NAMD, recipient of a 2002 Gordon Bell Award, is a parallel molecular dynamics code designed for high-performance simulation of large biomolecular systems. Based on Charm++ parallel objects, NAMD scales to hundreds of processors on high-end parallel platforms and tens of processors on commodity clusters using gigabit ethernet. NAMD uses the popular molecular graphics program VMD for simulation setup and trajectory analysis, but is also file-compatible with AMBER, CHARMM, and X-PLOR. NAMD is distributed free of charge with source code. You can build NAMD yourself or download binaries for a wide variety of platforms. Our tutorials show you how to use NAMD and VMD for biomolecular modeling.
NAMD reference paper: Scalable molecular dynamics with NAMD.
Spotlight: Bringing Oxygen into an Enzyme (Aug 2007)
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Because oxygen gas is very reactive, it is frequently employed by the cell as a reagent by proteins called enzymes, which build the organic compounds that the cell needs. One such enzyme belongs to the copper amine oxidase family. These proteins transform amine-containing compounds into molecules needed by the cell, by reacting the compounds with oxygen. Researchers have long been interested in finding out how the various reagents reach the buried copper active site before the final oxidation reaction can occur. While copper amine oxidases exhibit an obvious channel for capturing the amine compounds to be modified, it had been unclear until now how oxygen molecules make their way through the enzyme. With the help of computer simulations using NAMD, researchers have identified in a recent publication, the routes taken by oxygen inside various copper amine oxidases from different species. In order to accomplish this, they analyzed simulations of the motions of four copper amine oxidases, using the VMD analysis and visualization software, which can predict the probability of finding oxygen molecules anywhere inside the simulated proteins. This analysis found numerous oxygen conduction routes inside each copper amine oxidase, i.e., oxygen can enter the protein through many routes, as it would in a sponge. More information on finding O2 migration pathways in proteins can be found here.
Overview
Why NAMD? (in pictures)
Steered Molecular Dynamics
Interactive Molecular Dynamics
Features and Capabilities
Performance Benchmarks
Publications and
Citations
Credits and Development Team
Availability
Read the License
Download NAMD Binaries
(also VMD)
Build from Source Code
Run at NCSA, SDSC, PSC, Indiana, or Texas
NAMD in Scienomics Software
Training
Charm++ Workshop (May 1-3, 2008)
Cluster-Building Workshop (11/30-12/1, 2006)
Cluster-Building Workshops (3/16-17 & 4/20-21, 2006)
Frankfurt Hands-On Workshop (March 20-23, 2006)
Cluster-Building Workshops (9/22-23 & 11/10-11, 2005)
Older Workshops
Support
Contact the DevelopersAnnouncements
NAMD 2.6 (August 2006)
2005 User Survey Report
NAMD 2.5 (Sept. 2003)
NAMD 2.4 (Mar. 2002)
How to Cite NAMD
Previous Announcements
Documentation
Adaptive Biasing Force Website
Adaptive Biasing Force Calculations
Alchemical Free Energy Perturbation
Interactive Molecular Dynamics Tutorial
Related Codes, Scripts, and Examples
NAMD Wiki (Recent Changes)
Older Documentation
News
GPU Acceleration in Development
NCSA IACAT to Accelerate NAMD
Buckyball Bowling in Reno
TCBG Software at SC07
Parkinson's, Alzheimer's Diseases
Knock, Knock, Who's There?
Step Up to the BAR Domain
Protein Wranglers
Virus Simulated on SGI Altix
NAMD-G Paper Available
Managing Workflow with NAMD-G
Enzyme Antics
All in Your Brain
SPICE Wins HPC Analytics Challenge
Understanding the Protein Lock
Mechanosensitive Ion Channels
NAMD Wins Gordon Bell Award
Older News Items