large to be integrated in the Internet applications (more than 2 mb, so it takes it a remarkable amount of time to be loaded).

 

Program's official site http://openastexviewer.net/web/

 

Acceptable molecular files

Among files that Viewer supports are:

• CCP4 - Electron density map (with extension .map)
• PDB - Protein Data Bank
• MOL - Elsevier MDL structure

Main Features

Some functionality includes

• Graphical interface
• Sphere, cylinder and stick display styles for molecules.
• Versatile labelling and distance monitors.
• Shaded molecular surfaces, with transparency and property mapping.
• Protein schematics and secondary structure assignment.
• High quality image production to arbitrary resolution, with antialiasing and shadows.
• Measurements
• Writes images (BMP)

 

Gallery

 

4. Molekel

Overview

Molekel [13] is a multi-platform molecular visualization program that supports modern User Interface and graphic hardware. The program is developed and tested on the following platforms:

• SuSE Linux 10.3, Fedora Core 8 x86 32bit
• Red Hat Enterprise 4 x86 64bit
• Microsoft Windows XP/2000
• Apple Mac OS X 10.4 Intel and PowerPC G5

It should be remarked that this program takes advantages of VTK - Visualization toolkit, the object-oriented c++ library, that lies in it's core. So the quality of visualization rezults that can be obtained is quite high.

 

Program's official site http://molekel.cscs.ch/wiki/pmwiki.php

Acceptable molecular file formats

The program is realised also on the base of such c++ library as OpenBabel - a chemical toolbox designed to speak the many languages of chemical data, that can read, write and convert over 90 chemical file formats [14]. So the program can read practically all file formats that OpenBabel supports and even more ( for example Molekel developers realized functionality for propper reading GAMESS molecular orbitals information, as OpenBabel can't do it) . Some of this file formats are:

• CIF - Crystallographic Information File
• CML - Chemical Markup Language
• GAMESS Input
• GAMESS Output
• Gaussian 94/98/03 output - Gaussian, Inc.
• HIN - HyperChem from Hypercube, Inc.
• MOL - Elsevier MDL structure
• NWO - NWChem output
• PDB - Protein Data Bank
• XYZ

 

Main features

• Read molecular data from different file formats
• Display molecules with different styles:
• Spacefill
• Ball and Stick
• Ball and Wire
• Stick
• Backbone (Residues)
• Ribbon (Residues)
• Schematic (Residue)
• Change atom and bond size
• Read atom colors from file
• Display dipole moment (for molecular formats containing this information)
• Animate atoms using the trajectory and vibration information available in some file formats
• Animate molecules read from multi-frame pdb and xyz files
• Display arrows to show the speed and direction of motion of each animated atom
• Animate molecular surfaces (while exporting amimation)
• Perform distance and (dihedral) angle computations
• Use a planar probe to visualize scalar fields (e.g. Electrostatic Potential) and display the value of the scalar field at a specific point in 3D space.
• Visualize molecular orbital iso-surfaces optionally color-coded with Electrostatic Potential.
• Visualize surfaces generated from density matrix optionally color-coded with Electrostatic Potential.
• Visualize surfaces from grid data (in Gaussian cube format or read from ADF tape41 files) optionally color-coded with Electrostatic Potential.
• Smooth surfaces generated from grid data (Gaussian .cube) with Laplacian smoothing
• Use grid data read from .cube files as molecular electrostatic potential to map onto SAS and SES surfaces
• Compute Solvent Accessible Surface as iso-surface optionally color-coded with Electrostatic Potential.
• Save print quality (>300 DPI) images
• Export to TIFF, PNG, PostScript and PDF
• Programmable shaders (GLSL) support
• Visualization of radiation spectra (infra-red and Raman)
• High-quality multi-pass rendering with anti-aliasing and correct rendering of multi-layered transparent surfaces
• Blending of vibrational modes
• Export high resolution images

Gallery

It should be mentioned that some of presented below graphical presentations were made with experimental version of Molekel.

Static

 

Animation

 

 

5. MacMolPlt

Overview

MacMolPlt is the graphic program that is extremely useful for showing GAMESS results. It was developed by Brett Bode specifically to show GAMESS results, such as orbitals, electron density, vibrational modes, and so on [15, 16]. Program source distribution primarily targeted at Linux and can be downloaded from it's official site [15].

 

Program's official site http://www.scl.ameslab.gov/MacMolPlt/

Acceptable molecular file formats

It should be remarked that programm reads a variety of file formats including any GAMESS input, log or IRC file directly to create animations of IRC's, DRC's, and optimizations. You may also import a $VEC group from any file (such as a GAMESS .DAT file).

Some of acceptable file formats are:

• GAMESS log files
• GAMESS irc files
• GAMESS input files
• MolPlt .mol files
• MolDen format files
  
• PDB - Protein Data Bank
• CML - Chemical Markup Language
• MDL - MolFiles
• XYZ

 

Main features

• A modern graphics program for plotting 3-D molecular structures and normal modes (vibrations). Modern means:
• Mouse driven interface for real-time rotation and translation.
• copy and paste functionality for interfacing to other programs such as word processors or other graphics programs (like ChemDraw).
• simple printing to color or black and white printers (publication quality).
• multiple files open at once.
• It reads a variety of file formats including any GAMESS input, log or IRC file directly to create animations of IRC's, DRC's, and optimizations. You may also import a $VEC group from any file (such as a GAMESS .DAT file). In addition xMol XYZ files, MolDen format files and Chemical Markup Language (CML) files are supported. Also some PDB file support and MDL MolFile support is included.
• Molecular point group symmetry is supported.
• You may also paste GAMESS and Gaussian-92 style cartesian coordinates directly into the program.
• Animation of Normal Modes.
• Animation of IRC's, and DRC's including orbitals.
• Simple Energy Plots (including geometrical parameters).
• Simple frequency line graph of frequency versus infrared or Raman intensity.
• Append multiple GAMESS files together to create a single animation.
• Build or modify molecules using the graphical molecule builder.
• Quickly build realistic 3D structures.
• rotate selected atoms about bonds, change bond or dihedral angles.
• translate and rotate selected subgroups.
• Build molecules from scratch using cartesian or internal coordinates
• 2D orbital, total electron density contour map display
• 3D molecular orbital, total electron density display
• density difference maps
• Molecular Electrostatic Potential Maps
• Simple GAMESS input (.inp) builder
• 3D color display with lighting and shading using OpenGL under MacOS X.

Integrations

Program can export it's graphical scenes in such formats as PovRay, VRML. So integration with 3DS Max and PovRay is possible.

Gallery

Below are a few samples created directly with MacMolPlt:

Simple Molecule Display with labels and displaying the bond angle:

Water with the C2v operators.


Quinone with a total electron density surface colorized with the molecular electrostatic potential value.

 

Conclusions

5 Open Source molecular viewers presented in this overview have their own advantages and disadvantages. The following comparison table can be given:

Molecular Viewer	Windows, Mac, Linux/UNIX support	Written in language	License	Quantum chemistry files support (Gamess OUT, DAT, IRC; Gaussian output, GUBE; CCP4 )	Scripting language	Graphic Ingerface/ comand panel	Internet/ local computer	Quality of rendering (good/high) (short communication author's opinion)
PyMOL	+, +, +	Fortran, C	BSDL	+(CUBE,CCP4)	Pyton	+ /+	-/+	h
Jmol Applet	+, +, +	Java	GNU LGPL	+ (CUBE,OUT,Gaussian 94/98/03)	JavaScript based scripting language	-/+	+/+	g
Astex	+, +, + (should be so as stated on official site)	Java	GNU LGPL	+(CCP4)	JavaScript based scripting language	+/-	+/+	h
Molekel	+, +, +	C++	GNU	+(CUBE,OUT,CCP4,Gaussian 98/03)	-	+/-	-/+	h
MacMolPlt	+, +, +	C++	Freeware	+(OUT, DAT)	-	+/-	-/+	g

 

References

1. http://www.pymol.org/
2. Warren L. DeLano, Ph.D., "PyMOL: An Open-Source Molecular Graphics",CCP4 Newsletter March 2002 (http://www.ccp4.ac.uk/newsletters/newsletter40/11_pymol.html)
3. http://www.chem.ac.ru/Chemistry/Soft/PYMOL.en.html
4. http://www.pymolwiki.org/index.php/Axpymol
5. http://loschmidt.chemi.muni.cz/caver/
6. http://sts.bioengr.uic.edu/castp/
7. http://jmol.sourceforge.net/
8. http://moodle.org/
9. http://docs.moodle.org/en/Jmol_filter
10. http://csi.chemie.tu-darmstadt.de/ak/immel/misc/oc-scripts/tutorials.html
11. http://www.ebi.ac.uk/Tools/cdkweb/
12. http://openastexviewer.net/web/
13. http://molekel.cscs.ch/wiki/pmwiki.php
14. http://openbabel.org/wiki/Main_Page
15. http://www.scl.ameslab.gov/MacMolPlt/
16.Bode, B. M. and Gordon, M. S. J. Mol. Graphics Mod., 16, 1998, 133-138.