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My question relates to bioinformatics, specifically protein sequences however, no biological knowledge is really needed. I am trying to find an efficient way of solving this problem in Perl:

Protein sequences are basically sequences or strings which vary in length and are composed of combinations of 20 amino acids or characters.

At a length of 1, there would be thus 20 possibilities. The issue is that with every increment of 1 character, the number of possibilities increases substantially.

I wanted to compute another calculation on every sequence of every length. Protein sequences can be many hundreds and even thousands of amino acids. I just need to get all the possible sequences to do this.

edit: I realise that it is impossible to compute for every length, I do not need to do this, but I wanted to do it for a sensible length that would not take anywhere near the length of the universe.

Any suggestions on the most efficient way to code this?

edit: I do not really need to do this for sequences of 1000, I was just interested on ideas, resources, functions etc that I am not aware of that may help me understand the most efficient way to do this.

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The Book "Higher Order Perl" has some interesting solutions using iterators. See linked Chapter, especially 4.3.2 page 22 –  amon Jul 14 '12 at 15:13
SO is about helping people with specific programming questions. I don't see any code here, anything that you've tried, or how this question will be helpful to others in the future. –  Sparky Jul 14 '12 at 15:13
Thank you amon. I will look at this. –  kajendiran Jul 14 '12 at 15:17
You should think again. You cannot "compute another calculation on every sequence of every length". It would take forever several times over! –  Borodin Jul 14 '12 at 15:23
Thank you, yes you are correct, I will edit my post again to make it clearer. –  kajendiran Jul 14 '12 at 15:42

4 Answers 4

up vote 3 down vote accepted

The Math::Combinatorics module that has been recommended doesn't support permutations with replacement, which is what you want for this problem as otherwise your proteins can never be longer than twenty amino-acids.

Algorithm::Combinatorics will do the job, and is written partially in C so it should perform well.

Here is an example that generates all pairs of amino-acids. I have shown only the first few lines of output as even this produces 400 variations!

use strict;
use warnings;

use Algorithm::Combinatorics 'variations_with_repetition';

my @acids = qw/ ala arg asn asp cys gln glu gly his ile leu lys met phe pro ser thr trp tyr val /;

my @proteins = variations_with_repetition(\@acids, 2);

print "@$_\n" for @proteins;


ala ala
ala arg
ala asn
ala asp
ala cys
ala gln
ala glu
ala gly
ala his
ala ile
ala leu
ala lys
ala met
ala phe
ala pro
ala ser
ala thr
ala trp
ala tyr
ala val
arg ala
arg arg
arg asn
arg asp
arg cys
arg gln
arg glu
arg gly
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Brilliant, I have been trying to get Math::Combinatorics to do repetition for the last hour! This is exactly what I wanted, coding this explicitly was causing all sorts of problems and I hoped there would be something available for this exact purpose. Thank you! –  kajendiran Jul 14 '12 at 17:59

20^1000 is a really large number. You say you need to do some calculation for every sequence, which is not really possible without scaling out to multiple computers. Even at one million calculations a second it would take you many times the age of the universe to finish your calculations.

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Thank you for your reply. Yes, I realise it is a large number. I do not really need to do it up to such a high number, I was hoping to do this to a sensible value and then estimating the values above this. I was just wondering how people would conceptually go about this. –  kajendiran Jul 14 '12 at 15:26

Given that your phrasing involves every sequence of every known length, this problem would never converge to a reasonable result- you'd keep going to a length of infinity. Furthermore, your calculation would include a lot of sequences with no relation to reality, or comparisons between dipeptides and gigundous molecules. Even if you limited your calculation to the length of the largest known protein (titin, ~34,350 amino acids), it would still be a prohibitively expensive calculation.

As an alternate proposal: have you considered limiting it to proteins that are actually known to exist, or could be predicted from genetic databases? This would reduce the amount of work to a few thousand sequences of biological relevance, and for most bioinformatics applications genetic or sequence data is widely available from well-structured databases.

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Thank you for your comments. I have already computed the calculation for the entire known protein universe, however, I was just curious to see what the distribution for all possibilities at a given length would be. I was hoping to be able to extrapolate from a sensible length. Everything you say is correct, I was purely curious and also wanted to see if anyone suggests some resources that would help me in Perl. –  kajendiran Jul 14 '12 at 15:39
Well, the usual answer would be to brute force your calculation using a relatively robust implementation in the standard library, like creating a generator with Perl's List::Gen or python's itertools.product. In general you'll want to use generators to yield one element at a time, rather than calculate every element in memory at the same time. –  abought Jul 14 '12 at 15:45
Thank you, I have not heard of generator, I will look into this. Thank you once again. –  kajendiran Jul 14 '12 at 15:56

To generate permutations in perl I usually turn to Math::Combinatorics, here's a program snippet that returns all permutations of 1, 2, 3, one at a time:

#!/usr/bin/perl -l

use Math::Combinatorics;

$, = " ";

@n = (1 .. 3);
$permuter = Math::Combinatorics->new(data => \@n);

while(@perm = $permuter->next_permutation())
  print @perm;


1 2 3
1 3 2
2 1 3
2 3 1
3 1 2
3 2 1

But heed the advice from the other answers, this is an exponentially growing problem as it is stated, so you need some way of limiting your search space.

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Thor, thank you so much. This is great. –  kajendiran Jul 14 '12 at 16:10

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