A simple FASTA read and write toolbox for small to medium size projects.
This module is now part of the bfx suite. See https://py-bfx.readthedocs.io for more information.
FASTA files are text-based files for storing nucleotide or amino acid sequences. Reading such files is not particularly difficult, yet most off the shelf packages are overloaded with strange dependencies.
miniFASTA offers an alternative to this and brings many useful functions without relying on third party packages.
Using pip / pip3:
pip install miniFasta
Or by source with pip:
git clone git@github.com:not-a-feature/miniFASTA.git
cd miniFASTA
pip install .
Or by conda:
conda install -c conda-forge minifasta
miniFASTA offers easy to use functions for fasta handling. The five main parts are:
- read()
- write()
- fasta_object()
- toAmino()
- roRevComp()
- valid()
- len() / str() / eq() / iter()
- translate_seq()
- reverse_comp()
read()
is a fasta reader which is able to handle compressed and non-compressed files.
Following compressions are supported: zip, tar, tar.gz, gz. If multiple files are stored inside an archive, all files are read.
This function returns a Iterator of fasta_objects. If only the sequences should be returnes set the positional argument seq=True
.
The entries are usually casted to upper case letters. Set read("path.fasta", upper=False)
to disable casting.
# Read fasta_objects
fos = mf.read("dolphin.fasta") # Iterator of fasta_objects.
fos = list(fos) # Casts the iterator to list of fasta_objects
# Read only the sequence
fasta_strings = mf.read("dolphin.fasta", seq=True) # Iterator of string.
fasta_strings = [fo.body for fo in mf.read("dolphin.fasta")] # Alternative
# Options and compressed files
fos = mf.read("mouse.fasta", upper=False) # The entries won't be casted to upper case.
fos = mf.read("reads.tar.gz") # Is able to handle compressed files.
write()
is a basic fasta writer.
It takes a single or a list of fasta_objects and writes it to the given path.
The file is usually overwritten. Set write(fo, "path.fasta", mode="a")
to append file.
fos = mf.read("dolphin.fasta") # Iterator of fasta entries
fos = list(fos) # Materialize
mf.write(fos, "new.fasta")
The core component of miniFASTA is the fasta_object()
. This object represents an FASTA entry and consists of a head and body.
import miniFasta as mf
fo = mf.fasta_object(">Atlantic dolphin", "CGGCCTTCTATCTTCTTC", stype="DNA")
fo.getHead() or fo.head
# >Atlantic dolphin
fo.getSeq() or fo.body
# CGGCCTTCTATCTTCTTC
### Following functions are defined on a fasta_object():
str(fo) # will return:
# >Atlantic dolphin
# CGGCCTTCTATCTTCTTC
# Body length
len(fo) # will return 18, the length of the body
# Equality
fo == fo # True
fo_b = mf.fasta_object(">Same Body", "CGGCCTTCTATCTTCTTC")
fo == fo_b # True
fo_c = mf.fasta_object(">Different Body", "ZZZZAGCTAG")
fo == fo_c # False
for s in fo:
# Iterates through the sequence of fo.
fasta_object(...).valid()
Checks if the body contains invalid characters. stype of fasta_object needs to be set in order to check for illegal characters in its body.
stype is one of:
- ANY : [default] Allows all characters.
- NA : Allows all Nucleic Acid Codes (DNA & RNA).
- DNA : Allows all IUPAC DNA Codes.
- RNA : Allows all IUPAC RNA Codes.
- PROT: Allows all IUPAC Aminoacid Codes.
Optional: allowedChars can be set to overwrite default settings.
# The default object allows all characters.
# True
fasta_object(">valid", "Ä'_**?.asdLLA").valid()
# Only if stype is specified, valid can check for illegal characters.
# True
fasta_object(">valid", "ACGTUAGTGU", stype="NA").valid()
# False, as W is not allowed for DNA/RNA
fasta_object(">invalid", "ACWYUOTGU", stype="NA").valid()
# True
fasta_object(">valid", "AGGATTA", stype="ANY").valid(allowedChars = "AGTC")
# True, as stype is ignored if allowedChars is set.
fasta_object(">valid", "WYU", stype="DNA").valid(allowedChars = "WYU")
fasta_object(...).toAmino(translation_dict)
Translates the body to an amino-acid sequence. See tranlate_seq()
for more details.
fo.toAmino()
fo.body # Will return RPSIFF
d = {"CCG": "Z", "CTT": "A" ...}
fo.toAmino(d)
fo.getBody # Will return ZA...
fasta_object(...).toRevComp(complement_dict)
Converts the body to its reverse comlement. See reverse_comp()
for more details.
fo.toRevComp()
fo.getBody # Will return GAAGAAGATAGAAGGCCG
translate_seq()
translates a sequence starting at position 0.
Unless translation_dict is provided, the standart bacterial code is used. If the codon was not found, it will be replaced by an ~
. Tailing bases that do not fit into a codon will be ignored.
mf.translate_seq("CGGCCTTCTATCTTCTTC") # Will return RPSIFF
d = {"CGG": "Z", "CTT": "A"}
mf.translate_seq("CGGCTT", d) # Will return ZA.
reverse_comp()
converts a sequence to its reverse comlement.
Unless complement_dict is provided, the standart complement is used. If no complement was found, the nucleotide remains unchanged.
mf.reverse_comp("CGGCCTTCTATCTTCTTC") # Will return GAAGAAGATAGAAGGCCG
d = {"C": "Z", "T": "Y"}
mf.reverse_comp("TC", d) # Will return ZY
Copyright (C) 2024 by Jules Kreuer - @not_a_feature
This piece of software is published unter the GNU General Public License v3.0 TLDR:
Permissions | Conditions | Limitations |
---|---|---|
✓ Commercial use | Disclose source | ✕ Liability |
✓ Distribution | License and copyright notice | ✕ Warranty |
✓ Modification | Same license | |
✓ Patent use | State changes | |
✓ Private use |
Go to LICENSE.md to see the full version.