Here is some stuff from my last lab [1]. The objective was to do force field calculations (with CHARMM) on our protein of choice. What I picked is Ribonuclease A, the enzyme that digests RNA in our food.
Ribonoclease A is a sturdy little molecule with 124 amino acids. Its four disulfide bridges (yellow in the picture) make it very stable and comparably easy to isolate. Just 124 amino acids also makes it nice for computations. The pictures were made with VMD which makes nice pictures and is also a pretty versatile tool that reads tons of file formats.
The active group of Ribonuclease A comes from two Histidine (black) residues that help hydrolizing the phosphate in the nucleic acid. Lysine (orange) provides the positive charge to interact with negatively charged phosphate groups.
The first thing you can do with a molecular structure is an energy minimization. These are the Cα traces of the crystal structure (yellow) and the vacuum optimized structure (red). They are in fact quite different even though the red structure is just the next local minimum.
The major problem with this optimization is that I did not include solvent effects. The electrostatic interaction energy (in the macroscopic limit) is given by
The crucial part is εr, the relative dielectric constant of the medium. In water εr=78. In other words: charges are strongly shielded compared to a vacuum. In the microscopic world things aren't as simple but it is still the same trend. The difference is probably a major reason why the structures are so different.
Another thing you can do with structures is normal mode analysis. That means computing the eigenvalues/eigenvectors of the mass weighted energy Hessian matrix which correspond to the frequencies/motions of the normal modes. Ribonuclease A is small for a protein but it still has 1856 atoms. So we have 3x1856=5568 degrees of freedom. We have to compute, store and process about 30 million matrix elements. This seems much but these days most regular computers will be able to do this in less than half an hour. 30 million matrix elements corresponds to something like 300 MByte, nothing too crazy. [2]
These are the three lowest frequency modes (aside from translation and rotation) of Ribonuclease A. They are large scale backbone motions. A weak force constant and a high effective mass causes them to have wave numbers below 10/cm.
[1] Not the kind of lab where you need a lab coat.
[2] Actually if you are just interested in a few eigenvalues and -vectors, you can go much higher. For example multi-reference configuration interaction with Columbus (which is a great program by the way....): finding the first 4 states out of a 8569890 x 8569890 matrix was possible within about 17 hours. In this case you don't store trillions (7E13) of matrix elements and do a diagonalization. You use the iterative Davidson procedure which will find an eigenvector close to a starting guess.
Nonadiabatic Dynamics: Pushing Boundaries Beyond the Ultrafast Regime
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Long timescale dynamics are possible but still challenging. In brief: Our
latest work, coordinated by Saikat Mukherjee and published in the Journal
of Chem...
5 days ago
5 comments:
hey!
which methods do you apply? it's nice to see what you can treat, but what about the results? AFAIK there is no ab initio method that does such a hessian...
Greetins
Till
hi! it was regular molecular mechanics in CHARMM (standard settings, all atom force field) - I tried to sketch that in the first sentence
i don't really have any experience with force fields but it seems like you get some nice results. but of course it depends on what you want to do. for chemical reactions, excited states, unusual structures etc. you need quantum mechanics
but that's not possible for such a large system. what you could do though is QM/MM hybrid methods if you want to treat a part of the system very accurately
you are a live saver. you just explained the ribonuclease A to me better than my teacher did. thanks
you have explained the enzyme really thoroughly thanks
i am glad i could help :)
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