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Team:EPF-Lausanne/Modeling/RunSimulation
From 2009.igem.org
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===Heating=== | ===Heating=== | ||
| - | When the protein is stable, we have to add heat (kinetic energy) to reach | + | When the protein is stable, we have to add heat (kinetic energy) to reach a higher temperature (~300°K). We have to take a special care not to add heat too fast, which would result in protein burst and explosion of our system. |
===First NPT=== | ===First NPT=== | ||
Revision as of 09:31, 23 July 2009
Contents |
How to run a complete simulation
Theory
The .pdb is generated from X-ray diffraction crystallography. This process requires a crystal of the protein, which occurs only at low temperature (~5°K). Taking this in consideration, we have to go through different steps to bring our protein to lab conditions.
Initial minimization
We start with a few minimization rounds, to reach a minmimum in the sense of potential energy.
Heating
When the protein is stable, we have to add heat (kinetic energy) to reach a higher temperature (~300°K). We have to take a special care not to add heat too fast, which would result in protein burst and explosion of our system.
First NPT
This is a relaxation step, with constant atom number, pressure and temperature. This is a kind of homogeneization of the distribution of atoms inside our box.
NVT
This is also a relaxation step, with constant atom number, volume and temperature.
Second NPT
Now we perform another relaxation NPT to reach lab conditions.
Final NPT
This is the final NPT, which ast much longer and gives us the ouput of the simulation.
.conf file
Initial minimization
This is quite easy to achieve, as NAMD has a specific keyword to run a simulation: minimize #OF_MINIMIZ_STEPS
Heating
We tried different protocol, but this one is the best: reassignTemp $temp_step ;# starting temp reassignIncr $temp_step ;# temp increment reassignHold 300 ;# final temp reassignFreq 100 ;# num timesteps to temp incr.
