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# How do I counting overlapping dimers for multiple sequences?

I have to count the number of overlapping dimers (AA, AG, AC, AT, GA, GG, GC, GT, CC, CG, CA, CT, TT, TA, TG, TC) in multiple sequences using Perl. I wrote the following code but it only works for one sequence. How can I extend it to multiple sequences?

``````#!/usr/bin/perl -w
open FH, "sample.txt";
\$genome=<FH>;
%count=();
\$count{substr(\$genome, \$_, 2)}++ for 0..length(\$genome)-2;
print "AA: \$count{AA}\n";
print "AG: \$count{AG}\n";
print "AC: \$count{AC}\n";
print "AT: \$count{AT}\n";

print "TA: \$count{TA}\n";
print "TG: \$count{TG}\n";
print "TC: \$count{TC}\n";
print "TT: \$count{TT}\n";

print "GA: \$count{GA}\n";
print "GG: \$count{GG}\n";
print "GC: \$count{GC}\n";
print "GT: \$count{GT}\n";

print "CA: \$count{CA}\n";
print "CG: \$count{CG}\n";
print "CC: \$count{CC}\n";
print "CT: \$count{CT}\n";
``````

I need:

1. counts for each sequence and
2. the total counts

input example: `sample.txt`

``````ATGGGCTCCTCCGCCATCACCGTGAGCTTCCTCCTCTTTCTGGCATTTCAGCTCCCAGGGCAAACAGGAGCAAATCCCGTGTATGGCTCTGTGTCCAATGCAGACCTGATGGATTTCAAGTAAAAG
ATGGTGAGAAAATGGGCCCTGCTCCTGCCCATGCTGCTCTGCGGCCTGACTGGTCCCGCACACCTCTTCCAGCCAAGCCTGGTGCTGGAGATGGCCCAGGTCCTCTTGGATAACTACTGCTTCCCAGAGAACCTGATGGGGATGCAGGGAGCCATCGAGCAGGCCATCAAAAGTCAGGAGATTCTGTCTATCTCAGACCCTCAGACTCTGGCCCATGTGTTGACAGCTGGGGTGCAGAGCTCCTTGAATGACCCTCGCCTGGTCATCTCCTATGAGCCCAGCACCCTCGAGGCCCCTCCGCGAGCTCCAGCAGTCACGAACCTCACACTAGAGGAAATCATCGCAGGGCTGCAGGATGGCCTTCGCCATGAGATTCTGGAAGGCAATGTGGGCTACCTGCGGGTGGACGACATCCCGGGCCAGGAGGTGATGAGCAAGCTGAGGAGCTTCCTGGTGGCCAACGTCTGGAGGAAGCTCGTGAACACGTCCGCCTTGGTGCTGGACCTCCGGCACTGCACTGGGGGACACGTGTCTGGCATCCCCTATGTCATCTCCTACCTGCACCCAGGGAGCACAGTCTCGCACGTGGACACCGTCTACGACCGCCCCTCCAACACAACCACTGAGATCTGGACCCTGCCTGAAGCCCTGGGAGAGAAGTACAGTGCAGACAAGGATGTGGTGGTCCTCACCAGCAGCCGCACGGGGGGCGTGGCTGAGGACATCGCTTACATCCTCAAACAGATGCGCAGGGCCATCGTGGTGGGCGAGCGGACTGTTGGGGGGGCTCTGAACCTCCAGAAGCTGAGGGTAGGCCAGTCCGACTTCTTTCTCACTGTGCCTGTGTCCAGATCCCTGGGGCCCCTGGGTGAGGGCAGCCAGACGTGGGAGGGCAGTGGGGTGCTGCCCTGTGTGGGGACACCGGCCGAGCAGGCCCTGGAGAAAGCCCTGGCCGTTCTCATGCTGCGCAGGGCCCTGCCAGGAGTCATTCAGCGCCTTCAGGAGGCGCTGCGCGAGTACTACACGCTGGTGGACCGTGTGCCCGCCCTGCTGAGCCACCTGGCCGCCATGGACCTGTCCTCGGTGGTCTCCGAGGACGATCTGGTCACTAAGCTCAATGCTGGCCTGCAGGCTGTGTCTGAGGACCCCAGGCTCCAGGTGCAGGTGGTCAGACCCAAAGAAGCCTCTTCTGGGCCTGAGGAAGAAGCTGAAGAACCTCCAGAGGCGGTCCCGGAAGTGCCCGAGGACGAGGCTGTTCGGCGGGCTCTGGTGGACTCCGTGTTCCAGGTTTCTGTGCTGCCGGGCAACGTGGGCTACCTGCGCTTCGACAGTTTCGCTGATGCCTCTGTCCTGGAGGTGCTGGGCCCCTACATCCTGCACCAGGTGTGGGAGCCCCTGCAGGACACGGAGCACCTCATCATGGACCTGCGGCAGAACCCCGGGGGGCCGTCCTCCGCGGTGCCCCTGCTGCTCTCCTACTTCCAGAGCCCTGACGCCAGCCCCGTGCGCCTCTTCTCCACCTACGACCGGCGCACCAACATCACACGCGAGCACTTCAGCCAGACGGAGCTGCTGGGCCGGCCCTACGGCACCCAGCGTGGCGTGTACCTGCTCACTAGCCACCGCACCGCCACCGCGGCCGAGGAGCTGGCCTTCCTCATGCAGTCACTGGGCTGGGCCACGCTGGTGGGCGAGATCACCGCGGGCAGCCTGCTGCACACACACACAGTATCCCTGCTGGAGACGCCCGAGGGCGGCCTGGCGCTCACGGTGCCTGTGCTCACCTTCATCGACAACCATGGCGAGTGCTGGCTGGGGGGCGGTGTGGTCCCCGATGCCATTGTGCTGGCCGAGGAAGCCCTAGACAGAGCCCAGGAGGTGCTGGAGTTCCACCGAAGCTTGGGGGAGTTGGTGGAAGGCACGGGGCGCCTGCTGGAGGCCCACTACGCTCGGCCAGAGGTCGTGGGGCAGATGGGTGCCCTGCTGCGAGCCAAGCTGGCCCAGGGGGCCTACCGCACCGCGGTGGACCTGGAGTCGCTGGCTTCCCAGCTTACGGCCGACCTGCAGGAGATGTCTGGGGACCACCGTCTGCTGGTGTTCCACAGCCCCGGCGAAATGGTGGCTGAGGAGGCGCCCCCACCGCCTCCCGTCGTCCCCTCCCCGGAGGAGCTGTCCTATCTCATCGAGGCCCTGTTCAAGACTGAGGTGCTGCCCGGCCAGCTGGGCTACCTGCGTTTCGACGCCATGGCTGAGCTGGAGACGGTGAAGGCCGTCGGGCCACAGCTGGTGCAGCTGGTGTGGCAGAAGCTGGTGGACACGGCCGCGCTGGTGGTCGACCTGCGCTACAACCCCGGCAGCTACTCCACAGCCGTGCCTCTACTCTGCTCCTACTTCTTCGAGGCAGAGCCCCGCCGGCACCTCTACTCTGTCTTTGACAGGGCCACGTCAAGGGTCACAGAGGTATGGACCCTGCCCCACGTTACAGGCCAGCGCTATGGCTCCCACAAGGACCTCTACGTTCTGGTGAGCCACACCAGCGGTTCAGCAGCTGAGGCTTTTGCTCACACCATGCAGGATCTGCAGCGAGCCACCATCATCGGGGAGCCCACGGCCGGAGGGGCACTCTCCGTGGGAATCTACCAGGTGGGCAGCAGCGCCTTATACGCCTCCATGCCCACGCAGATGGCCATGAGTGCCAGCACCGGCGAGGCCTGGGATCTGGCTGGGGTGGAGCCGGACATCACTGTGCCCATGAGCGTGGCCCTCTCCACAGCCCGGGACATAGTGACCCTGCGTGCCAAGGTGCCCACTGTGCTGCAGACAGCTGGGAAGCTCGTAGCGGATAACTACGCCTCCCCTGAGCTGGGAGTCAAGATGGCAGCCGAACTGAGTGGTCTGCAGAGCCGCTATGCCAGGGTGACCTCAGAAGCCGCCCTCGCCGAGCTGCTGCAAGCCGACCTGCAGGTGCTGTCCGGGGACCCACACCTGAAGACAGCTCATATACCTGAGGATGCCAAAGACCGCATTCCTGGCATTGTACCCATGCAGTAACAG
ATGGACATGATGGACGGCTGCCAGTTCTCGCCCTCTGAGTACTTCTACGACGGCTCCTGCATCCCATCCCCCGACGGTGAGTTCGGGGACGAGTTTGAGCCGCGAGTGGCTGCTTTCGGGGCTCACAAGGCAGACCTGCAAGGCTCAGACGAGGACGAGCACGTGCGAGCACCCACGGGCCACCACCAGGCCGGCCACTGCCTCATGTGGGCCTGCAAAGCATGCAAAAGGAAGTCCACCACCATGGATCGGCGGAAGGCGGCCACCATGCGCGAGCGGAGACGCCTGAAGAAGGTCAACCAGGCTTTCGACACGCTCAAGCGGTGCACCACGACCAACCCTAACCAGAGGCTGCCCAAGGTGGAGATCCTCAGGAATGCCATCCGCTACATTGAGAGTCTGCAGGAGCTGCTTAGGGAACAGGTGGAAAACTACTATAGCCTGCCGGGGCAGAGCTGCTCTGAGCCCACCAGCCCCACCTCAAGTTGCTCTGATGGCATGTAAATG
``````
-
Please specify the definition of "sequence", particularly how you expect the program to recognize that one sequence is ending and another is beginning. – darch Mar 26 '12 at 7:25
Each sequence begins on a newline. – user1241854 Mar 26 '12 at 7:28
Do you already know what the counts should be? I'm a bit too busy this morning to figure it out myself (and it is your question, after all :) – brian d foy Mar 26 '12 at 18:45

The key to this is take what you had so far as a functional unit of what you were trying to build. Your code worked for one sequence; extending it to multiple sequences is simply a matter of getting rid of the assumption that only one sequence is being considered:

``````use strict;
use warnings;
use 5.010;

use Data::Dumper ();

sub count_dimers {
my (\$sequence) = @_;

my %counts;
\$counts{substr(\$sequence, \$_, 2)}++ for 0..length(\$sequence) - 2;

my @dimers = qw(AA AG AC AT GA GG GC GT CC CG CA CT TT TA TG TC);
%counts = map { \$_ => \$counts{\$_} } @dimers;

return %counts;
}

open(my \$fh, '<', 'sample.txt');

my @counts_by_sequence;
while (my \$sequence = <\$fh>) {
my %sequence_counts = count_dimers(\$sequence);
push @counts_by_sequence, \%sequence_counts;
}

my %total_counts;
for my \$sequence_counts (@counts_by_sequence) {
for my \$dimer (keys %\$sequence_counts) {
\$total_counts{\$dimer} += \${ \$sequence_counts}{\$dimer};
}
}

say Data::Dumper->Dump(
[\%total_counts, \@counts_by_sequence],
[qw(total_count counts_by_sequence)]
);
``````

I left the output as an exercise to the reader, but the general shape of the transformation should be evident: What was once the entirety of the program is now a function that gets called once per sequence with the results per call stored and the results over all calls totaled.

-
Thanks, the code works perfectly! – user1241854 Mar 26 '12 at 9:08
``````#!/usr/bin/perl

use strict;

my @dimers = qw(AA AG AC AT GA GG GC GT CC CG CA CT TT TA TG TC);
my @dimers_totals;

my \$i = 1;
for(<>)
{
my \$sequence = \$_;
print("Sequence \$i:\n");
my \$j = 0;
for(@dimers)
{
my \$number =()= \$sequence =~ /\$_/gi;
\$dimers_totals[\$j++] += \$number;
print "\t\$_: \$number\n"
}
print("\n");
\$i++;
}

print("Totals:\n");
\$i = 0;
for(@dimers)
{
print("\t\$_: \$dimers_totals[\$i++]\n");
}
``````

Use like

``````./dimers_count.pl < sample.txt
``````
-
This code is giving me the count for the entire file. My file contains many sequences and I need a count for each sequence as well. How can I modify the code? – user1241854 Mar 26 '12 at 7:17
Ok, modified it, check if this is what you want. PS: I didn't use hashes to not mess the order. – m0skit0 Mar 26 '12 at 8:14
This code does not count AA, TT, CC, GG correctly. Otherwise, it's good! – user1241854 Mar 26 '12 at 9:12
It does count them correctly indeed. The problem is that you didn't specify in your question that dimers go in pairs ;) – m0skit0 Mar 26 '12 at 10:25
This works, but you end up scanning every sequence several times. – brian d foy Mar 26 '12 at 18:48

My first thought was a global match in scalar context with an adjustment to pos() to back up one. This way, I only have to scan the string once for all dimers (whereas the other answers so far scan the sequence once for every dimer). I maintain too hashes; one for the total and one for the sequence. I'm using the `\$.` special variable that holds the current input line number to label the sequence:

``````use Data::Printer;

while( <DATA> ) {
while( /\G([ATGC]{2})/g ) {
\$total{\$1}++;
\$by_sequence{\$.}{\$1}++;
pos() = pos() - 1
}
}

p( %total );
p( %by_sequence );
``````

Doing the same thing with substr took a bit much more work because I couldn't limit the substring to just the characters that mattered. I had to pay attention to newlines and odd counts at the end:

``````use Data::Printer;

LINE: while( <DATA> ) {
chomp;
my \$pos = 0;
SUB: while( my \$sub = substr( \$_, \$pos, 2 ) ) {
last SUB unless 2 == length \$sub;
\$total{\$sub}++;
\$by_sequence{\$.}{\$sub}++;
\$pos++;
}
}

p( %total );
p( %by_sequence );
``````

The output from Data::Printer is very nice. I've been using it in preference to Data::Dumper since I found out about it at YAPC::Brasil. (And, by the way, its author will be at YAPC::NA in Madison this year to talk about it):

``````{
AA   101,
AC   215,
AG   268,
AT   106,
CA   286,
CC   388,
CG   201,
CT   310,
GA   239,
GC   376,
GG   369,
GT   168,
TA   61,
TC   206,
TG   317,
TT   73
}
{
1   {
AA   9,
AC   3,
AG   8,
AT   8,
CA   11,
CC   12,
CG   3,
CT   11,
GA   5,
GC   9,
GG   8,
GT   6,
TA   2,
TC   13,
TG   10,
TT   7
},
2   {
AA   68,
AC   177,
AG   219,
AT   80,
CA   230,
CC   329,
CG   168,
CT   264,
GA   195,
GC   316,
GG   317,
GT   146,
TA   50,
TC   169,
TG   271,
TT   54
},
3   {
AA   24,
AC   35,
AG   41,
AT   18,
CA   45,
CC   47,
CG   30,
CT   35,
GA   39,
GC   51,
GG   44,
GT   16,
TA   9,
TC   24,
TG   36,
TT   12
}
}
``````
-
`Data::Printer` looks good, but its dependencies list is impressive (tried it on debian) – eugene y Mar 27 '12 at 10:12