lammps/tools/moltemplate/examples/CG_biomolecules/protein_folding_examples/1beadProtSci20104a1807d39739efficient_neuronet
lammps/tools/moltemplate/examples/CG_biomolecules/protein_folding_examples/1beadProtSci2010
4a1807d39739efficient_neuronet
1beadProtSci2010
1beadProtSci2010
README.TXT
README.TXT
# -------- REQUIREMENTS: ---------
# 1) This example requires the "USER-MISC" package. (Use "make yes-USER-MISC")
# http://lammps.sandia.gov/doc/Section_start.html#start_3
# 2) It also may require additional features and bug fixes for LAMMPS.
# be sure to download and copy the "additional_lammps_code" from
# http://moltemplate.org (upper-left corner menu)
# 3) Unpack it
# 4) copy the .cpp and .h files to the src folding of your lammps installation.
# 5) Compile LAMMPS.
This is an example of a very simple coarse-grained protein.
This example contains a 1-bead (C-alpha model) representation of the
"unfrustrated" 4-helix bundle model used in this paper:
G. Bellesia, AI Jewett, and J-E Shea, Protein Science, Vol19 141-154 (2010)
In this model, there are three atom-types (bead-types), H, L, and N
representing one amino-acid each. The "H" beads represent the hydrophobic
amino acids, and are attracted to eachother with a strength of "1.0"
(in dimensionless units of "epsilon"). The "L" and "N" atoms are
hydrophilic and purely repulsive, and only differ in their secondary-structure
propensity (ie their dihedral parameters).
The dihedral-interaction is bi-stable with two deep local minima (corresponding
to helix-like and sheet-like secondary structure). You can adjust the bias
in favor of one minima or another by modifying the angle-shift parameter in
the appropriate "dihedral_coeff" command in the other .lt file.
A definition for the 4-sheet beta-barell protein model is also included.
If you want to simulate that molecule instead, then edit the "system.lt"
file (in the "moltemplate_files" subdirectory), and replace this line:
prot = new 4HelixBundle
with
prot = new 4SheetBundle
-------------
Instructions on how to build LAMMPS input files and
run a short simulation are provided in other README files.
step 1)
README_setup.sh
step2)
README_run.sh
# 1) This example requires the "USER-MISC" package. (Use "make yes-USER-MISC")
# http://lammps.sandia.gov/doc/Section_start.html#start_3
# 2) It also may require additional features and bug fixes for LAMMPS.
# be sure to download and copy the "additional_lammps_code" from
# http://moltemplate.org (upper-left corner menu)
# 3) Unpack it
# 4) copy the .cpp and .h files to the src folding of your lammps installation.
# 5) Compile LAMMPS.
This is an example of a very simple coarse-grained protein.
This example contains a 1-bead (C-alpha model) representation of the
"unfrustrated" 4-helix bundle model used in this paper:
G. Bellesia, AI Jewett, and J-E Shea, Protein Science, Vol19 141-154 (2010)
In this model, there are three atom-types (bead-types), H, L, and N
representing one amino-acid each. The "H" beads represent the hydrophobic
amino acids, and are attracted to eachother with a strength of "1.0"
(in dimensionless units of "epsilon"). The "L" and "N" atoms are
hydrophilic and purely repulsive, and only differ in their secondary-structure
propensity (ie their dihedral parameters).
The dihedral-interaction is bi-stable with two deep local minima (corresponding
to helix-like and sheet-like secondary structure). You can adjust the bias
in favor of one minima or another by modifying the angle-shift parameter in
the appropriate "dihedral_coeff" command in the other .lt file.
A definition for the 4-sheet beta-barell protein model is also included.
If you want to simulate that molecule instead, then edit the "system.lt"
file (in the "moltemplate_files" subdirectory), and replace this line:
prot = new 4HelixBundle
with
prot = new 4SheetBundle
-------------
Instructions on how to build LAMMPS input files and
run a short simulation are provided in other README files.
step 1)
README_setup.sh
step2)
README_run.sh
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