Bio.Align package

Module contents

Code for dealing with sequence alignments.

One of the most important things in this module is the MultipleSeqAlignment class, used in the Bio.AlignIO module.

class Bio.Align.MultipleSeqAlignment(records, alphabet=None, annotations=None, column_annotations=None)

Bases: object

Represents a classical multiple sequence alignment (MSA).

By this we mean a collection of sequences (usually shown as rows) which are all the same length (usually with gap characters for insertions or padding). The data can then be regarded as a matrix of letters, with well defined columns.

You would typically create an MSA by loading an alignment file with the AlignIO module:

>>> from Bio import AlignIO
>>> align = AlignIO.read("Clustalw/opuntia.aln", "clustal")
>>> print(align)
SingleLetterAlphabet() alignment with 7 rows and 156 columns
TATACATTAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273285|gb|AF191659.1|AF191
TATACATTAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273284|gb|AF191658.1|AF191
TATACATTAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273287|gb|AF191661.1|AF191
TATACATAAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273286|gb|AF191660.1|AF191
TATACATTAAAGGAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273290|gb|AF191664.1|AF191
TATACATTAAAGGAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273289|gb|AF191663.1|AF191
TATACATTAAAGGAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273291|gb|AF191665.1|AF191

In some respects you can treat these objects as lists of SeqRecord objects, each representing a row of the alignment. Iterating over an alignment gives the SeqRecord object for each row:

>>> len(align)
7
>>> for record in align:
...     print("%s %i" % (record.id, len(record)))
...
gi|6273285|gb|AF191659.1|AF191 156
gi|6273284|gb|AF191658.1|AF191 156
gi|6273287|gb|AF191661.1|AF191 156
gi|6273286|gb|AF191660.1|AF191 156
gi|6273290|gb|AF191664.1|AF191 156
gi|6273289|gb|AF191663.1|AF191 156
gi|6273291|gb|AF191665.1|AF191 156

You can also access individual rows as SeqRecord objects via their index:

>>> print(align[0].id)
gi|6273285|gb|AF191659.1|AF191
>>> print(align[-1].id)
gi|6273291|gb|AF191665.1|AF191

And extract columns as strings:

>>> print(align[:, 1])
AAAAAAA

Or, take just the first ten columns as a sub-alignment:

>>> print(align[:, :10])
SingleLetterAlphabet() alignment with 7 rows and 10 columns
TATACATTAA gi|6273285|gb|AF191659.1|AF191
TATACATTAA gi|6273284|gb|AF191658.1|AF191
TATACATTAA gi|6273287|gb|AF191661.1|AF191
TATACATAAA gi|6273286|gb|AF191660.1|AF191
TATACATTAA gi|6273290|gb|AF191664.1|AF191
TATACATTAA gi|6273289|gb|AF191663.1|AF191
TATACATTAA gi|6273291|gb|AF191665.1|AF191

Combining this alignment slicing with alignment addition allows you to remove a section of the alignment. For example, taking just the first and last ten columns:

>>> print(align[:, :10] + align[:, -10:])
SingleLetterAlphabet() alignment with 7 rows and 20 columns
TATACATTAAGTGTACCAGA gi|6273285|gb|AF191659.1|AF191
TATACATTAAGTGTACCAGA gi|6273284|gb|AF191658.1|AF191
TATACATTAAGTGTACCAGA gi|6273287|gb|AF191661.1|AF191
TATACATAAAGTGTACCAGA gi|6273286|gb|AF191660.1|AF191
TATACATTAAGTGTACCAGA gi|6273290|gb|AF191664.1|AF191
TATACATTAAGTATACCAGA gi|6273289|gb|AF191663.1|AF191
TATACATTAAGTGTACCAGA gi|6273291|gb|AF191665.1|AF191

Note - This object replaced the older Alignment object defined in module Bio.Align.Generic but is not fully backwards compatible with it.

Note - This object does NOT attempt to model the kind of alignments used in next generation sequencing with multiple sequencing reads which are much shorter than the alignment, and where there is usually a consensus or reference sequence with special status.

__init__(self, records, alphabet=None, annotations=None, column_annotations=None)

Initialize a new MultipleSeqAlignment object.

Arguments:
  • records - A list (or iterator) of SeqRecord objects, whose

    sequences are all the same length. This may be an be an empty list.

  • alphabet - The alphabet for the whole alignment, typically a gapped

    alphabet, which should be a super-set of the individual record alphabets. If omitted, a consensus alphabet is used.

  • annotations - Information about the whole alignment (dictionary).

  • column_annotations - Per column annotation (restricted dictionary).

    This holds Python sequences (lists, strings, tuples) whose length matches the number of columns. A typical use would be a secondary structure consensus string.

You would normally load a MSA from a file using Bio.AlignIO, but you can do this from a list of SeqRecord objects too:

>>> from Bio.Alphabet import generic_dna
>>> from Bio.Seq import Seq
>>> from Bio.SeqRecord import SeqRecord
>>> from Bio.Align import MultipleSeqAlignment
>>> a = SeqRecord(Seq("AAAACGT", generic_dna), id="Alpha")
>>> b = SeqRecord(Seq("AAA-CGT", generic_dna), id="Beta")
>>> c = SeqRecord(Seq("AAAAGGT", generic_dna), id="Gamma")
>>> align = MultipleSeqAlignment([a, b, c],
...                              annotations={"tool": "demo"},
...                              column_annotations={"stats": "CCCXCCC"})
>>> print(align)
DNAAlphabet() alignment with 3 rows and 7 columns
AAAACGT Alpha
AAA-CGT Beta
AAAAGGT Gamma
>>> align.annotations
{'tool': 'demo'}
>>> align.column_annotations
{'stats': 'CCCXCCC'}
property column_annotations

Dictionary of per-letter-annotation for the sequence.

__str__(self)

Return a multi-line string summary of the alignment.

This output is intended to be readable, but large alignments are shown truncated. A maximum of 20 rows (sequences) and 50 columns are shown, with the record identifiers. This should fit nicely on a single screen. e.g.

>>> from Bio.Alphabet import IUPAC, Gapped
>>> from Bio.Align import MultipleSeqAlignment
>>> align = MultipleSeqAlignment([], Gapped(IUPAC.unambiguous_dna, "-"))
>>> align.add_sequence("Alpha", "ACTGCTAGCTAG")
>>> align.add_sequence("Beta",  "ACT-CTAGCTAG")
>>> align.add_sequence("Gamma", "ACTGCTAGATAG")
>>> print(align)
Gapped(IUPACUnambiguousDNA(), '-') alignment with 3 rows and 12 columns
ACTGCTAGCTAG Alpha
ACT-CTAGCTAG Beta
ACTGCTAGATAG Gamma

See also the alignment’s format method.

__repr__(self)

Return a representation of the object for debugging.

The representation cannot be used with eval() to recreate the object, which is usually possible with simple python ojects. For example:

<Bio.Align.MultipleSeqAlignment instance (2 records of length 14, SingleLetterAlphabet()) at a3c184c>

The hex string is the memory address of the object, see help(id). This provides a simple way to visually distinguish alignments of the same size.

format(self, format)

Return the alignment as a string in the specified file format.

The format should be a lower case string supported as an output format by Bio.AlignIO (such as “fasta”, “clustal”, “phylip”, “stockholm”, etc), which is used to turn the alignment into a string.

e.g.

>>> from Bio.Alphabet import IUPAC, Gapped
>>> from Bio.Align import MultipleSeqAlignment
>>> align = MultipleSeqAlignment([], Gapped(IUPAC.unambiguous_dna, "-"))
>>> align.add_sequence("Alpha", "ACTGCTAGCTAG")
>>> align.add_sequence("Beta",  "ACT-CTAGCTAG")
>>> align.add_sequence("Gamma", "ACTGCTAGATAG")
>>> print(align.format("fasta"))
>Alpha
ACTGCTAGCTAG
>Beta
ACT-CTAGCTAG
>Gamma
ACTGCTAGATAG

>>> print(align.format("phylip"))
 3 12
Alpha      ACTGCTAGCT AG
Beta       ACT-CTAGCT AG
Gamma      ACTGCTAGAT AG

For Python 2.6, 3.0 or later see also the built in format() function.

__format__(self, format_spec)

Return the alignment as a string in the specified file format.

This method supports the python format() function added in Python 2.6/3.0. The format_spec should be a lower case string supported by Bio.AlignIO as an output file format. See also the alignment’s format() method.

__iter__(self)

Iterate over alignment rows as SeqRecord objects.

e.g.

>>> from Bio.Alphabet import IUPAC, Gapped
>>> from Bio.Align import MultipleSeqAlignment
>>> align = MultipleSeqAlignment([], Gapped(IUPAC.unambiguous_dna, "-"))
>>> align.add_sequence("Alpha", "ACTGCTAGCTAG")
>>> align.add_sequence("Beta",  "ACT-CTAGCTAG")
>>> align.add_sequence("Gamma", "ACTGCTAGATAG")
>>> for record in align:
...    print(record.id)
...    print(record.seq)
...
Alpha
ACTGCTAGCTAG
Beta
ACT-CTAGCTAG
Gamma
ACTGCTAGATAG
__len__(self)

Return the number of sequences in the alignment.

Use len(alignment) to get the number of sequences (i.e. the number of rows), and alignment.get_alignment_length() to get the length of the longest sequence (i.e. the number of columns).

This is easy to remember if you think of the alignment as being like a list of SeqRecord objects.

get_alignment_length(self)

Return the maximum length of the alignment.

All objects in the alignment should (hopefully) have the same length. This function will go through and find this length by finding the maximum length of sequences in the alignment.

>>> from Bio.Alphabet import IUPAC, Gapped
>>> from Bio.Align import MultipleSeqAlignment
>>> align = MultipleSeqAlignment([], Gapped(IUPAC.unambiguous_dna, "-"))
>>> align.add_sequence("Alpha", "ACTGCTAGCTAG")
>>> align.add_sequence("Beta",  "ACT-CTAGCTAG")
>>> align.add_sequence("Gamma", "ACTGCTAGATAG")
>>> align.get_alignment_length()
12

If you want to know the number of sequences in the alignment, use len(align) instead:

>>> len(align)
3
add_sequence(self, descriptor, sequence, start=None, end=None, weight=1.0)

Add a sequence to the alignment.

This doesn’t do any kind of alignment, it just adds in the sequence object, which is assumed to be prealigned with the existing sequences.

Arguments:
  • descriptor - The descriptive id of the sequence being added. This will be used as the resulting SeqRecord’s .id property (and, for historical compatibility, also the .description property)

  • sequence - A string with sequence info.

  • start - You can explicitly set the start point of the sequence. This is useful (at least) for BLAST alignments, which can just be partial alignments of sequences.

  • end - Specify the end of the sequence, which is important for the same reason as the start.

  • weight - The weight to place on the sequence in the alignment. By default, all sequences have the same weight. (0.0 => no weight, 1.0 => highest weight)

In general providing a SeqRecord and calling .append is preferred.

extend(self, records)

Add more SeqRecord objects to the alignment as rows.

They must all have the same length as the original alignment, and have alphabets compatible with the alignment’s alphabet. For example,

>>> from Bio.Alphabet import generic_dna
>>> from Bio.Seq import Seq
>>> from Bio.SeqRecord import SeqRecord
>>> from Bio.Align import MultipleSeqAlignment
>>> a = SeqRecord(Seq("AAAACGT", generic_dna), id="Alpha")
>>> b = SeqRecord(Seq("AAA-CGT", generic_dna), id="Beta")
>>> c = SeqRecord(Seq("AAAAGGT", generic_dna), id="Gamma")
>>> d = SeqRecord(Seq("AAAACGT", generic_dna), id="Delta")
>>> e = SeqRecord(Seq("AAA-GGT", generic_dna), id="Epsilon")

First we create a small alignment (three rows):

>>> align = MultipleSeqAlignment([a, b, c])
>>> print(align)
DNAAlphabet() alignment with 3 rows and 7 columns
AAAACGT Alpha
AAA-CGT Beta
AAAAGGT Gamma

Now we can extend this alignment with another two rows:

>>> align.extend([d, e])
>>> print(align)
DNAAlphabet() alignment with 5 rows and 7 columns
AAAACGT Alpha
AAA-CGT Beta
AAAAGGT Gamma
AAAACGT Delta
AAA-GGT Epsilon

Because the alignment object allows iteration over the rows as SeqRecords, you can use the extend method with a second alignment (provided its sequences have the same length as the original alignment).

append(self, record)

Add one more SeqRecord object to the alignment as a new row.

This must have the same length as the original alignment (unless this is the first record), and have an alphabet compatible with the alignment’s alphabet.

>>> from Bio import AlignIO
>>> align = AlignIO.read("Clustalw/opuntia.aln", "clustal")
>>> print(align)
SingleLetterAlphabet() alignment with 7 rows and 156 columns
TATACATTAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273285|gb|AF191659.1|AF191
TATACATTAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273284|gb|AF191658.1|AF191
TATACATTAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273287|gb|AF191661.1|AF191
TATACATAAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273286|gb|AF191660.1|AF191
TATACATTAAAGGAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273290|gb|AF191664.1|AF191
TATACATTAAAGGAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273289|gb|AF191663.1|AF191
TATACATTAAAGGAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273291|gb|AF191665.1|AF191
>>> len(align)
7

We’ll now construct a dummy record to append as an example:

>>> from Bio.Seq import Seq
>>> from Bio.SeqRecord import SeqRecord
>>> dummy = SeqRecord(Seq("N"*156), id="dummy")

Now append this to the alignment,

>>> align.append(dummy)
>>> print(align)
SingleLetterAlphabet() alignment with 8 rows and 156 columns
TATACATTAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273285|gb|AF191659.1|AF191
TATACATTAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273284|gb|AF191658.1|AF191
TATACATTAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273287|gb|AF191661.1|AF191
TATACATAAAAGAAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273286|gb|AF191660.1|AF191
TATACATTAAAGGAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273290|gb|AF191664.1|AF191
TATACATTAAAGGAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273289|gb|AF191663.1|AF191
TATACATTAAAGGAGGGGGATGCGGATAAATGGAAAGGCGAAAG...AGA gi|6273291|gb|AF191665.1|AF191
NNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNN...NNN dummy
>>> len(align)
8
__add__(self, other)

Combine two alignments with the same number of rows by adding them.

If you have two multiple sequence alignments (MSAs), there are two ways to think about adding them - by row or by column. Using the extend method adds by row. Using the addition operator adds by column. For example,

>>> from Bio.Alphabet import generic_dna
>>> from Bio.Seq import Seq
>>> from Bio.SeqRecord import SeqRecord
>>> from Bio.Align import MultipleSeqAlignment
>>> a1 = SeqRecord(Seq("AAAAC", generic_dna), id="Alpha")
>>> b1 = SeqRecord(Seq("AAA-C", generic_dna), id="Beta")
>>> c1 = SeqRecord(Seq("AAAAG", generic_dna), id="Gamma")
>>> a2 = SeqRecord(Seq("GT", generic_dna), id="Alpha")
>>> b2 = SeqRecord(Seq("GT", generic_dna), id="Beta")
>>> c2 = SeqRecord(Seq("GT", generic_dna), id="Gamma")
>>> left = MultipleSeqAlignment([a1, b1, c1],
...                             annotations={"tool": "demo", "name": "start"},
...                             column_annotations={"stats": "CCCXC"})
>>> right = MultipleSeqAlignment([a2, b2, c2],
...                             annotations={"tool": "demo", "name": "end"},
...                             column_annotations={"stats": "CC"})

Now, let’s look at these two alignments:

>>> print(left)
DNAAlphabet() alignment with 3 rows and 5 columns
AAAAC Alpha
AAA-C Beta
AAAAG Gamma
>>> print(right)
DNAAlphabet() alignment with 3 rows and 2 columns
GT Alpha
GT Beta
GT Gamma

And add them:

>>> combined = left + right
>>> print(combined)
DNAAlphabet() alignment with 3 rows and 7 columns
AAAACGT Alpha
AAA-CGT Beta
AAAAGGT Gamma

For this to work, both alignments must have the same number of records (here they both have 3 rows):

>>> len(left)
3
>>> len(right)
3
>>> len(combined)
3

The individual rows are SeqRecord objects, and these can be added together. Refer to the SeqRecord documentation for details of how the annotation is handled. This example is a special case in that both original alignments shared the same names, meaning when the rows are added they also get the same name.

Any common annotations are preserved, but differing annotation is lost. This is the same behaviour used in the SeqRecord annotations and is designed to prevent accidental propagation of inappropriate values:

>>> combined.annotations
{'tool': 'demo'}

Similarly any common per-column-annotations are combined:

>>> combined.column_annotations
{'stats': 'CCCXCCC'}
__getitem__(self, index)

Access part of the alignment.

Depending on the indices, you can get a SeqRecord object (representing a single row), a Seq object (for a single columns), a string (for a single characters) or another alignment (representing some part or all of the alignment).

align[r,c] gives a single character as a string align[r] gives a row as a SeqRecord align[r,:] gives a row as a SeqRecord align[:,c] gives a column as a Seq (using the alignment’s alphabet)

align[:] and align[:,:] give a copy of the alignment

Anything else gives a sub alignment, e.g. align[0:2] or align[0:2,:] uses only row 0 and 1 align[:,1:3] uses only columns 1 and 2 align[0:2,1:3] uses only rows 0 & 1 and only cols 1 & 2

We’ll use the following example alignment here for illustration:

>>> from Bio.Alphabet import generic_dna
>>> from Bio.Seq import Seq
>>> from Bio.SeqRecord import SeqRecord
>>> from Bio.Align import MultipleSeqAlignment
>>> a = SeqRecord(Seq("AAAACGT", generic_dna), id="Alpha")
>>> b = SeqRecord(Seq("AAA-CGT", generic_dna), id="Beta")
>>> c = SeqRecord(Seq("AAAAGGT", generic_dna), id="Gamma")
>>> d = SeqRecord(Seq("AAAACGT", generic_dna), id="Delta")
>>> e = SeqRecord(Seq("AAA-GGT", generic_dna), id="Epsilon")
>>> align = MultipleSeqAlignment([a, b, c, d, e], generic_dna)

You can access a row of the alignment as a SeqRecord using an integer index (think of the alignment as a list of SeqRecord objects here):

>>> first_record = align[0]
>>> print("%s %s" % (first_record.id, first_record.seq))
Alpha AAAACGT
>>> last_record = align[-1]
>>> print("%s %s" % (last_record.id, last_record.seq))
Epsilon AAA-GGT

You can also access use python’s slice notation to create a sub-alignment containing only some of the SeqRecord objects:

>>> sub_alignment = align[2:5]
>>> print(sub_alignment)
DNAAlphabet() alignment with 3 rows and 7 columns
AAAAGGT Gamma
AAAACGT Delta
AAA-GGT Epsilon

This includes support for a step, i.e. align[start:end:step], which can be used to select every second sequence:

>>> sub_alignment = align[::2]
>>> print(sub_alignment)
DNAAlphabet() alignment with 3 rows and 7 columns
AAAACGT Alpha
AAAAGGT Gamma
AAA-GGT Epsilon

Or to get a copy of the alignment with the rows in reverse order:

>>> rev_alignment = align[::-1]
>>> print(rev_alignment)
DNAAlphabet() alignment with 5 rows and 7 columns
AAA-GGT Epsilon
AAAACGT Delta
AAAAGGT Gamma
AAA-CGT Beta
AAAACGT Alpha

You can also use two indices to specify both rows and columns. Using simple integers gives you the entry as a single character string. e.g.

>>> align[3, 4]
'C'

This is equivalent to:

>>> align[3][4]
'C'

or:

>>> align[3].seq[4]
'C'

To get a single column (as a string) use this syntax:

>>> align[:, 4]
'CCGCG'

Or, to get part of a column,

>>> align[1:3, 4]
'CG'

However, in general you get a sub-alignment,

>>> print(align[1:5, 3:6])
DNAAlphabet() alignment with 4 rows and 3 columns
-CG Beta
AGG Gamma
ACG Delta
-GG Epsilon

This should all seem familiar to anyone who has used the NumPy array or matrix objects.

sort(self, key=None, reverse=False)

Sort the rows (SeqRecord objects) of the alignment in place.

This sorts the rows alphabetically using the SeqRecord object id by default. The sorting can be controlled by supplying a key function which must map each SeqRecord to a sort value.

This is useful if you want to add two alignments which use the same record identifiers, but in a different order. For example,

>>> from Bio.Alphabet import generic_dna
>>> from Bio.Seq import Seq
>>> from Bio.SeqRecord import SeqRecord
>>> from Bio.Align import MultipleSeqAlignment
>>> align1 = MultipleSeqAlignment([
...              SeqRecord(Seq("ACGT", generic_dna), id="Human"),
...              SeqRecord(Seq("ACGG", generic_dna), id="Mouse"),
...              SeqRecord(Seq("ACGC", generic_dna), id="Chicken"),
...          ])
>>> align2 = MultipleSeqAlignment([
...              SeqRecord(Seq("CGGT", generic_dna), id="Mouse"),
...              SeqRecord(Seq("CGTT", generic_dna), id="Human"),
...              SeqRecord(Seq("CGCT", generic_dna), id="Chicken"),
...          ])

If you simple try and add these without sorting, you get this:

>>> print(align1 + align2)
DNAAlphabet() alignment with 3 rows and 8 columns
ACGTCGGT <unknown id>
ACGGCGTT <unknown id>
ACGCCGCT Chicken

Consult the SeqRecord documentation which explains why you get a default value when annotation like the identifier doesn’t match up. However, if we sort the alignments first, then add them we get the desired result:

>>> align1.sort()
>>> align2.sort()
>>> print(align1 + align2)
DNAAlphabet() alignment with 3 rows and 8 columns
ACGCCGCT Chicken
ACGTCGTT Human
ACGGCGGT Mouse

As an example using a different sort order, you could sort on the GC content of each sequence.

>>> from Bio.SeqUtils import GC
>>> print(align1)
DNAAlphabet() alignment with 3 rows and 4 columns
ACGC Chicken
ACGT Human
ACGG Mouse
>>> align1.sort(key = lambda record: GC(record.seq))
>>> print(align1)
DNAAlphabet() alignment with 3 rows and 4 columns
ACGT Human
ACGC Chicken
ACGG Mouse

There is also a reverse argument, so if you wanted to sort by ID but backwards:

>>> align1.sort(reverse=True)
>>> print(align1)
DNAAlphabet() alignment with 3 rows and 4 columns
ACGG Mouse
ACGT Human
ACGC Chicken
class Bio.Align.PairwiseAlignment(target, query, path, score)

Bases: object

Represents a pairwise sequence alignment.

Internally, the pairwise alignment is stored as the path through the traceback matrix, i.e. a tuple of pairs of indices corresponding to the vertices of the path in the traceback matrix.

__init__(self, target, query, path, score)

Initialize a new PairwiseAlignment object.

Arguments:
  • target - The first sequence, as a plain string, without gaps.

  • query - The second sequence, as a plain string, without gaps.

  • path - The path through the traceback matrix, defining an

    alignment.

  • score - The alignment score.

You would normally obtain a PairwiseAlignment object by iterating over a PairwiseAlignments object.

__cmp__(self, other)
__eq__(self, other)

Return self==value.

__ne__(self, other)

Return self!=value.

__lt__(self, other)

Return self<value.

__le__(self, other)

Return self<=value.

__gt__(self, other)

Return self>value.

__ge__(self, other)

Return self>=value.

__format__(self, format_spec)

Default object formatter.

__str__(self)

Return str(self).

format(self)

Create a human-readable representation of the alignment.

property aligned

Return the indices of subsequences aligned to each other.

This property returns the start and end indices of subsequences in the target and query sequence that were aligned to each other. If the alignment between target (t) and query (q) consists of N chunks, you get two tuples of length N:

(((t_start1, t_end1), (t_start2, t_end2), …, (t_startN, t_endN)),

((q_start1, q_end1), (q_start2, q_end2), …, (q_startN, q_endN)))

For example,

>>> from Bio import Align
>>> aligner = Align.PairwiseAligner()
>>> alignments = aligner.align("GAACT", "GAT")
>>> alignment = alignments[0]
>>> print(alignment)
GAACT
||--|
GA--T

>>> alignment.aligned
(((0, 2), (4, 5)), ((0, 2), (2, 3)))
>>> alignment = alignments[1]
>>> print(alignment)
GAACT
|-|-|
G-A-T

>>> alignment.aligned
(((0, 1), (2, 3), (4, 5)), ((0, 1), (1, 2), (2, 3)))

Note that different alignments may have the same subsequences aligned to each other. In particular, this may occur if alignments differ from each other in terms of their gap placement only:

>>> aligner.mismatch_score = -10
>>> alignments = aligner.align("AAACAAA", "AAAGAAA")
>>> len(alignments)
2
>>> print(alignments[0])
AAAC-AAA
|||--|||
AAA-GAAA

>>> alignments[0].aligned
(((0, 3), (4, 7)), ((0, 3), (4, 7)))
>>> print(alignments[1])
AAA-CAAA
|||--|||
AAAG-AAA

>>> alignments[1].aligned
(((0, 3), (4, 7)), ((0, 3), (4, 7)))

The property can be used to identify alignments that are identical to each other in terms of their aligned sequences.

__hash__ = None
class Bio.Align.PairwiseAlignments(seqA, seqB, score, paths)

Bases: object

Implements an iterator over pairwise alignments returned by the aligner.

This class also supports indexing, which is fast for increasing indices, but may be slow for random access of a large number of alignments.

Note that pairwise aligners can return an astronomical number of alignments, even for relatively short sequences, if they align poorly to each other. We therefore recommend to first check the number of alignments, accessible as len(alignments), which can be calculated quickly even if the number of alignments is very large.

__init__(self, seqA, seqB, score, paths)

Initialize a new PairwiseAlignments object.

Arguments:
  • seqA - The first sequence, as a plain string, without gaps.

  • seqB - The second sequence, as a plain string, without gaps.

  • score - The alignment score.

  • paths - An iterator over the paths in the traceback matrix;

    each path defines one alignment.

You would normally obtain an PairwiseAlignments object by calling aligner.align(seqA, seqB), where aligner is a PairwiseAligner object.

__len__(self)
__getitem__(self, index)
__iter__(self)
__next__(self)
class Bio.Align.PairwiseAligner

Bases: _algorithms.PairwiseAligner

Performs pairwise sequence alignment using dynamic programming.

This provides functions to get global and local alignments between two sequences. A global alignment finds the best concordance between all characters in two sequences. A local alignment finds just the subsequences that align the best.

To perform a pairwise sequence alignment, first create a PairwiseAligner object. This object stores the match and mismatch scores, as well as the gap scores. Typically, match scores are positive, while mismatch scores and gap scores are negative or zero. By default, the match score is 1, and the mismatch and gap scores are zero. Based on the values of the gap scores, a PairwiseAligner object automatically chooses the appropriate alignment algorithm (the Needleman-Wunsch, Smith-Waterman, Gotoh, or Waterman-Smith-Beyer global or local alignment algorithm).

Calling the “score” method on the aligner with two sequences as arguments will calculate the alignment score between the two sequences. Calling the “align” method on the aligner with two sequences as arguments will return a generator yielding the alignments between the two sequences.

Some examples:

>>> from Bio import Align
>>> aligner = Align.PairwiseAligner()
>>> alignments = aligner.align("TACCG", "ACG")
>>> for alignment in sorted(alignments):
...     print("Score = %.1f:" % alignment.score)
...     print(alignment)
...
Score = 3.0:
TACCG
-|-||
-A-CG

Score = 3.0:
TACCG
-||-|
-AC-G

Specify the aligner mode as local to generate local alignments:

>>> aligner.mode = 'local'
>>> alignments = aligner.align("TACCG", "ACG")
>>> for alignment in sorted(alignments):
...     print("Score = %.1f:" % alignment.score)
...     print(alignment)
...
Score = 3.0:
TACCG
 |-||
 A-CG

Score = 3.0:
TACCG
 ||-|
 AC-G

Do a global alignment. Identical characters are given 2 points, 1 point is deducted for each non-identical character.

>>> aligner.mode = 'global'
>>> aligner.match_score = 2
>>> aligner.mismatch_score = -1
>>> for alignment in aligner.align("TACCG", "ACG"):
...     print("Score = %.1f:" % alignment.score)
...     print(alignment)
...
Score = 6.0:
TACCG
-||-|
-AC-G

Score = 6.0:
TACCG
-|-||
-A-CG

Same as above, except now 0.5 points are deducted when opening a gap, and 0.1 points are deducted when extending it.

>>> aligner.open_gap_score = -0.5
>>> aligner.extend_gap_score = -0.1
>>> aligner.target_end_gap_score = 0.0
>>> aligner.query_end_gap_score = 0.0
>>> for alignment in aligner.align("TACCG", "ACG"):
...     print("Score = %.1f:" % alignment.score)
...     print(alignment)
...
Score = 5.5:
TACCG
-|-||
-A-CG

Score = 5.5:
TACCG
-||-|
-AC-G

The alignment function can also use known matrices already included in Biopython:

>>> from Bio.Align import substitution_matrices
>>> aligner = Align.PairwiseAligner()
>>> aligner.substitution_matrix = substitution_matrices.load("BLOSUM62")
>>> alignments = aligner.align("KEVLA", "EVL")
>>> alignments = list(alignments)
>>> print("Number of alignments: %d" % len(alignments))
Number of alignments: 1
>>> alignment = alignments[0]
>>> print("Score = %.1f" % alignment.score)
Score = 13.0
>>> print(alignment)
KEVLA
-|||-
-EVL-
__setattr__(self, key, value)

Implement setattr(self, name, value).

align(self, seqA, seqB)

Return the alignments of two sequences using PairwiseAligner.

score(self, seqA, seqB)

Return the alignments score of two sequences using PairwiseAligner.