sharplabtool: tools/evolution/codingSnps.pl comparison

comparison tools/evolution/codingSnps.pl @ 0:9071e359b9a3

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author	xuebing
date	Fri, 09 Mar 2012 19:37:19 -0500
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--1:000000000000
+:9071e359b9a3
+#!/usr/bin/perl -w
+use strict;
+#########################################################################
+#	codingSnps.pl
+#	This takes a bed file with the names being / separated nts
+#	and a gene bed file with cds start and stop.
+#	It then checks for changes in coding regions, reporting
+#	those that cause a frameshift or substitution in the amino acid.
+#########################################################################
+my $seqFlag = "2bit"; #flag to set sequence type 2bit|nib
+if (!@ARGV or scalar @ARGV < 3) {
+print "Usage: codingSnps.pl snps.bed genes.bed (/dir/*$seqFlag|Galaxy build= loc=) [chr=# start=# end=# snp=# keepColumns=1] > codingSnps.txt\n";
+exit;
+}
+my $uniq = 0; #flag for whether want uniq positions
+my $syn = 0;  #flag for if want synonomous changes rather than non-syn
+my $keep = 0; #keep old columns and append new ones
+my $snpFile = shift @ARGV;
+my $geneFile = shift @ARGV;
+my $nibDir = shift @ARGV;  #2bit or nib, depending on flag above
+if ($nibDir eq 'Galaxy') { getGalaxyInfo(); }
+my $col0 = 0; #bed like columns in default positions
+my $col1 = 1;
+my $col2 = 2;
+my $col3 = 3;
+#column positions 1 based coming in (for Galaxy)
+foreach (@ARGV) {
+if (/chr=(\d+)/) { $col0 = $1 -1; }
+elsif (/start=(\d+)/) { $col1 = $1 -1; }
+elsif (/end=(\d+)/) { $col2 = $1 -1; }
+elsif (/snp=(\d+)/) { $col3 = $1 -1; }
+elsif (/keepColumns=1/) { $keep = 1; }
+}
+if ($col0 < 0 || $col1 < 0 || $col2 < 0 || $col3 < 0) {
+print STDERR "ERROR column numbers are given with origin 1\n";
+exit 1;
+}
+my @genes; #bed lines for genes, sorted by chrom and start
+my %chrSt; #index in array where each chrom starts
+my %codon; #hash of codon amino acid conversions
+my $ends = 0; #ends vs sizes in bed 11 position, starts relative to chrom
+my $ignoreN = 1; #skip N
+my %amb = (
+"R" => "A/G",
+"Y" => "C/T",
+"S" => "C/G",
+"W" => "A/T",
+"K" => "G/T",
+"M" => "A/C",
+"B" => "C/G/T",
+"D" => "A/G/T",
+"H" => "A/C/T",
+"V" => "A/C/G",
+"N" => "A/C/G/T"
+);
+fill_codon();
+open(FH, "cat $geneFile | sort -k1,1 -k2,2n |")
+or die "Couldn't open and sort $geneFile, $!\n";
+my $i = 0;
+while(<FH>) {
+chomp;
+if (/refGene.cdsEnd|ccdsGene.exonEnds/) { $ends = 1; next; }
+push(@genes, "$_");
+my @f = split(/\t/);
+if (!exists $chrSt{$f[0]}) { $chrSt{$f[0]} = $i; }
+$i++;
+}
+close FH or die "Couldn't close $geneFile, $!\n";
+if ($ends) { print STDERR "WARNING using block ends rather than sizes\n"; }
+#open snps sorted as well
+my $s1 = $col0 + 1; #sort order is origin 1
+my $s2 = $col1 + 1;
+open(FH, "cat $snpFile | sort -k$s1,$s1 -k$s2,${s2}n |")
+or die "Couldn't open and sort $snpFile, $!\n";
+$i = 0;
+my @g; #one genes fields, should be used repeatedly
+my %done;
+while(<FH>) {
+chomp;
+if (/^\s*#/) { next; } #comment
+my @s = split(/\t/); #SNP fields
+if (!@s or !$s[$col0]) { die "ERROR missing SNP data, $_\n"; }
+my $size = $#s;
+if ($col0 > $size || $col1 > $size || $col2 > $size || $col3 > $size) {
+print STDERR "ERROR file has fewer columns than requested, requested columns (0 based) $col0 $col1 $col2 $col3, file has $size\n";
+exit 1;
+}
+if ($s[$col1] =~ /\D/) {
+print STDERR "ERROR the start point must be an integer not $s[$col1]\n";
+exit 1;
+}
+if ($s[$col2] =~ /\D/) {
+print STDERR "ERROR the start point must be an integer not $s[$col2]\n";
+exit 1;
+}
+if ($s[$col3] eq 'N' && $ignoreN) { next; }
+if (exists $amb{$s[$col3]}) { $s[$col3] = $amb{$s[$col3]}; }
+if (!@g && exists $chrSt{$s[$col0]}) { #need to fetch first gene row
+$i = $chrSt{$s[$col0]};
+@g = split(/\t/, $genes[$i]);
+if (scalar @g < 12) {
+print STDERR "ERROR the gene file must be the whole genes in BED format\n";
+exit 1;
+}
+}elsif (!@g) {
+next; #no gene for this chrom
+}elsif ($s[$col0] ne $g[0] && exists $chrSt{$s[$col0]}) { #new chrom
+$i = $chrSt{$s[$col0]};
+@g = split(/\t/, $genes[$i]);
+}elsif ($s[$col0] ne $g[0]) {
+next; #no gene for this chrom
+}elsif ($s[$col1] < $g[1] && $i == $chrSt{$s[$col0]}) {
+next; #before any genes
+}elsif ($s[$col1] > $g[2] && ($i == $#genes or $genes[$i+1] !~ $s[$col0])) {
+next; #after all genes on chr
+}else {
+while ($s[$col1] > $g[2] && $i < $#genes) {
+$i++;
+@g = split(/\t/, $genes[$i]);
+if ($s[$col0] ne $g[0]) { last; } #end of gene
+}
+if ($s[$col0] ne $g[0] or $s[$col1] < $g[1] or $s[$col1] > $g[2]) {
+next; #no overlap with genes
+}
+}
+processSnp(\@s, \@g);
+if ($uniq && exists $done{"$s[$col0] $s[$col1] $s[$col2]"}) { next; }
+my $k = $i + 1; #check for more genes without losing data of first
+if ($k <= $#genes) {
+my @g2 = split(/\t/, $genes[$k]);
+while (@g2 && $k <= $#genes) {
+@g2 = split(/\t/, $genes[$k]);
+if ($s[$col0] ne $g2[0]) {
+undef @g2;
+last; #not same chrom
+}else {
+while ($s[$col1] > $g2[2] && $k <= $#genes) {
+$k++;
+@g2 = split(/\t/, $genes[$k]);
+if ($s[$col0] ne $g2[0]) { last; } #end of chrom
+}
+if ($s[$col0] ne $g2[0] or $s[$col1] < $g2[1] or $s[$col1] > $g2[2]) {
+undef @g2;
+last; #no overlap with more genes
+}
+processSnp(\@s, \@g2);
+if ($uniq && exists $done{"$s[$col0] $s[$col1] $s[$col2]"}) { last; }
+}
+$k++;
+}
+}
+}
+close FH or die "Couldn't close $snpFile, $!\n";
+exit;
+########################################################################
+sub processSnp {
+my $sref = shift;
+my $gref = shift;
+#overlaps gene, but maybe not coding seq
+#inside cds
+if ($sref->[$col1] + 1 < $gref->[6] or $sref->[$col2] > $gref->[7]) {
+return; #outside of coding
+}
+#now check exon
+my $i = 0;
+my @st = split(/,/, $gref->[11]);
+my @size = split(/,/, $gref->[10]);
+if (scalar @st ne $gref->[9]) { return; } #cant do this gene #die "bad gene $gref->[3]\n"; }
+my @pos;
+my $in = 0;
+for($i = 0; $i < $gref->[9]; $i++) {
+my $sta = $gref->[1] + $st[$i] + 1; #1 based position
+my $end = $sta + $size[$i] - 1; #
+if ($ends) { $end = $size[$i]; $sta = $st[$i] + 1; } #ends instead of sizes
+if ($end < $gref->[6]) { next; } #utr only
+if ($sta > $gref->[7]) { next; } #utr only
+#shorten to coding only
+if ($sta < $gref->[6]) { $sta = $gref->[6] + 1; }
+if ($end > $gref->[7]) { $end = $gref->[7]; }
+if ($sref->[$col1] + 1 >= $sta && $sref->[$col2] <= $end) { $in = 1; }
+elsif ($sref->[$col1] == $sref->[$col2] && $sref->[$col2] <= $end && $sref->[$col2] >= $sta) { $in = 1; }
+push(@pos, ($sta .. $end)); #add exon worth of positions
+}
+#@pos has coding positions for whole gene (chr coors),
+#and $in has whether we need to continue
+if (!$in) { return; } #not in coding exon
+if ((scalar @pos) % 3 != 0) { return; } #partial gene? not even codons
+if ($sref->[$col3] =~ /^-+\/[ACTG]+$/ or $sref->[$col3] =~ /^[ACTG]+\/-+$/ or
+$sref->[$col3] =~ /^-+$/) { #indel or del
+my $copy = $sref->[$col3];
+my $c = ($copy =~ tr/-//);
+if ($c % 3 == 0) { return; } #not frameshift
+#handle bed4 or any interval file
+if (!$keep) {
+print "$sref->[$col0]\t$sref->[$col1]\t$sref->[$col2]\t$sref->[$col3]";
+print "\t$gref->[3]\tframeshift\n";
+}else {
+my @s = @{$sref};
+print join("\t", @s), "\t$gref->[3]\tframeshift\n";
+}
+$done{"$sref->[$col0] $sref->[$col1] $sref->[$col2]"}++;
+return;
+}elsif ($sref->[$col1] == $sref->[$col2]) { #insertion
+my $copy = $sref->[$col3];
+my $c = ($copy =~ tr/\[ACTG]+//);
+if ($c % 3 == 0) { return; } #not frameshift
+#handle bed4 or any interval file
+if (!$keep) {
+print "$sref->[$col0]\t$sref->[$col1]\t$sref->[$col2]\t$sref->[$col3]";
+print "\t$gref->[3]\tframeshift\n";
+}else {
+my @s = @{$sref};
+print join("\t", @s), "\t$gref->[3]\tframeshift\n";
+}
+$done{"$sref->[$col0] $sref->[$col1] $sref->[$col2]"}++;
+return;
+}elsif ($sref->[$col3] =~ /-/) { #indel and sub?
+return; #skip
+}
+#check for amino acid substitutions
+my $s = $sref->[$col1] + 1;
+my $e = $sref->[$col2];
+my $len = $sref->[$col2] - $sref->[$col1];
+if ($gref->[5] eq '-') {
+@pos = reverse(@pos);
+my $t = $s;
+$s = $e;
+$e = $t;
+}
+$i = 0;
+my $found = 0;
+foreach (@pos) {
+if ($s == $_) {
+$found = 1;
+last;
+}
+$i++;
+}
+if ($found) {
+my $fs = $i; #keep original start index
+#have index where substitution starts
+my $cp = $i % 3;
+$i -= $cp; #i is now first position in codon
+my $cdNum = int($i / 3) + 1;
+my $ls = $i;
+if (!defined $ls) { die "ERROR not defined ls for $fs $sref->[$col2]\n"; }
+if (!@pos) { die "ERROR not defined array pos\n"; }
+if (!defined $pos[$ls]) { die "ERROR not defined pos at $ls\n"; }
+if (!defined $e) { die "ERROR not defined e for $pos[0] $pos[1] $pos[2]\n"; }
+while ($ls <= $#pos && $pos[$ls] ne $e) {
+$ls++;
+}
+my $i2 = $ls + (2 - ($ls % 3));
+if ($i2 > $#pos) { return; } #not a full codon, partial gene?
+if ($i2 - $i < 2) { die "not a full codon positions $i to $i2 for $sref->[3]\n"; }
+my $oldnts = getnts($sref->[$col0], @pos[$i..$i2]);
+if (!$oldnts) { die "Failed to get sequence for $sref->[$col0] $pos[$i] .. $pos[$i2]\n"; }
+my @vars = split(/\//, $sref->[$col3]);
+if ($gref->[5] eq '-') { #complement oldnts and revcomp vars
+$oldnts = compl($oldnts);
+if (!$oldnts) { return; } #skip this one
+$oldnts = join('', (reverse(split(/ */, $oldnts))));
+foreach (@vars) {
+$_ = reverse(split(/ */)); #needed for indels
+$_ = compl($_);
+}
+}
+my $r = $fs - $i; #difference in old indexes gives new index
+my @newnts;
+my $changed = '';
+foreach my $v (@vars) {
+if (!$v or length($v) != 1) { return; } #only simple changes
+my @new = split(/ */, $oldnts);
+$changed = splice(@new, $r, $len, split(/ */, $v));
+#should only change single nt
+push(@newnts, join("", @new));
+}
+#now compute amino acids
+my $oldaa = getaa($oldnts);
+my @newaa;
+my $change = 0; #flag for if there is a change
+foreach my $v (@newnts) {
+my $t = getaa($v);
+if ($t ne $oldaa) { $change = 1; }
+push(@newaa, $t);
+}
+if (!$change && $syn) {
+if (!$keep) {
+print "$sref->[$col0]\t$sref->[$col1]\t$sref->[$col2]\t$sref->[$col3]";
+print "\t$gref->[3]\t$oldaa:", join("/", @newaa), "\n";
+}else {
+my @s = @{$sref};
+print join("\t", @s),
+"\t$gref->[3]\t$oldaa:", join("/", @newaa), "\n";
+}
+return;
+}elsif ($syn) { return; } #only want synonymous changes
+if (!$change) { return; } #no change in amino acids
+if (!$keep) {
+print "$sref->[$col0]\t$sref->[$col1]\t$sref->[$col2]\t$sref->[$col3]";
+if ($gref->[5] eq '-') { $changed = compl($changed); } #use plus for ref
+if (!$changed) { return; } #skip this one
+print "\t$gref->[3]\t$oldaa:", join("/", @newaa), "\t$cdNum\t$changed\n";
+}else {
+my @s = @{$sref};
+print join("\t", @s);
+if ($gref->[5] eq '-') { $changed = compl($changed); } #use plus for ref
+if (!$changed) { return; } #skip this one
+print "\t$gref->[3]\t$oldaa:", join("/", @newaa), "\t$cdNum\t$changed\n";
+}
+$done{"$sref->[$col0] $sref->[$col1] $sref->[$col2]"}++;
+}
+}
+sub getnts {
+my $chr = shift;
+my @pos = @_; #list of positions not necessarily in order
+#list may be reversed or have gaps(introns), at least 3 bps
+my $seq = '';
+if (scalar @pos < 3) { die "too small region for $chr $pos[0]\n"; }
+if ($pos[0] < $pos[1]) { #not reversed
+my $s = $pos[0];
+for(my $i = 1; $i <= $#pos; $i++) {
+if ($pos[$i] == $pos[$i-1] + 1) { next; }
+if ($seqFlag eq '2bit') {
+$seq .= fetchSeq2bit($chr, $s, $pos[$i-1]);
+}else {
+$seq .= fetchSeqNib($chr, $s, $pos[$i-1]);
+}
+$s = $pos[$i];
+}
+if (length $seq != scalar @pos) { #still need to fetch seq
+if ($seqFlag eq '2bit') {
+$seq .= fetchSeq2bit($chr, $s, $pos[$#pos]);
+}else {
+$seq .= fetchSeqNib($chr, $s, $pos[$#pos]);
+}
+}
+}else { #reversed
+my $s = $pos[$#pos];
+for(my $i = $#pos -1; $i >= 0; $i--) {
+if ($pos[$i] == $pos[$i+1] + 1) { next; }
+if ($seqFlag eq '2bit') {
+$seq .= fetchSeq2bit($chr, $s, $pos[$i+1]);
+}else {
+$seq .= fetchSeqNib($chr, $s, $pos[$i+1]);
+}
+$s = $pos[$i];
+}
+if (length $seq != scalar @pos) { #still need to fetch seq
+if ($seqFlag eq '2bit') {
+$seq .= fetchSeq2bit($chr, $s, $pos[0]);
+}else {
+$seq .= fetchSeqNib($chr, $s, $pos[0]);
+}
+}
+}
+}
+sub fetchSeq2bit {
+my $chr = shift;
+my $st = shift;
+my $end = shift;
+my $strand = '+';
+$st--; #change to UCSC numbering
+open (BIT, "twoBitToFa -seq=$chr -start=$st -end=$end $nibDir stdout |") or
+die "Couldn't run twoBitToFa, $!\n";
+my $seq = '';
+while (<BIT>) {
+chomp;
+if (/^>/) { next; } #header
+$seq .= uc($_);
+}
+close BIT or die "Couldn't finish twoBitToFa on $chr $st $end, $!\n";
+return $seq;
+}
+sub fetchSeqNib {
+my $chr = shift;
+my $st = shift;
+my $end = shift;
+my $strand = '+';
+$st--; #change to UCSC numbering
+open (NIB, "nibFrag -upper $nibDir/${chr}.nib $st $end $strand stdout |") or die "Couldn't run nibFrag, $!\n";
+my $seq = '';
+while (<NIB>) {
+chomp;
+if (/^>/) { next; } #header
+$seq .= $_;
+}
+close NIB or die "Couldn't finish nibFrag on $chr $st $end, $!\n";
+return $seq;
+}
+sub compl {
+my $nts = shift;
+my $comp = '';
+if (!$nts) { die "ERROR called compl with nts undefined"; }
+foreach my $n (split(/ */, $nts)) {
+if ($n eq 'A') { $comp .= 'T'; }
+elsif ($n eq 'T') { $comp .= 'A'; }
+elsif ($n eq 'C') { $comp .= 'G'; }
+elsif ($n eq 'G') { $comp .= 'C'; }
+elsif ($n eq 'N') { $comp .= 'N'; }
+elsif ($n eq '-') { $comp .= '-'; } #deletion
+else { $comp = undef; }
+}
+return $comp;
+}
+sub getaa {
+my $nts = shift;  #in multiples of 3
+my $aa = '';
+my @n = split(/ */, $nts);
+while (@n) {
+my @t = splice(@n, 0, 3);
+my $n = uc(join("", @t));
+if (!exists $codon{$n}) { $aa .= 'N'; next; }
+$aa .= $codon{$n};
+}
+return $aa;
+}
+sub fill_codon {
+$codon{GCA} = 'Ala';
+$codon{GCC} = 'Ala';
+$codon{GCG} = 'Ala';
+$codon{GCT} = 'Ala';
+$codon{CGG} = 'Arg';
+$codon{CGT} = 'Arg';
+$codon{CGC} = 'Arg';
+$codon{AGA} = 'Arg';
+$codon{AGG} = 'Arg';
+$codon{CGA} = 'Arg';
+$codon{AAC} = 'Asn';
+$codon{AAT} = 'Asn';
+$codon{GAC} = 'Asp';
+$codon{GAT} = 'Asp';
+$codon{TGC} = 'Cys';
+$codon{TGT} = 'Cys';
+$codon{CAG} = 'Gln';
+$codon{CAA} = 'Gln';
+$codon{GAA} = 'Glu';
+$codon{GAG} = 'Glu';
+$codon{GGG} = 'Gly';
+$codon{GGA} = 'Gly';
+$codon{GGC} = 'Gly';
+$codon{GGT} = 'Gly';
+$codon{CAC} = 'His';
+$codon{CAT} = 'His';
+$codon{ATA} = 'Ile';
+$codon{ATT} = 'Ile';
+$codon{ATC} = 'Ile';
+$codon{CTA} = 'Leu';
+$codon{CTC} = 'Leu';
+$codon{CTG} = 'Leu';
+$codon{CTT} = 'Leu';
+$codon{TTG} = 'Leu';
+$codon{TTA} = 'Leu';
+$codon{AAA} = 'Lys';
+$codon{AAG} = 'Lys';
+$codon{ATG} = 'Met';
+$codon{TTC} = 'Phe';
+$codon{TTT} = 'Phe';
+$codon{CCT} = 'Pro';
+$codon{CCA} = 'Pro';
+$codon{CCC} = 'Pro';
+$codon{CCG} = 'Pro';
+$codon{TCA} = 'Ser';
+$codon{AGC} = 'Ser';
+$codon{AGT} = 'Ser';
+$codon{TCC} = 'Ser';
+$codon{TCT} = 'Ser';
+$codon{TCG} = 'Ser';
+$codon{TGA} = 'Stop';
+$codon{TAG} = 'Stop';
+$codon{TAA} = 'Stop';
+$codon{ACT} = 'Thr';
+$codon{ACA} = 'Thr';
+$codon{ACC} = 'Thr';
+$codon{ACG} = 'Thr';
+$codon{TGG} = 'Trp';
+$codon{TAT} = 'Tyr';
+$codon{TAC} = 'Tyr';
+$codon{GTC} = 'Val';
+$codon{GTA} = 'Val';
+$codon{GTG} = 'Val';
+$codon{GTT} = 'Val';
+}
+sub getGalaxyInfo {
+my $build;
+my $locFile;
+foreach (@ARGV) {
+if (/build=(.*)/) { $build = $1; }
+elsif (/loc=(.*)/) { $locFile = $1; }
+}
+if (!$build or !$locFile) {
+print STDERR "ERROR missing build or locfile for Galaxy input\n";
+exit 1;
+}
+# read $locFile to get $nibDir (ignoring commets)
+open(LF, "< $locFile") || die "open($locFile): $!\n";
+while(<LF>) {
+s/#.*$//;
+s/(?:^\s+|\s+$)//g;
+next if (/^$/);
+my @t = split(/\t/);
+if ($t[0] eq $build) { $nibDir = $t[1]; }
+}
+close(LF);
+if ($nibDir eq 'Galaxy') {
+print STDERR "Failed to find sequence directory in locfile $locFile\n";
+}
+$nibDir .= "/$build.2bit";  #we want full path and filename
+}

Mercurial > repos > xuebing > sharplabtool

comparison tools/evolution/codingSnps.pl @ 0:9071e359b9a3