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Suppose I have two PDB files (one of them is as follows)

ATOM      1  N   MET A   1      66.104  56.583 -35.505  
ATOM      2  CA  MET A   1      66.953  57.259 -36.531  
ATOM      3  C   MET A   1      67.370  56.262 -37.627  
ATOM      4  O   MET A   1      67.105  55.079 -37.531  
ATOM      5  CB  MET A   1      68.227  57.852 -35.867  
ATOM      6  CG  MET A   1      67.848  58.995 -34.899  
ATOM      7  SD  MET A   1      66.880  58.593 -33.421  
....      .  ..  ... .   .      ......  ......  ......
....      .  ..  ... .   .      ......  ......  ......

This file can be read in python using following script.

import sys
for fn in sys.argv[1:]:
   while 1:
      if not line: break
      if line[0:6]=='ATOM  ' :
         if line[21]=='A' :
            x.append(rx); y.append(ry); z.append(rz)
   for i in range(1,Nr-1):
      print fn, i, res[i], x[i], y[i], z[i]

Now I would like to generate the grid of N*N*N dimension and rotate and translate the molecule on the grid. The rotation and translation can be done by using FFT (Fast Fourier Transform).

I tried to write something like follows

import numpy as np
import fftw as fft

class Grid3D(object):

   def __init__(self, grid_dimension):
      x = y = z = grid_dimension
      self.grid = np.zeros([x, y, z], dtype=float)

All this is actually to perform docking of two molecules using 3d grid and FFT. I wanted to know how to proceed further or any better way?

share|improve this question

closed as not a real question by Jaime, Jan Dvorak, Sgoettschkes, mipe34, keyboardsurfer Apr 1 '13 at 19:05

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center. If this question can be reworded to fit the rules in the help center, please edit the question.

It's not clear what the specific question is here... –  Oliver Charlesworth Apr 1 '13 at 15:44
1 Center receptor coordinates at origin based on center of mass. 2.Center ligand coordinates at origin based on center of mass. 3.Select cubic grid size to contain centered molecules for FFT 4.Discretize receptor, assigning scores to 3D grid(s) of complex numbers 5.Rotate input ligand to random orientation 6.Rotate ligand to Euler angles from uniformly distributed set, and discretize 7.Perform 3D FFT to compute convolution between ligand and receptor grids, and select top scoring position from the resultant grid 8.Repeat steps 6–7 for a total of 3,600 ligand rotations (15° angular sampling) –  user2176228 Apr 1 '13 at 15:52
Is there a well known way to follow above procedure? –  user2176228 Apr 1 '13 at 15:53
You are using Python!! FOLLOW PEP-8!! Or in this case specifically THIS –  Pradyun Apr 1 '13 at 16:33
Your question is much too broad to be answered. I'd suggest you break it down into little bits, try to solve them yourself first, then come here for help if you get stuck. For a recommendation on a general procedure, you may be better off asking at SciComp. You may also want to google for ready-made python solutions, such as MMTK. –  Jaime Apr 1 '13 at 16:45

1 Answer 1

An answer to you first question, "How to read a pdb file"

If you want to end up with a numpy array, you can use numpy.genfromtxt which is very nice, and much easier to implement and use than your looped reading. It is also much more robust to spacing of the files, etc.

import numpy as np
data = np.genfromtxt('filename.txt',
        names = 'ATOM,index,res,MET,A,count,x,y,z',

Now data is a numpy "structured array", which can easily be accessed as follows:

In [13]: data
array([('ATOM', 1, 'N', 'MET', 'A', 1, 66.104, 56.583, -35.505),
       ('ATOM', 2, 'CA', 'MET', 'A', 1, 66.953, 57.259, -36.531),
       ('ATOM', 3, 'C', 'MET', 'A', 1, 67.37, 56.262, -37.627),
       ('ATOM', 4, 'O', 'MET', 'A', 1, 67.105, 55.079, -37.531),
       ('ATOM', 5, 'CB', 'MET', 'A', 1, 68.227, 57.852, -35.867),
       ('ATOM', 6, 'CG', 'MET', 'A', 1, 67.848, 58.995, -34.899),
       ('ATOM', 7, 'SD', 'MET', 'A', 1, 66.88, 58.593, -33.421)], 
      dtype=[('ATOM', 'S4'), ('index', '<i8'), ('el', 'S2'), ('MET', 'S3'), ('A', 'S1'), ('count', '<i8'), ('x', '<f8'), ('y', '<f8'), ('z', '<f8')])

In [14]: data['x']
Out[14]: array([ 66.104,  66.953,  67.37 ,  67.105,  68.227,  67.848,  66.88 ])

In [15]: data['y']
Out[15]: array([ 56.583,  57.259,  56.262,  55.079,  57.852,  58.995,  58.593])

In [16]: data['index']
Out[16]: array([1, 2, 3, 4, 5, 6, 7])

In [17]: data[3]
Out[17]: ('ATOM', 4, 'O', 'MET', 'A', 1, 67.105, 55.079, -37.531)
share|improve this answer
OK this really a nice way to read. Thanks a lot. Now I will wait for the answer of other points. –  user2176228 Apr 1 '13 at 15:58
I suggest you split your question into two questions, since they are pretty different. I read your title and assumed at first it was just about reading a file. Rotating the data is another question that would justify another post, with the details from your above comment included. –  askewchan Apr 1 '13 at 16:00
Thanks askewchan. I will write a separate question. –  user2176228 Apr 1 '13 at 16:08

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