ICGC Data Parser¶
What is the ICGC-data-parser?¶
A library to ease the parsing of data from the International Cancer Genome Consortium data releases, in particular, the simple somatic mutation aggregates.
Tutorial¶
Data download¶
The base data for the scripts is the ICGC’s aggregated of the simple somatic mutation data. Which can be downloded using
wget https://dcc.icgc.org/api/v1/download?fn=/current/Summary/simple_somatic_mutation.aggregated.vcf.gz
To know more about this file, please read About the ICGC’s simple somatic mutations file
WARNING: The current release of the data contains a malformed
header that causes the library to crash with an IndexError
:
---------------------------------------------------------------------------
ValueError Traceback (most recent call last)
~/.local/lib/python3.6/site-packages/vcf/parser.py in _parse_info(self, info_str)
389 try:
...
...
...
362 def _parse_info(self, info_str):
ValueError: could not convert string to float: 'PCAWG'
This is caused by a bad type specification in the header of the
VCF file. To solve it, use the lollowing line after creating the
SSM_Reader
object (asuming the reader is in the reader
variable)
# Fix weird bug due to malformed description headers
reader.infos['studies'] = reader.infos['studies']._replace(type='String')
In the future this will be solved in a more elegant way, but for now this is what we’ve got.
Usage¶
The main class in the project is the SSM_Reader. It allows to read easily the ICGC mutations file:
>>> from ICGC_data_parser import SSM_Reader
# Reads also compressed files!
>>> reader = SSM_Reader(open('data/simple_somatic_mutations.aggregated.vcf.gz'))
# or...
>>> reader = SSM_Reader(filename='data/simple_somatic_mutations.aggregated.vcf.gz')
# ^^^^^^^^
# The filename keyord argument is important, else we get an IndexError
The SSM_Reader.parse method allows to iterate through the records of the file and access the parts of the record. You can also specify regular expressions to filter only the lines you want:
# Print only the mutations that are in the
# European Union Breast Cancer project (BRCA-EU).
>>> for record in reader.parse(filters=['BRCA-EU']):
... print(record.ID, record.CHROM, record.POS)
MU66865518 1 100141201
MU65487875 1 100160548
MU66281118 1 100638179
MU66254120 1 101352655
...
The INFO field is special in the sense that it contains several subfields, AND those subfields may be list-like entries with more subfields themselves (in particular the CONSEQUENCE and OCCURRENCE subfields):
# The subfields of the INFO field:
>>> next(reader).INFO
{'CONSEQUENCE': [
'||||||intergenic_region||',
'CD1A|ENSG00000158477|+|CD1A-001|ENST00000289429||upstream_gene_variant||'
],
'OCCURRENCE': [
'ESAD-UK|1|301|0.00332',
'EOPC-DE|1|202|0.00495',
'BRCA-EU|1|569|0.00176'
],
'affected_donors': 3,
'mutation': 'T>A',
'project_count': 3,
'studies': None,
'tested_donors': 12068}
# The description of the CONSEQUENCE subfield
>>> print(reader.infos['CONSEQUENCE'].desc)
Mutation consequence predictions annotated by SnpEff
(subfields: gene_symbol|gene_affected|gene_strand|transcript_name|transcript_affected|protein_affected|consequence_type|cds_mutation|aa_mutation)
# The description of the OCCURRENCE subfield
>>> print(reader.infos['OCCURRENCE'].desc)
Mutation occurrence counts broken down by project
(subfields: project_code|affected_donors|tested_donors|frequency)
Sometimes we want to also parse the information in those subfields. For
this purpose, the SSM_Reader.subfield_parser
factory method is
useful. This method creates a parser of the specified subfield that
allows easy access to the data:
# Create the subfield parser for the CONSEQUENCE subfield
>>> consequences = reader.subfield_parser('CONSEQUENCE')
>>> for record in reader.parse():
... # Which genes are affected?
... genes_affected = {c.gene_symbol
... for c in consequences(record)
... if c.gene_affected}
...
... print(f'Mutation: {record.ID}')
... print('\t', ", ".join(genes_affected))
Mutation: MU93246178
TPM3
Mutation: MU66962994
RP11-350G8.9, SHE
Mutation: MU93246498
DCST1, ADAM15, RP11-307C12.11
Mutation: MU66377106
EFNA3, ADAM15, EFNA4
...
The library also contains some helper scripts to manipulate VCF files (like the ICGC mutations file):
vcf_map_assembly.py
: Creates a new VCF with the positions mapped to another genome assembly. This is useful because currently the positions reported by ICGC are in the human genome assembly GRCh37, while the most recent (and the one the rest of the world uses) is the GRCh38 assembly.vcf_sample.py
: Creates a new VCF with a fraction of the mutations in the original. The mutations are randomly sampled but maintain the order they had in the original file. This is useful when one wants to make small test analysis on the data, but still wants the results to be representative of all the mutations.vcf_split.py
: Splits the input VCF into several (also valid VCFs), this is useful in case one wants to split the analyses into processes that receive one file each.
The specific documentation of the scripts can be obtained by executing:
$ python3 <script name>.py --help
Also, the library is shipped with some Jupyter Notebooks that elaborate on the examples. Besides, in the notebooks are demonstrated ways to manage common parsing errors that have to do with malformed input files.
Meta¶
Author: Ad115 - Github – a.garcia230395@gmail.com
Project pages: Docs - @GitHub - @PyPI
Distributed under the MIT license. See LICENSE for more information.
Contributing¶
- Check for open issues or open a fresh issue to start a discussion around a feature idea or a bug.
- Fork the repository on GitHub to start making your changes to a feature branch, derived from the master branch.
- Write a test which shows that the bug was fixed or that the feature works as expected.
- Send a pull request and bug the maintainer until it gets merged and published.
Examples and more¶
Examples¶
Now we demonstrate more involved examples of what can be done with the library. Please read the Tutorial first to get started.
Finding the distribution of mutation consequences¶
Whether the mutations affect genes, cause frameshifts, fall in an intronic region or are silent SNPs, we want to know the relative abundance of these consequences:
from collections import Counter
from ICGC_data_parser import SSM_Reader
counter = Counter()
# Open the mutations file
mutations = SSM_Reader(filename='data/ssm_sample.vcf')
consequences = mutations.subfield_parser('CONSEQUENCE')
for record in mutations:
consequence_types = [c.consequence_type for c in consequences(record)]
counter.update(consequence_types)
total = sum(counter.values())
for consequence_type,n in counter.most_common():
print(f'{n/total :<10.3%} : {consequence_type}')
60.787% : intron_variant
17.344% : intergenic_region
8.558% : downstream_gene_variant
8.295% : upstream_gene_variant
1.657% : missense_variant
1.327% : exon_variant
0.746% : synonymous_variant
0.654% : 3_prime_UTR_variant
0.167% : splice_region_variant
0.144% : 5_prime_UTR_variant
0.103% : stop_gained
0.099% : frameshift_variant
...
As we can see, rather unexpectedly, an overwhelming amount of mutations fall in intronic regions. This is worth of more investigation.
Finding the distribution of mutation recurrence among patients¶
The ICGC data allows us to know, for each mutation, how many patients where affected by this mutation (the recurrence of the mutation). Thus, one can solve the question: Do the mutations in cancer patients follow a recurring pattern? In which case, the mutation recurrences must be more or less homogeneously distributed, or: Is it that every patient has their unique set of mutations? In which case, most mutations would appear only once.
Let’s try to solve this:
from collections import Counter
from ICGC_data_parser import SSM_Reader
# Open the mutations file
mutations = SSM_Reader(filename='data/ssm_sample.vcf')
# Fetch recurrence data per mutation
recurrence_distribution = Counter(mutation.INFO['affected_donors']
for mutation in mutations)
total = sum(recurrence_distribution.values())
for mut_recurrence,n in recurrence_distribution.most_common():
print(f'{n/total :<10.3%} : Mutations recurred in {mut_recurrence} patients.')
92.324% : Mutations recurred in 1 patients.
6.058% : Mutations recurred in 2 patients.
0.990% : Mutations recurred in 3 patients.
0.327% : Mutations recurred in 4 patients.
0.132% : Mutations recurred in 5 patients.
0.061% : Mutations recurred in 6 patients.
0.035% : Mutations recurred in 7 patients.
0.026% : Mutations recurred in 8 patients.
0.015% : Mutations recurred in 9 patients.
0.012% : Mutations recurred in 10 patients.
0.010% : Mutations recurred in 11 patients.
...
As we can see, most of the mutations are only present in very few patients, and taking into account that the file aggregates more than 10,000 patients’ worth of data, this tells us that every patient’s mutational footprint is essentially unique.
The Jupyter notebook recurrence_distribution.ipynb
from the library
elaborates on this example and shows how to plot this and fit to a power
law. The presence of a power law means that the mutations present
themselves as randomly as they can:
Finding the distribution of mutatios among genes¶
From the above example, we can see that, per nucleotide, the mutations can be considered essentially random. But, we can try to take a more coarse grained approach and quantify the mutations by gene so that it may be that the mutations divide randomly among all genes (in which case we may find almost all genes with the same number of mutations), or we may find that some genes have significantly more mutations than the rest.
This is how we may find out:
from collections import Counter
from ICGC_data_parser import SSM_Reader
# -- 1. Get the mutations count per gene
mutations_per_gene = Counter()
mutations = SSM_Reader(filename='data/ssm_sample.vcf')
consequences = mutations.subfield_parser('CONSEQUENCE')
for record in mutations:
affected_genes = [c.gene_symbol for c in consequences(record) if c.gene_affected]
mutations_per_gene.update(affected_genes)
# Show partial results
for gene,mutations in mutations_per_gene.most_common():
print(f'{gene:<10}: {mutations}')
PCDH15 : 1651
RBFOX1 : 1041
CSMD1 : 979
DLG2 : 941
SPOCK3 : 929
DPP10 : 649
CTNND2 : 632
...
# -- 2. Now group by number of mutations
distribution = Counter(mutations_per_gene.values())
X | NO. OF GENES WITH X MUTATIONS
----------------------------------------
1 | 8600
2 | 3624
3 | 1638
4 | 1403
6 | 1001
5 | 877
8 | 712
...
In the script mutations_distribution_genes.ipynb
we can see how we
plot this data. For now, the resulting figure is the following:
But remember that genes have wildly varying lengths:
So, the distribution of mutations may be convoluted by the distribution of gene lengths. In order to smooth out this effect, we want to plot not the total number of mutations per gene, but the mutation density (the number of mutations normalized by the gene length).
To do this we need to check gene lengths, and the easiest way to do this
is via the Ensembl REST API, which we may use with the module
ensembl_rest
. The following shows how to do this:
# In order to find out the length of the
# genes, we will use the Ensembl REST API.
import ensembl_rest
from itertools import islice
def chunks_of(iterable, size=10):
"""A generator that yields chunks of fixed size from the iterable."""
iterator = iter(iterable)
while True:
next_ = list(islice(iterator, size))
if next_:
yield next_
else:
break
# ---
# -- 3. Normalize mutation counts by gene length
# Instantiate a client for communication with
# the Ensembl REST API.
client = ensembl_rest.EnsemblClient()
normalized_counts = Counter()
for gene_batch in chunks_of(mutations_per_gene, size=1000):
# Get information of the genes
gene_data = client.symbol_post('human',
params={'symbols': gene_batch})
gene_lengths = {gene: data['end'] - data['start'] + 1
for gene, data in gene_data.items()}
# Get the normalization
normalized_counts.update({
gene: mutations_per_gene[gene] / gene_lengths[gene]
for gene in gene_data
})
# Show partial results
for gene,mutations in normalized_counts.most_common():
print(f'{gene:<10}: {mutations}')
IGHD7-27 : 0.5454545454545454
IGKJ1 : 0.2894736842105263
IGKJ3 : 0.2894736842105263
IGKJ2 : 0.28205128205128205
SNORD112 : 0.18181818181818182
IGHJ3P : 0.18
IGHJ5 : 0.16326530612244897
...
# -- 4. Aggregate by mutation density
normalized_distribution = Counter(normalized_counts.values())
X | NO. OF GENES WITH X MUTATION DENSITY
----------------------------------------
0.9346% | 112
0.9615% | 33
0.9524% | 26
0.9434% | 23
1.6129% | 20
1.8692% | 20
0.9804% | 19
1.2195% | 19
...
Now we can plot this data. The code to do so is in the notebook
mutations_distribution_genes.ipynb
. For now, the figure that results
is the following:
Plotting the mutation density in the chromosomes¶
The example notebook mutation_distribution_chroms.ipynb
shows how to
plot the mutations distribution in the chromosomes. This is useful when
one wants to compare the variations among different projects. The
resulting figures are as the following one (with the chromosome and
centromere boundaries shown):
The ICGC’s mutations file¶
This is about the infamous simple_somatic_mutations.aggregated.vcf
file
presented in each ICGC Data Release which contains an aggregated of the
information of all simple somatic mutations found accross all patients in all
cancer projects is found.
Download¶
This file can be downloaded from the ICGC site data releases site or using:
$ wget https://dcc.icgc.org/api/v1/download?fn=/current/Summary/simple_somatic_mutation.aggregated.vcf.gz
To resume an interrupted download use the -c
switch on the previous command.
Then, the file can be extracted with the gunzip
command (or not, the ICGC_data_parser.SSM_Reader
can read compressed files too ;D).
Structure¶
The simple_somatic_mutations.aggregated.vcf
file, from now on referred as the SSM file, is a VCF file as specified in HTS format specifications, and in particular, the SSM files are created using the SnpEff annotation tool.
In general, the format is similar to a TSV file in which the comments are marked with ##
and the headers line with #
and there is one line per simple-somatic-mutation found.
Fields and Header lines¶
Next are the 13 heading lines from a SSM file (data release 22):
##fileformat=VCFv4.1
##INFO=<ID=CONSEQUENCE,Number=.,Type=String,Description="Mutation consequence predictions annotated by SnpEff (subfields: gene_symbol|gene_affected|gene_strand|transcript_name|transcript_affected|protein_affected|consequence_type|cds_mutation|aa_mutation)">
##INFO=<ID=OCCURRENCE,Number=.,Type=String,Description="Mutation occurrence counts broken down by project (subfields: project_code|affected_donors|tested_donors|frequency)">
##INFO=<ID=affected_donors,Number=1,Type=Integer,Description="Number of donors with the current mutation">
##INFO=<ID=mutation,Number=1,Type=String,Description="Somatic mutation definition">
##INFO=<ID=project_count,Number=1,Type=Integer,Description="Number of projects with the current mutation">
##INFO=<ID=tested_donors,Number=1,Type=Integer,Description="Total number of donors with SSM data available">
##comment=ICGC open access Simple Somatic Mutations (SSM) data dump in VCF format
##fileDate=2016-08-16T16:32:17.882-04:00
##geneModel=ENSEMBL75
##reference=GRCh37
##source=ICGC22-12
#CHROM POS ID REF ALT QUAL FILTER INFO
- This is what we can see in those lines:
- fileformat: A line specifying the VCF version (4.1).
- INFO: Six lines breaking down each part of the INFO field.
- comment:A general description of the file (ICGC open access Simple Somatic Mutations (SSM) data dump in VCF format).
- fileDate: The creation date of the file (August 2016).
- geneModel: A specification of the gene model (ENSEMBL75). This is the nameset used for the annotations in the INFO field. In particular the identifiers and names in the CONSEQUENCE subfield. WATCH OUT! Some genes, transcripts and identifiers annotated may have changed for the current release and so may not be found in a direct query. At the moment of writing, the most recent build is Ensembl 87.
- reference: The genome assembly version used for the positions in the reference genome (GRCh37). WATCH OUT THIS! The positions may have dramatic changes from one assembly to another. At the moment, the most recent version of the human genome reference is the GRCh38 assembly.
- source: The data source (ICGC Data release 22)
- The column headers: See section The column headers.
The column headers¶
- The data is split in these fields:
- CHROM: The chromosome the mutation is in.
- POS: The position in the chromosome of the start of the mutation. This is in the reference assembly specified in the initial comments.
- ID: The current mutation’s ICGC identifier.
- REF: The sequence found in the reference.
- ALT: The sequence found in the mutated sample, so that the mutation definition is REF>ALT.
- QUAL: The quality of the read. As a general rule, a quality <10 is unreliable.
- FILTER.
- INFO: Additional annotation on the mutation consequences, and occurrence along patients and projects. It is further commented on The INFO Field
The INFO field¶
This field annotates predicted consequences, and seen occurrences of the current mutation. The consequences are as seen by the SnpEff package.
There may be multiple consecuences and occurrences of the same mutation, and those need to be clearly specified. Thus the complex form of this field.
In the file, the parts are separated with a semicolon ( ;
), and each part may have itself subfields, which are separated with pipes ( |
).
Alternative parts (e.g. different consequences for the mutation or occurrences in different cancer projects) are separated by a comma ( ,
).
- CONSEQUENCE: Mutation consequence predictions annotated by SnpEff. Which has itself the next subfields:
- gene_symbol,
- gene_affected,
- gene_strand,
- transcript_name,
- transcript_affected,
- protein_affected,
- consequence_type,
- cds_mutation,
- aa_mutation
- OCCURRENCE: Mutation occurrence counts broken down by project. Which has itself the next subfields:
- project_code,
- affected_donors,
- tested_donors,
- frequency
- affected_donors: Total number of donors with the current mutation.
- mutation: Somatic mutation definition, in the form BEFORE>AFTER.
- project_count: Number of projects with the current mutation.
- tested_donors: Total number of donors with SSM data available.
Interpreting a sample mutation¶
Now we are ready to interpret an example mutation line from the data.
The mutation¶
#CHROM POS ID REF ALT QUAL FILTER INFO
1 100000022 MU39532371 C T . . CONSEQUENCE=||||||intergenic_region||,RP11-413P11.1|ENSG00000224445|1|RP11-413P11.1-001|ENST00000438829||upstream_gene_variant||;OCCURRENCE=SKCA-BR|1|70|0.01429;affected_donors=1;mutation=C>T;project_count=1;tested_donors=10638
The interpretation¶
We can see the data for the mutation MU39532371, which is in the chromosome number 1, at the position 100000022, and is defined as C>T, with no quality or filtering information available. We can also see in the INFO that this mutation has two consequences: one as a mutation ocurring in an intergenic region, and one as a mutation that affects the ENSG00000224445 (RP11-413P11.1) gene and it’s ENST00000438829 (RP11-413P11.1-001) transcript provoking an upstream_gene_variant. Besides, it was found in a sample from the Great Britain’s skin cancer ICGC project (SKCA-BR) with 1 patient affected out of the 70 in the project and of the 10638 accross all projects.
API Documentation¶
-
class
ICGC_data_parser.
SSM_Reader
(*args, **kwargs)[source]¶ Reader class for the International Cancer Genome Consortium aggregate file of simple somatic mutations from the Data Releases.
Example:
>>> reader = SSM_Reader(filename='data/ssm_sample.vcf') >>> for record in reader.parse(filters=['BRCA-EU']): ... print(record.ID, record.CHROM, record.POS) MU66865518 1 100141201 MU65487875 1 100160548 MU66281118 1 100638179 MU66254120 1 101352655 ...
-
iter_lines
(filters=None)[source]¶ Iterate through the file’s raw lines, filtering out the ones not matching the regular expressions given.
-
next_array
(strict_whitespace=False)[source]¶ Fetch the next line splitted into fields.
If
strict_whitespace
is True, then split on tabs rather than whitespace. This allows for fields with spaces in them.
-
parse
(filters=None)[source]¶ Iterate through the records of the file, filtering out the lines that do not match the regular expressions given.
Example:
>>> reader = SSM_Reader(filename='data/ssm_sample.vcf') >>> for record in reader.parse(filters=['BRCA-EU']): ... print(record.ID) MU66865518 MU65487875 MU66281118 MU66254120 ...
-
subfield_parser
(sf_name, sep='|')[source]¶ Get a parser for the items of the subfield.
Useful to parse the CONSEQUENCE and OCCURRENCE subfields of the INFO field.
Example:
>>> reader = SSM_Reader(filename='data/ssm_sample.vcf') >>> CONSEQUENCE = reader.subfield_parser('CONSEQUENCE') >>> for record in reader.parse(filters=['BRCA-EU']): ... # Which genes are affected? ... print(CONSEQUENCE(record)[0].gene_symbol) SLC27A3 GATAD2B TPM3 SHE ADAM15 ...
-