Skip to main content

Transcripts for HGVS libraries

Project description

cdot

PyPi version Python versions tests DOI

cdot provides the transcript data needed to map and validate HGVS variants - the gene/transcript coordinates, exon structure and genome alignments - for the two most popular Python HGVS libraries: biocommons HGVS and PyHGVS.

To do HGVS work (e.g. convert NM_001637.3:c.1582G>A to genomic coordinates) those libraries need a transcript data source. The usual source, UTA, is a PostgreSQL database that's slow and heavy to run. cdot instead converts the official RefSeq/Ensembl annotation files (GTF/GFF3) into compact JSON and ships fast loaders for the HGVS libraries. You can use it via:

Because it reads the released annotation files directly, cdot covers 1.58 million transcript/genome alignments, including historical transcript versions - vs ~141k in UTA (v.20210129) - which matters when resolving legacy HGVS. See cdot vs UTA for the trade-offs.

Recent changes are in the changelog.

Install

pip install cdot

Optional extras:

pip install cdot[fasta]   # local genome FASTA sequence fetching (pysam) - needed for the PyHGVS example below

(hgvs is a core dependency, so the biocommons HGVS examples work out of the box.)

Examples

Biocommons HGVS example:

import hgvs
from hgvs.assemblymapper import AssemblyMapper
from cdot.hgvs.dataproviders import JSONDataProvider, RESTDataProvider

hdp = RESTDataProvider()  # Uses API server at cdotlib.org
# hdp = JSONDataProvider(["./cdot-0.2.32.refseq.grch37.json.gz"])  # Uses local JSON file

am = AssemblyMapper(hdp,
                    assembly_name='GRCh37',
                    alt_aln_method='splign', replace_reference=True)

hp = hgvs.parser.Parser()
var_c = hp.parse_hgvs_variant('NM_001637.3:c.1582G>A')
am.c_to_g(var_c)

more Biocommons examples:

Tip: cdot provides many transcripts that aren't in SeqRepo, so the default sequence fetcher will raise HGVSDataNotAvailableError for them. You almost always want to supply a FastaSeqFetcher (chained after SeqRepo) so every cdot transcript resolves against a local genome FASTA.

For fixing messy HGVS input and fast bulk processing, see Advanced usage.

PyHGVS example (needs pip install cdot[fasta] for pysam):

import pyhgvs
from pysam.libcfaidx import FastaFile
from cdot.pyhgvs.pyhgvs_transcript import JSONPyHGVSTranscriptFactory, RESTPyHGVSTranscriptFactory

genome = FastaFile("/data/annotation/fasta/GCF_000001405.25_GRCh37.p13_genomic.fna.gz")
factory = RESTPyHGVSTranscriptFactory()
# factory = JSONPyHGVSTranscriptFactory(["./cdot-0.2.32.refseq.grch37.json.gz"])  # Uses local JSON file
pyhgvs.parse_hgvs_name('NM_001637.3:c.1582G>A', genome, get_transcript=factory.get_transcript_grch37)

more PyHGVS examples:

Documentation

See docs/ for reference and how-to guides:

See the docs index for the full list (examples, FastaSeqFetcher, creating data, cdot vs UTA, …).

Q. What's the performance like?

Resolving real ClinVar c.HGVS to genomic coordinates (GRCh38, biocommons HGVS, local sequence fetching):

  • UTA public DB: ~1-1.5 seconds / transcript
  • cdot REST service: ~30 HGVS/second sequential, ~500 HGVS/second with prefetch() batch cache-warming
  • cdot JSON.gz (local): 500-1k/second

prefetch() warms every transcript in one batch round-trip up front, so bulk resolution over the REST service runs almost entirely from cache - closing most of the gap to local JSON.gz (~16x faster end-to-end on 500 variants). Reproduce with analysis/benchmark_resolution.py.

Q. Where can I download the JSON.gz files?

Download from GitHub releases - RefSeq (37/38) - 72M, Ensembl (37/38) 61M

Details on what the files contain here

Q. How does this compare to Universal Transcript Archive?

Both projects have similar goals of providing transcripts for loading HGVS, but they approach it from different ways

  • UTA aligns sequences, then stores coordinates in an SQL database.
  • cdot convert existing Ensembl/RefSeq GTFs into JSON

See cdot vs UTA for more details

Q. How do you store transcripts in JSON?

See the JSON data format reference for a full description of every field, with a machine-readable JSON Schema alongside it. Coordinates & exon alignments explains how exon coordinates and the alignment gap strings work. See also design notes on why the format looks the way it does.

You can also read the data with typed Python objects (no extra install required):

from cdot import models

data = models.load("cdot-0.2.32.refseq.GRCh38.json.gz")
tx = data.transcripts["NM_001637.3"]
print(tx.gene_name, tx.protein)

We think a standard for JSON gene/transcript information would be a great thing, and am keen to collaborate to make it happen!

Q. What does cdot stand for?

cdot, pronounced "see dot", is a play on the HGVS coding-sequence prefix :c.

This was developed for the Australian Genomics Shariant project, due to the need to load historical HGVS from lab archives.

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

cdot-0.2.28.tar.gz (81.2 kB view details)

Uploaded Source

Built Distribution

If you're not sure about the file name format, learn more about wheel file names.

cdot-0.2.28-py3-none-any.whl (66.8 kB view details)

Uploaded Python 3

File details

Details for the file cdot-0.2.28.tar.gz.

File metadata

  • Download URL: cdot-0.2.28.tar.gz
  • Upload date:
  • Size: 81.2 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/6.2.0 CPython/3.12.3

File hashes

Hashes for cdot-0.2.28.tar.gz
Algorithm Hash digest
SHA256 f898ff17bd484441e4b0157d17037b27c10c35e095c9c3cd8d930898e59b288d
MD5 8f0a5b5047fc0a69f066bcd931fc457c
BLAKE2b-256 64a16b2e5bb1f142002e500c6d365a39f4a0102f9e9173c0576eee6137243bbb

See more details on using hashes here.

File details

Details for the file cdot-0.2.28-py3-none-any.whl.

File metadata

  • Download URL: cdot-0.2.28-py3-none-any.whl
  • Upload date:
  • Size: 66.8 kB
  • Tags: Python 3
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/6.2.0 CPython/3.12.3

File hashes

Hashes for cdot-0.2.28-py3-none-any.whl
Algorithm Hash digest
SHA256 1688035f10a61b193f19af55190e8bd5a1aa934ab8837ffde6755a6a9a1bc6b8
MD5 54b4283af0491f74408398d7f3076ca3
BLAKE2b-256 5c0b5335ec7dc7506e7993f8fff499d4975bfe6b31c6ff6ce3fff7c8d5fc3c4b

See more details on using hashes here.

Supported by

AWS Cloud computing and Security Sponsor Datadog Monitoring Depot Continuous Integration Fastly CDN Google Download Analytics Pingdom Monitoring Sentry Error logging StatusPage Status page