Bio::DB::Sam(3) User Contributed Perl Documentation Bio::DB::Sam(3)NAMEBio::DB::Sam-- Read SAM/BAM database files
SYNOPSIS
use Bio::DB::Sam;
# high level API
my $sam = Bio::DB::Sam->new(-bam =>"data/ex1.bam",
-fasta=>"data/ex1.fa",
);
my @targets = $sam->seq_ids;
my @alignments = $sam->get_features_by_location(-seq_id => 'seq2',
-start => 500,
-end => 800);
for my $a (@alignments) {
# where does the alignment start in the reference sequence
my $seqid = $a->seq_id;
my $start = $a->start;
my $end = $a->end;
my $strand = $a->strand;
my $cigar = $a->cigar_str;
my $paired = $a->get_tag_values('PAIRED');
# where does the alignment start in the query sequence
my $query_start = $a->query->start;
my $query_end = $a->query->end;
my $ref_dna = $a->dna; # reference sequence bases
my $query_dna = $a->query->dna; # query sequence bases
my @scores = $a->qscore; # per-base quality scores
my $match_qual= $a->qual; # quality of the match
}
my @pairs = $sam->get_features_by_location(-type => 'read_pair',
-seq_id => 'seq2',
-start => 500,
-end => 800);
for my $pair (@pairs) {
my $length = $pair->length; # insert length
my ($first_mate,$second_mate) = $pair->get_SeqFeatures;
my $f_start = $first_mate->start;
my $s_start = $second_mate->start;
}
# low level API
my $bam = Bio::DB::Bam->open('/path/to/bamfile');
my $header = $bam->header;
my $target_count = $header->n_targets;
my $target_names = $header->target_name;
while (my $align = $bam->read1) {
my $seqid = $target_names->[$align->tid];
my $start = $align->pos+1;
my $end = $align->calend;
my $cigar = $align->cigar_str;
}
my $index = Bio::DB::Bam->index_open('/path/to/bamfile');
my $index = Bio::DB::Bam->index_open_in_safewd('/path/to/bamfile');
my $callback = sub {
my $alignment = shift;
my $start = $alignment->start;
my $end = $alignment->end;
my $seqid = $target_names->[$alignment->tid];
print $alignment->qname," aligns to $seqid:$start..$end\n";
}
my $header = $index->header;
$index->fetch($bam,$header->parse_region('seq2'),$callback);
DESCRIPTION
This module provides a Perl interface to the libbam library for indexed
and unindexed SAM/BAM sequence alignment databases. It provides support
for retrieving information on individual alignments, read pairs, and
alignment coverage information across large regions. It also provides
callback functionality for calling SNPs and performing other base-by-
base functions. Most operations are compatible with the BioPerl
Bio::SeqFeatureI interface, allowing BAM files to be used as a backend
to the GBrowse genome browser application (gmod.sourceforge.net).
The high-level API
The high-level API provides a BioPerl-compatible interface to indexed
BAM files. The BAM database is treated as a collection of
Bio::SeqFeatureI features, and can be searched for features by name,
location, type and combinations of feature tags such as whether the
alignment is part of a mate-pair.
When opening a BAM database using the high-level API, you provide the
pathnames of two files: the FASTA file that contains the reference
genome sequence, and the BAM file that contains the query sequences and
their alignments. If either of the two files needs to be indexed, the
indexing will happen automatically. You can then query the database for
alignment features by combinations of name, position, type, and feature
tag.
The high-level API provides access to up to four feature "types":
* "match": The "raw" unpaired alignment between a read and the
reference sequence.
* "read_pair": Paired alignments; a single composite
feature that contains two subfeatures for the alignments of each
of the mates in a mate pair.
* "coverage": A feature that spans a region of interest that contains
numeric information on the coverage of reads across the region.
* "region": A way of retrieving information about the reference
sequence. Searching for features of type "region" will return a
list of chromosomes or contigs in the reference sequence, rather
than read alignments.
* "chromosome": A synonym for "region".
Features can be en masse in a single call, retrieved in a memory-
efficient streaming basis using an iterator, or interrogated using a
filehandle that return a series of TAM-format lines.
SAM alignment flags can be retrieved using BioPerl's feature "tag"
mechanism. For example, to interrogate the FIRST_MATE flag, one fetches
the "FIRST_MATE" tag:
warn "aye aye captain!" if $alignment->get_tag_values('FIRST_MATE');
The Bio::SeqFeatureI interface has been extended to retrieve all flags
as a compact human-readable string, and to return the CIGAR alignment
in a variety of formats.
Split alignments, such as reads that cover introns, are dealt with in
one of two ways. The default is to leave split alignments alone: they
can be detected by one or more "N" operations in the CIGAR string.
Optionally, you can choose to have the API split these alignments
across two or more subfeatures; the CIGAR strings of these split
alignments will be adjusted accordingly.
Interface to the pileup routines The API provides you with access to
the samtools "pileup" API. This gives you the ability to write a
callback that will be invoked on every column of the alignment for the
purpose of calculating coverage, quality score metrics, or SNP calling.
Access to the reference sequence When you create the Bio::DB::Sam
object, you can pass the path to a FASTA file containing the reference
sequence. Alternatively, you may pass an object that knows how to
retrieve DNA sequences across a range via the seq() of fetch_seq()
methods, as described under new().
If the SAM/BAM file has MD tags, then these tags will be used to
reconstruct the reference sequence when necessary, in which case you
can completely omit the -fasta argument. Note that not all SAM/BAM
files have MD tags, and those that do may not use them correctly due to
the newness of this part of the SAM spec. You may wish to populate
these tags using samtools' "calmd" command.
If the -fasta argument is omitted and no MD tags are present, then the
reference sequence will be returned as 'N'.
The main object classes that you will be dealing with in the high-level
API are as follows:
* Bio::DB::Sam-- A collection of alignments and reference sequences.
* Bio::DB::Bam::Alignment -- The alignment between a query and the reference.
* Bio::DB::Bam::Query -- An object corresponding to the query sequence in
which both (+) and (-) strand alignments are
shown in the reference (+) strand.
* Bio::DB::Bam::Target -- An interface to the query sequence in which
(-) strand alignments are shown in reverse
complement
You may encounter other classes as well. These include:
* Bio::DB::Sam::Segment -- This corresponds to a region on the reference
sequence.
* Bio::DB::Sam::Constants -- This defines CIGAR symbol constants and flags.
* Bio::DB::Bam::AlignWrapper -- An alignment helper object that adds split
alignment functionality. See Bio::DB::Bam::Alignment
for the documentation on using it.
* Bio::DB::Bam::ReadIterator -- An iterator that mediates the one-feature-at-a-time
retrieval mechanism.
* Bio::DB::Bam::FetchIterator -- Another iterator for feature-at-a-time retrieval.
The low-level API
The low-level API closely mirrors that of the libbam library. It
provides the ability to open TAM and BAM files, read and write to them,
build indexes, and perform searches across them. There is less overhead
to using the API because there is very little Perl memory management,
but the functions are less convenient to use. Some operations, such as
writing BAM files, are only available through the low-level API.
The classes you will be interacting with in the low-level API are as
follows:
* Bio::DB::Tam -- Methods that read and write TAM (text SAM) files.
* Bio::DB::Bam -- Methods that read and write BAM (binary SAM) files.
* Bio::DB::Bam::Header -- Methods for manipulating the BAM file header.
* Bio::DB::Bam::Index -- Methods for retrieving data from indexed BAM files.
* Bio::DB::Bam::Alignment -- Methods for manipulating alignment data.
* Bio::DB::Bam::Pileup -- Methods for manipulating the pileup data structure.
* Bio::DB::Sam::Fai -- Methods for creating and reading from indexed Fasta
files.
=head1 METHODS
We cover the high-level API first. The high-level API code can be found
in the files Bio/DB/Sam.pm, Bio/DB/Sam/*.pm, and Bio/DB/Bam/*.pm.
Bio::DB::Sam Constructor and basic accessors
$sam = Bio::DB::Sam->new(%options)
The Bio::DB::Sam object combines a Fasta file of the reference
sequences with a BAM file to allow for convenient retrieval of
human-readable sequence IDs and reference sequences. The new()
constructor accepts a -name=>value style list of options as
follows:
Option Description
-------------------
-bam Path to the BAM file that contains the
alignments (required). When using samtools 0.1.6
or higher, an http: or ftp: URL is accepted.
-fasta Path to the Fasta file that contains
the reference sequences (optional). Alternatively,
you may pass any object that supports a seq()
or fetch_seq() method and takes the three arguments
($seq_id,$start,$end).
-expand_flags A boolean value. If true then the standard
alignment flags will be broken out as
individual tags such as 'M_UNMAPPED' (default
false).
-split_splices A boolean value. If true, then alignments that
are split across splices will be broken out
into a single alignment containing two sub-
alignments (default false).
-split The same as -split_splices.
-autoindex Create a BAM index file if one does not exist
or the current one has a modification date
earlier than the BAM file.
An example of a typical new() constructor invocation is:
$sam = Bio::DB::Sam->new(-fasta => '/home/projects/genomes/hu17.fa',
-bam => '/home/projects/alignments/ej88.bam',
-expand_flags => 1,
-split_splices => 1);
If the -fasta argument is present, then you will be able to use the
interface to fetch the reference sequence's bases. Otherwise, calls
that return the reference sequence will return sequences consisting
entirely of "N".
-expand_flags option, if true, has the effect of turning each of
the standard SAM flags into a separately retrievable tag in the
Bio::SeqFeatureI interface. Otherwise, the standard flags will be
concatenated in easily parseable form as a tag named "FLAGS". See
get_all_tags() and get_tag_values() for more information.
Any two-letter extension flags, such as H0 or H1, will always
appear as separate tags regardless of the setting.
-split_splices has the effect of breaking up alignments that
contain an "N" operation into subparts for more convenient
manipulation. For example, if you have both paired reads and
spliced alignments in the BAM file, the following code shows the
subpart relationships:
$pair = $sam->get_feature_by_name('E113:01:01:23');
@mates = $pair->get_SeqFeatures;
@mate1_parts = $mates[0]->get_SeqFeatures;
@mate2_parts = $mates[1]->get_SeqFeatures;
Because there is some overhead to splitting up the spliced
alignments, this option is false by default.
Remote access to BAM files located on an HTTP or FTP server is
possible when using the Samtools library version 0.1.6 or higher.
Simply replace the path to the BAM file with the appropriate URL.
Note that incorrect URLs may lead to a core dump.
It is not currently possible to refer to a remote FASTA file. These
will have to be downloaded locally and indexed before using.
$flag = $sam->expand_flags([$new_value])
Get or set the expand_flags option. This can be done after object
creation and will have an immediate effect on all alignments
fetched from the BAM file.
$flag = $sam->split_splices([$new_value])
Get or set the split_splices option. This can be done after object
creation and will affect all alignments fetched from the BAM file
subsequently.
$header = $sam->header
Return the Bio::DB::Bam::Header object associated with the BAM
file. You can manipulate the header using the low-level API.
$bam = $sam->bam
Returns the low-level Bio::DB::Bam object associated with the
opened file.
$fai = $sam->fai
Returns the Bio::DB::Sam::Fai object associated with the Fasta
file. You can then manipuate this object with the low-level API.
The index will be built automatically for you if it does not
already exist. If index building is necessarily, the process will
need write privileges to the same directory in which the Fasta file
resides.> If the process does not have write permission, then the
call will fail. Unfortunately, the BAM library does not do great
error recovery for this condition, and you may experience a core
dump. This is not trappable via an eval {}.
$bai = $sam->bam_index
Return the Bio::DB::Bam::Index object associated with the BAM file.
The BAM file index will be built automatically for you if it does
not already exist. In addition, if the BAM file is not already
sorted by chromosome and coordinate, it will be sorted
automatically, an operation that consumes significant time and disk
space. The current process must have write permission to the
directory in which the BAM file resides in order for this to work.>
In case of a permissions problem, the Perl library will catch the
error and die. You can trap it with an eval {}.
$sam->clone
Bio::DB::SAM objects are not stable across fork() operations. If
you fork, you must call clone() either in the parent or the child
process before attempting to call any methods.
Getting information about reference sequences
The Bio::DB::Sam object provides the following methods for getting
information about the reference sequence(s) contained in the associated
Fasta file.
@seq_ids = $sam->seq_ids
Returns an unsorted list of the IDs of the reference sequences
(known elsewhere in this document as seq_ids). This is the same as
the identifier following the ">" sign in the Fasta file (e.g.
"chr1").
$num_targets = $sam->n_targets
Return the number of reference sequences.
$length = $sam->length('seqid')
Returns the length of the reference sequence named "seqid".
$seq_id = $sam->target_name($tid)
Translates a numeric target ID (TID) returned by the low-level API
into a seq_id used by the high-level API.
$length = $sam->target_len($tid)
Translates a numeric target ID (TID) from the low-level API to a
sequence length.
$dna = $sam->seq($seqid,$start,$end)
Returns the DNA across the region from start to end on reference
seqid. Note that this is a string, not a Bio::PrimarySeq object. If
no -fasta path was passed when the sam object was created, then you
will receive a series of N nucleotides of the requested length.
Creating and querying segments
Bio::DB::Sam::Segment objects refer regions on the reference sequence.
They can be used to retrieve the sequence of the reference, as well as
alignments that overlap with the region.
$segment = $sam->segment($seqid,$start,$end);
$segment = $sam->segment(-seq_id=>'chr1',-start=>5000,-end=>6000);
Segments are created using the Bio:DB::Sam->segment() method. It
can be called using one to three positional arguments corresponding
to the seq_id of the reference sequence, and optionally the start
and end positions of a subregion on the sequence. If the start
and/or end are undefined, they will be replaced with the beginning
and end of the sequence respectively.
Alternatively, you may call segment() with named -seq_id, -start
and -end arguments.
All coordinates are 1-based.
$seqid = $segment->seq_id
Return the segment's sequence ID.
$start = $segment->start
Return the segment's start position.
$end = $segment->end
Return the segment's end position.
$strand = $segment->strand
Return the strand of the segment (always 0).
$length = $segment->length
Return the length of the segment.
$dna = $segment->dna
Return the DNA string for the reference sequence under this
segment.
$seq = $segment->seq
Return a Bio::PrimarySeq object corresponding to the sequence of
the reference under this segment. You can get the actual DNA string
in this redundant-looking way:
$dna = $segment->seq->seq
The advantage of working with a Bio::PrimarySeq object is that you
can perform operations on it, including taking its reverse
complement and subsequences.
@alignments = $segment->features(%args)
Return alignments that overlap the segment in the associated BAM
file. The optional %args list allows you to filter features by
name, tag or other attributes. See the documentation of the
Bio::DB::Sam->features() method for the full list of options. Here
are some typical examples:
# get all the overlapping alignments
@all_alignments = $segment->features;
# get an iterator across the alignments
my $iterator = $segment->features(-iterator=>1);
while (my $align = $iterator->next_seq) { do something }
# get a TAM filehandle across the alignments
my $fh = $segment->features(-fh=>1);
while (<$fh>) { print }
# get only the alignments with unmapped mates
my @unmapped = $segment->features(-flags=>{M_UNMAPPED=>1});
# get coverage across this region
my ($coverage) = $segment->features('coverage');
my @data_points = $coverage->coverage;
# grep through features using a coderef
my @reverse_alignments = $segment->features(
-filter => sub {
my $a = shift;
return $a->strand < 0;
});
$tag = $segment->primary_tag
$tag = $segment->source_tag
Return the strings "region" and "sam/bam" respectively. These
methods allow the segment to be passed to BioPerl methods that
expect Bio::SeqFeatureI objects.
$segment->name, $segment->display_name, $segment->get_SeqFeatures,
$segment->get_tag_values
These methods are provided for Bio::SeqFeatureI compatibility and
don't do anything of interest.
Retrieving alignments, mate pairs and coverage information
The features() method is an all-purpose tool for retrieving alignment
information from the SAM/BAM database. In addition, the methods
get_features_by_name(), get_features_by_location() and others provide
convenient shortcuts to features().
These methods either return a list of features, an iterator across a
list of features, or a filehandle opened on a pseudo-TAM file.
@features = $sam->features(%options)
$iterator = $sam->features(-iterator=>1,%more_options)
$filehandle = $sam->features(-fh=>1,%more_options)
@features = $sam->features('type1','type2'...)
This is the all-purpose interface for fetching alignments and other
types of features from the database. Arguments are a -name=>value
option list selected from the following list of options:
Option Description
-------------------
-type Filter on features of a given type. You may provide
either a scalar typename, or a reference to an
array of desired feature types. Valid types are
"match", "read_pair", "coverage" and "chromosome."
See below for a full explanation of feature types.
-name Filter on reads with the designated name. Note that
this can be a slow operation unless accompanied by
the feature location as well.
-seq_id Filter on features that align to seq_id between start
-start and end. -start and -end must be used in conjunction
-end with -seq_id. If -start and/or -end are absent, they
will default to 1 and the end of the reference
sequence, respectively.
-flags Filter features that match a list of one or more
flags. See below for the format.
-attributes The same as -flags, for compatibility with other
-tags APIs.
-filter Filter on features with a coderef. The coderef will
receive a single argument consisting of the feature
and should return true to keep the feature, or false
to discard it.
-iterator Instead of returning a list of features, return an
iterator across the results. To retrieve the results,
call the iterator's next_seq() method repeatedly
until it returns undef to indicate that no more
matching features remain.
-fh Instead of returning a list of features, return a
filehandle. Read from the filehandle to retrieve
each of the results in TAM format, one alignment
per line read. This only works for features of type
"match."
The high-level API introduces the concept of a feature "type" in
order to provide several convenience functions. You specify types
by using the optional -type argument. The following types are
currently supported:
match. The "match" type corresponds to the unprocessed SAM
alignment. It will retrieve single reads, either mapped or
unmapped. Each match feature's primary_tag() method will return the
string "match." The features returned by this call are of type
Bio::DB::Bam::AlignWrapper.
read_pair. The "paired_end" type causes the sam interface to find
and merge together mate pairs. Fetching this type of feature will
yield a series of Bio::SeqFeatureI objects, each as long as the
total distance on the reference sequence spanned by the mate pairs.
The top-level feature is of type Bio::SeqFeature::Lite; it contains
two Bio::DB::Bam::AlignWrapper subparts.
Call get_SeqFeatures() to get the two individual reads. Example:
my @pairs = $sam->features(-type=>'read_pair');
my $p = $pairs[0];
my $i_length = $p->length;
my @ends = $p->get_SeqFeatures;
my $left = $ends[0]->start;
my $right = $ends[1]->end;
coverage. The "coverage" type causes the sam interface to calculate
coverage across the designated region. It only works properly if
accompanied by the desired location of the coverage graph; -seq_id
is a mandatory argument for coverage calculation, and -start and
-end are optional. The call will return a single Bio::SeqFeatureI
object whose primary_tag() is "coverage." To recover the coverage
data, call the object's coverage() method to obtain an array (list
context) or arrayref (scalar context) of coverage counts across the
region of interest:
my ($coverage) = $sam->features(-type=>'coverage',-seq_id=>'seq1');
my @data = $coverage->coverage;
my $total;
for (@data) { $total += $_ }
my $average_coverage = $total/@data;
By default the coverage graph will be at the base pair level. So
for a region 5000 bp wide, coverage() will return an array or
arrayref with exactly 5000 elements. However, you also have the
option of calculating the coverage across larger bins. Simply
append the number of intervals you are interested to the "coverage"
typename. For example, fetching "coverage:500" will return a
feature whose coverage() method will return the coverage across 500
intervals.
chromosome or region. The "chromosome" or "region" type are
interchangeable. They ask the sam interface to construct
Bio::DB::Sam::Segment representing the reference sequences. These
two calls give similar results:
my $segment = $sam->segment('seq2',1=>500);
my ($seg) = $sam->features(-type=>'chromosome',
-seq_id=>'seq2',-start=>1,-end=>500);
Due to an unresolved bug, you cannot fetch chromosome features in
the same call with matches and other feature types call.
Specifically, this works as expected:
my @chromosomes = $sam->features (-type=>'chromosome');
But this doesn't (as of 18 June 2009):
my @chromosomes_and_matches = $sam->features(-type=>['match','chromosome']);
If no -type argument is provided, then features() defaults to
finding features of type "match."
You may call features() with a plain list of strings (positional
arguments, not -type=>value arguments). This will be interpreted as
a list of feature types to return:
my ($coverage) = $sam->features('coverage')
For a description of the methods available in the features returned
from this call, please see Bio::SeqfeatureI and
Bio::DB::Bam::Alignment.
You can filter "match" and "read_pair" features by name, location
and/or flags. The name and flag filters are not very efficient.
Unless they are combined with a location filter, they will initiate
an exhaustive search of the BAM database.
Name filters are case-insensitive, and allow you to use shell-style
"*" and "?" wildcards. Flag filters created with the -flag,
-attribute or -tag options have the following syntax:
-flag => { FLAG_NAME_1 => ['list','of','possible','values'],
FLAG_NAME_2 => ['list','of','possible','values'],
...
}
The value of -flag is a hash reference in which the keys are flag
names and the values are array references containing lists of
acceptable values. The list of values are OR'd with each other, and
the flag names are AND'd with each other.
The -filter option provides a completely generic filtering
interface. Provide a reference to a subroutine. It will be called
once for each potential feature. Return true to keep the feature,
or false to discard it. Here is an example of how to find all
matches whose alignment quality scores are greater than 80.
@features = $sam->features(-filter=>sub {shift->qual > 80} );
By default, features() returns a list of all matching features. You
may instead request an iterator across the results list by passing
-iterator=>1. This will give you an object that has a single
method, next_seq():
my $high_qual = $sam->features(-filter => sub {shift->qual > 80},
-iterator=> 1 );
while (my $feature = $high_qual->next_seq) {
# do something with the alignment
}
Similarly, by passing a true value to the argument -fh, you can
obtain a filehandle to a virtual TAM file. This only works with the
"match" feature type:
my $high_qual = $sam->features(-filter => sub {shift->qual > 80},
-fh => 1 );
while (my $tam_line = <$high_qual>) {
chomp($tam_line);
# do something with it
}
@features = $sam->get_features_by_name($name)
Convenience method. The same as calling
$sam->features(-name=>$name);
$feature = $sam->get_feature_by_name($name)
Convenience method. The same as ($sam->features(-name=>$name))[0].
@features = $sam->get_features_by_location($seqid,$start,$end)
Convenience method. The same as calling
$sam->features(-seq_id=>$seqid,-start=>$start,-end=>$end).
@features = $sam->get_features_by_flag(%flags)
Convenience method. The same as calling
$sam->features(-flags=>\%flags). This method is also called
get_features_by_attribute() and get_features_by_tag(). Example:
@features = $sam->get_features_by_flag(H0=>1)
$feature = $sam->get_feature_by_id($id)
The high-level API assigns each feature a unique ID composed of its
read name, position and strand and returns it when you call the
feature's primary_id() method. Given that ID, this method returns
the feature.
$iterator = $sam->get_seq_stream(%options)
Convenience method. This is the same as calling
$sam->features(%options,-iterator=>1).
$fh = $sam->get_seq_fh(%options)
Convenience method. This is the same as calling
$sam->features(%options,-fh=>1).
$fh = $sam->tam_fh
Convenience method. It is the same as calling
$sam->features(-fh=>1).
@types = $sam->types
This method returns the list of feature types (e.g. "read_pair")
returned by the current version of the interface.
The generic fetch() and pileup() methods
Lastly, the high-level API supports two methods for rapidly traversing
indexed BAM databases.
$sam->fetch($region,$callback)
This method, which is named after the native bam_fetch() function
in the C interface, traverses the indicated region and invokes a
callback code reference on each match. Specify a region using the
BAM syntax "seqid:start-end", or either of the alternative syntaxes
"seqid:start..end" and "seqid:start,end". If start and end are
absent, then the entire reference sequence is traversed. If end is
absent, then the end of the reference sequence is assumed.
The callback will be called repeatedly with a
Bio::DB::Bam::AlignWrapper on the argument list.
Example:
$sam->fetch('seq1:600-700',
sub {
my $a = shift;
print $a->display_name,' ',$a->cigar_str,"\n";
});
Note that the fetch() operation works on reads that overlap the
indicated region. Therefore the callback may be called for reads
that align to the reference at positions that start before or end
after the indicated region.
$sam->pileup($region,$callback [,$keep_level])
This method, which is named after the native bam_lpileupfile()
function in the C interfaces, traverses the indicated region and
generates a "pileup" of all the mapped reads that cover it. The
user-provided callback function is then invoked on each position of
the alignment along with a data structure that provides access to
the individual aligned reads.
As with fetch(), the region is specified as a string in the format
"seqid:start-end", "seqid:start..end" or "seqid:start,end".
The callback is a coderef that will be invoked with three
arguments: the seq_id of the reference sequence, the current
position on the reference (in 1-based coordinates!), and a
reference to an array of Bio::DB::Bam::Pileup objects. Here is the
typical call signature:
sub {
my ($seqid,$pos,$pileup) = @_;
# do something
}
For example, if you call pileup on the region "seq1:501-600", then
the callback will be invoked for all reads that overlap the
indicated region. The first invocation of the callback will
typically have a $pos argument somewhat to the left of the desired
region and the last call will be somewhat to the right. You may
wish to ignore positions that are outside of the requested region.
Also be aware that the reference sequence position uses 1-based
coordinates, which is different from the low-level interface, which
use 0-based coordinates.
The optional $keep_level argument, if true, asks the BAM library to
keep track of the level of the read in the multiple alignment, an
operation that generates some overhead. This is mostly useful for
text alignment viewers, and so is off by default.
The size of the $pileup array reference indicates the read coverage
at that position. Here is a simple average coverage calculator:
my $depth = 0;
my $positions = 0;
my $callback = sub {
my ($seqid,$pos,$pileup) = @_;
next unless $pos >= 501 && $pos <= 600;
$positions++;
$depth += @$pileup;
}
$sam->pileup('seq1:501-600',$callback);
print "coverage = ",$depth/$positions;
Each Bio::DB::Bam::Pileup object describes the position of a read
in the alignment. Briefly, Bio::DB::Bam::Pileup has the following
methods:
$pileup->alignment The alignment at this level (a
Bio::DB::Bam::AlignWrapper object).
$pileup->qpos The position of the read base at the pileup site,
in 0-based coordinates.
$pileup->pos The position of the read base at the pileup site,
in 1-based coordinates;
$pileup->level The level of the read in the multiple alignment
view. Note that this field is only valid when
$keep_level is true.
$pileup->indel Length of the indel at this position: 0 for no indel, positive
for an insertion (relative to the reference), negative for a
deletion (relative to the reference.)
$pileup->is_del True if the base on the padded read is a deletion.
$pileup->is_refskip True if the base on the padded read is a gap relative to the reference (denoted as < or > in the pileup)
$pileup->is_head Undocumented field in the bam.h header file.
$pileup->is_tail Undocumented field in the bam.h header file.
See "Examples" for a very simple SNP caller.
$sam->fast_pileup($region,$callback [,$keep_level])
This is identical to pileup() except that the pileup object returns
low-level Bio::DB::Bam::Alignment objects rather than the higher-
level Bio::DB::Bam::AlignWrapper objects. This makes it roughly 50%
faster, but you lose the align objects' seq_id() and
get_tag_values() methods. As a compensation, the callback receives
an additional argument corresponding to the Bio::DB::Sam object.
You can use this to create AlignWrapper objects on an as needed
basis:
my $callback = sub {
my($seqid,$pos,$pileup,$sam) = @_;
for my $p (@$pileup) {
my $alignment = $p->alignment;
my $wrapper = Bio::DB::Bam::AlignWrapper->new($alignment,$sam);
my $has_mate = $wrapper->get_tag_values('PAIRED');
}
};
Bio::DB::Sam->max_pileup_cnt([$new_cnt])
$sam->max_pileup_cnt([$new_cnt])
The Samtools library caps pileups at a set level, defaulting to
8000. The callback will not be invoked on a single position more
than the level set by the cap, even if there are more reads. Called
with no arguments, this method returns the current cap value.
Called with a numeric argument, it changes the cap. There is
currently no way to specify an unlimited cap.
This method can be called as an instance method or a class method.
$sam->coverage2BedGraph([$fh])
This special-purpose method will compute a four-column BED graph of
the coverage across the entire SAM/BAM file and print it to STDOUT.
You may provide a filehandle to redirect output to a file or pipe.
The next sections correspond to the low-level API, which let you create
and manipulate Perl objects that correspond directly to data structures
in the C interface. A major difference between the high and low level
APIs is that in the high-level API, the reference sequence is
identified using a human-readable seq_id. However, in the low-level
API, the reference is identified using a numeric target ID ("tid"). The
target ID is established during the creation of the BAM file and is a
small 0-based integer index. The Bio::DB::Bam::Header object provides
methods for converting from seq_ids to tids.
Indexed Fasta Files
These methods relate to the BAM library's indexed Fasta (".fai") files.
$fai = Bio::DB::Sam::Fai->load('/path/to/file.fa')
Load an indexed Fasta file and return the object corresponding to
it. If the index does not exist, it will be created automatically.
Note that you pass the path to the Fasta file, not the index.
For consistency with Bio::DB::Bam->open() this method is also
called open().
$dna_string = $fai->fetch("seqid:start-end")
Given a sequence ID contained in the Fasta file and optionally a
subrange in the form "start-end", finds the indicated subsequence
and returns it as a string.
TAM Files
These methods provide interfaces to the "TAM" text version of SAM
files; they often have a .sam extension.
$tam = Bio::DB::Tam->open('/path/to/file.sam')
Given the path to a SAM file, opens it for reading. The file can be
compressed with gzip if desired.
$header = $tam->header_read()
Create and return a Bio::DB::Bam::Header object from the
information contained within @SQ header lines of the Sam file. If
there are no @SQ lines, then the header will not be useful, and you
should call header_read2() to generate the missing information from
the appropriate indexed Fasta file. Here is some code to illustrate
the suggested logic:
my $header = $tam->header_read;
unless ($header->n_targets > 0) {
$header = $tam->header_read2('/path/to/file.fa.fai');
}
$header = $tam->header_read2('/path/to/file.fa.fai')
Create and return a Bio::DB::Bam::Header object from the
information contained within the indexed Fasta file of the
reference sequences. Note that you have to pass the path to the
.fai file, and not the .fa file. The header object contains
information on the reference sequence names and lengths.
$bytes = $tam->read1($header,$alignment)
Given a Bio::DB::Bam::Header object, such as the one created by
header_read2(), and a Bio::DB::Bam::Alignment object created by
Bio::DB::Bam::Alignment->new(), reads one line of alignment
information into the alignment object from the TAM file and returns
a status code. The result code will be the number of bytes read.
BAM Files
These methods provide interfaces to the "BAM" binary version of SAM.
They usually have a .bam extension.
$bam = Bio::DB::Bam->open('/path/to/file.bam' [,$mode])
Open up the BAM file at the indicated path. Mode, if present, must
be one of the file stream open flags ("r", "w", "a", "r+", etc.).
If absent, mode defaults to "r".
Note that Bio::DB::Bam objects are not stable across fork()
operations. If you fork, and intend to use the object in both
parent and child, you must reopen the Bio::DB::Bam in either the
child or the parent (but not both) before attempting to call any of
the object's methods.
The path may be an http: or ftp: URL, in which case a copy of the
index file will be downloaded to the current working directory (see
below) and all accesses will be performed on the remote BAM file.
Example:
$bam = Bio::DB::Bam->open('http://some.site.com/nextgen/chr1_bowtie.bam');
$header = $bam->header()
Given an open BAM file, return a Bio::DB::Bam::Header object
containing information about the reference sequence(s).
$status_code = $bam->header_write($header)
Given a Bio::DB::Bam::Header object and a BAM file opened in write
mode, write the header to the file. If the write fails the process
will be terminated at the C layer. The result code is (currently)
always zero.
$integer = $bam->tell()
Return the current position of the BAM file read/write pointer.
$bam->seek($integer)
Set the current position of the BAM file read/write pointer.
$alignment = $bam->read1()
Read one alignment from the BAM file and return it as a
Bio::DB::Bam::Alignment object.
$bytes = $bam->write1($alignment)
Given a BAM file that has been opened in write mode and a
Bio::DB::Bam::Alignment object, write the alignment to the BAM file
and return the number of bytes successfully written.
Bio::DB::Bam->sort_core($by_qname,$path,$prefix,$max_mem)
Attempt to sort a BAM file by chromosomal location or name and
create a new sorted BAM file. Arguments are as follows:
Argument Description
-------------------
$by_qname If true, sort by read name rather than chromosomal
location.
$path Path to the BAM file
$prefix Prefix to use for the new sorted file. For example,
passing "foo" will result in a BAM file named
"foo.bam".
$max_mem Maximum core memory to use for the sort. If the sort
requires more than this amount of memory, intermediate
sort files will be written to disk. The default, if not
provided is 500M.
BAM index methods
The Bio::DB::Bam::Index object provides access to BAM index (.bai)
files.
$status_code = Bio::DB::Bam->index_build('/path/to/file.bam')
Given the path to a .bam file, this function attempts to build a
".bai" index. The process in which the .bam file exists must be
writable by the current process and there must be sufficient disk
space for the operation or the process will be terminated in the C
library layer. The result code is currently always zero, but in the
future may return a negative value to indicate failure.
$index = Bio::DB::Bam->index('/path/to/file.bam',$reindex)
Attempt to open the index for the indicated BAM file. If $reindex
is true, and the index either does not exist or is out of date with
respect to the BAM file (by checking modification dates), then
attempt to rebuild the index. Will throw an exception if the index
does not exist or if attempting to rebuild the index was
unsuccessful.
$index = Bio::DB::Bam->index_open('/path/to/file.bam')
Attempt to open the index file for a BAM file, returning a
Bio::DB::Bam::Index object. The filename path to use is the .bam
file, not the .bai file.
$index = Bio::DB::Bam->index_open_in_safewd('/path/to/file.bam'
[,$mode])
When opening a remote BAM file, you may not wish for the index to
be downloaded to the current working directory. This version of
index_open copies the index into the directory indicated by the
TMPDIR environment variable or the system-defined /tmp directory if
not present. You may change the environment variable just before
the call to change its behavior.
$code = $index->fetch($bam,$tid,$start,$end,$callback
[,$callback_data])
This is the low-level equivalent of the $sam->fetch() function
described for the high-level API. Given a open BAM file object, the
numeric ID of the reference sequence, start and end ranges on the
reference, and a coderef, this function will traverse the region
and repeatedly invoke the coderef with each Bio::DB::Bam::Alignment
object that overlaps the region.
Arguments:
Argument Description
-------------------
$bam The Bio::DB::Bam object that corresponds to the
index object.
$tid The target ID of the reference sequence. This can
be obtained by calling $header->parse_region() with
an appropriate opened Bio::DB::Bam::Header object.
$start The start and end positions of the desired range on
the reference sequence given by $tid, in 0-based
$end coordinates. Like the $tid, these can be obtained from
$header->parse_region().
$callback A coderef that will be called for each read overlapping
the designated region.
$callback_data Any arbitrary Perl data that you wish to pass to the
$callback (optional).
The coderef's call signature should look like this:
my $callback = sub {
my ($alignment,$data) = @_;
...
}
The first argument is a Bio::DB::Bam::Alignment object. The second
is the callback data (if any) passed to fetch().
Fetch() returns an integer code, but its meaning is not described
in the SAM/BAM C library documentation.
$index->pileup($bam,$tid,$start,$end,$callback [,$callback_data])
This is the low-level version of the pileup() method, which allows
you to invoke a coderef for every position in a BAM alignment.
Arguments are:
Argument Description
-------------------
$bam The Bio::DB::Bam object that corresponds to the
index object.
$tid The target ID of the reference sequence. This can
be obtained by calling $header->parse_region() with
an appropriate opened Bio::DB::Bam::Header object.
$start The start and end positions of the desired range on
the reference sequence given by $tid, in 0-based
$end coordinates. Like the $tid, these can be obtained from
$header->parse_region().
$callback A coderef that will be called for each position of the
alignment across the designated region.
$callback_data Any arbitrary Perl data that you wish to pass to the
$callback (optional).
The callback will be invoked with four arguments corresponding to
the numeric sequence ID of the reference sequence, the zero-based
position on the alignment, an arrayref of Bio::DB::Bam::Pileup
objects, and the callback data, if any. A typical call signature
will be this:
$callback = sub {
my ($tid,$pos,$pileups,$callback_data) = @_;
for my $pileup (@$pileups) {
# do something
};
Note that the position argument is zero-based rather than 1-based,
as it is in the high-level API.
The Bio::DB::Bam::Pileup object was described earlier in the
description of the high-level pileup() method.
$coverage = $index->coverage($bam,$tid,$start,$end [,$bins [,maxcnt]])
Calculate coverage for the region on the target sequence given by
$tid between positions $start and $end (zero-based coordinates).
This method will return an array reference equal to the size of the
region (by default). Each element of the array will be an integer
indicating the number of reads aligning over that position. If you
provide an option binsize in $bins, the array will be $bins
elements in length, and each element will contain the average
coverage over that region as a floating point number.
By default, the underlying Samtools library caps coverage counting
at a fixed value of 8000. You may change this default by providing
an optional numeric sixth value, which changes the cap for the
duration of the call, or by invoking
Bio::DB::Sam->max_pileup_cnt($new_value), which changes the cap
permanently. Unfortunately there is no way of specifying that you
want an unlimited cap.
BAM header methods
The Bio::DB::Bam::Header object contains information regarding the
reference sequence(s) used to construct the corresponding TAM or BAM
file. It is most frequently used to translate between numeric target
IDs and human-readable seq_ids. Headers can be created either from
reading from a .fai file with the Bio::DB::Tam->header_read2() method,
or by reading from a BAM file using Bio::DB::Bam->header(). You can
also create header objects from scratch, although there is not much
that you can do with such objects at this point.
$header = Bio::DB::Bam::Header->new()
Return a new, empty, header object.
$n_targets = $header->n_targets
Return the number of reference sequences in the database.
$name_arrayref = $header->target_name
Return a reference to an array of reference sequence names,
corresponding to the high-level API's seq_ids.
To convert from a target ID to a seq_id, simply index into this
array:
$seq_id = $header->target_name->[$tid];
$length_arrayref = $header->target_len
Return a reference to an array of reference sequence lengths. To
get the length of the sequence corresponding to $tid, just index
into the array returned by target_len():
$length = $header->target_len->[$tid];
$text = $header->text =item $header->text("new value")
Read the text portion of the BAM header. The text can be replaced
by providing the replacement string as an argument. Note that you
should follow the header conventions when replacing the header
text. No parsing or other error-checking is performed.
($tid,$start,$end) = $header->parse_region("seq_id:start-end")
Given a string in the format "seqid:start-end" (using a human-
readable seq_id and 1-based start and end coordinates), parse the
string and return the target ID and start and end positions in
0-based coordinates. If the range is omitted, then the start and
end coordinates of the entire sequence is returned. If only the end
position is omitted, then the end of the sequence is assumed.
$header->view1($alignment)
This method will accept a Bio::DB::Bam::Alignment object, convert
it to a line of TAM output, and write the output to STDOUT. In the
low-level API there is currently no way to send the output to a
different filehandle or capture it as a string.
Bio::DB::Bam::Pileup methods
An array of Bio::DB::Bam::Pileup object is passed to the pileup()
callback for each position of a multi-read alignment. Each pileup
object contains information about the alignment of a single read at a
single position.
$alignment = $pileup->alignment
Return the Bio::DB::Bam::Alignment object at this level. This
provides you with access to the aligning read.
$alignment = $pileup->b
An alias for alignment(), provided for compatibility with the C
API.
$pos = $pileup->qpos
The position of the aligning base in the read in zero-based
coordinates.
$pos = $pileup->pos
The position of the aligning base in 1-based coordinates.
$level = $pileup->level
The "level" of the read in the BAM-generated text display of the
alignment.
$indel = $pileup->indel
Length of the indel at this position: 0 for no indel, positive for
an insertion (relative to the reference), negative for a deletion
(relative to the reference sequence.)
$flag = $pileup->is_del
True if the base on the padded read is a deletion.
$flag = $pileup->is_refskip
True if the base on the padded read is a gap relative to the
reference (denoted as < or > in the pileup)
$flag = $pileup->is_head
$flag = $pileup->is_del
These fields are undocumented in the BAM documentation, but are
exported to the Perl API just in case.
The alignment objects
Please see Bio::DB::Bam::Alignment for documentation of the
Bio::DB::Bam::Alignment and Bio::DB::Bam::AlignWrapper objects.
EXAMPLES
For illustrative purposes only, here is an extremely stupid SNP caller
that tallies up bases that are q>20 and calls a SNP if there are at
least 4 non-N/non-indel bases at the position and at least 25% of them
are a non-reference base.
my @SNPs; # this will be list of SNPs
my $snp_caller = sub {
my ($seqid,$pos,$p) = @_;
my $refbase = $sam->segment($seqid,$pos,$pos)->dna;
my ($total,$different);
for my $pileup (@$p) {
my $b = $pileup->alignment;
next if $pileup->indel or $pileup->is_refskip; # don't deal with these ;-)
my $qbase = substr($b->qseq,$pileup->qpos,1);
next if $qbase =~ /[nN]/;
my $qscore = $b->qscore->[$pileup->qpos];
next unless $qscore > 25;
$total++;
$different++ if $refbase ne $qbase;
}
if ($total >= 4 && $different/$total >= 0.25) {
push @SNPs,"$seqid:$pos";
}
};
$sam->pileup('seq1',$snp_caller);
print "Found SNPs: @SNPs\n";
GBrowse Compatibility
The Bio::DB::Sam interface can be used as a backend to GBrowse
(gmod.sourceforge.net/gbrowse). GBrowse can calculate and display
coverage graphs across large regions, alignment cartoons across
intermediate size regions, and detailed base-pair level alignments
across small regions.
Here is a typical configuration for a BAM database that contains
information from a shotgun genomic sequencing project. Some notes:
* It is important to set "search options = none" in order to avoid
GBrowse trying to scan through the BAM database to match read
names. This is a time-consuming operation.
* The callback to "bgcolor" renders pairs whose mates are unmapped in
red.
* The callback to "balloon hover" causes a balloon to pop up with the
read name when the user hovers over each paired read. Otherwise the
default behavior would be to provide information about the pair as
a whole.
* When the user zooms out to 1001 bp or greaterp, the track switches
to a coverage graph.
[bamtest:database]
db_adaptor = Bio::DB::Sam
db_args = -bam /var/www/gbrowse2/databases/bamtest/ex1.bam
search options= default
[Pair]
feature = read_pair
glyph = segments
database = bamtest
draw_target = 1
show_mismatch = 1
bgcolor = sub {
my $f = shift;
return $f->get_tag_values('M_UNMAPPED') ? 'red' : 'green';
}
fgcolor = green
height = 3
label = sub {shift->display_name}
label density = 50
bump = fast
connector = dashed
balloon hover = sub {
my $f = shift;
return '' unless $f->type eq 'match';
return 'Read: '.$f->display_name.' : '.$f->flag_str;
}
key = Read Pairs
[Pair:1000]
feature = coverage:1001
glyph = wiggle_xyplot
height = 50
min_score = 0
autoscale = local
To show alignment data correctly when the user is zoomed in, you should
also provide a pointer to the FASTA file containing the reference
genome. In this case, modify the db_args line to read:
db_args = -bam /var/www/gbrowse2/databases/bamtest/ex1.bam
-fasta /var/www/gbrowse2/databases/bamtest/ex1.fa
SEE ALSO
Bio::Perl, Bio::DB::Bam::Alignment, Bio::DB::Bam::Constants
AUTHOR
Lincoln Stein <lincoln.stein@oicr.on.ca>. <lincoln.stein@bmail.com>
Copyright (c) 2009 Ontario Institute for Cancer Research.
This package and its accompanying libraries is free software; you can
redistribute it and/or modify it under the terms of the GPL (either
version 1, or at your option, any later version) or the Artistic
License 2.0. Refer to LICENSE for the full license text. In addition,
please see DISCLAIMER.txt for disclaimers of warranty.
perl v5.14.2 2012-08-23 Bio::DB::Sam(3)