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Filter and combine various peptide/MHC datasets to derive a composite training set,
optionally including eluted peptides identified by mass-spec.
"""
import sys
import argparse
import pandas
import mhcnames
def normalize_allele_name(s):
try:
return mhcnames.normalize_allele_name(s)
except Exception:
return "UNKNOWN"
parser = argparse.ArgumentParser(usage=__doc__)
parser.add_argument(
"--data-kim2014",
action="append",
default=[],
help="Path to Kim 2014-style affinity data")
parser.add_argument(
"--data-iedb",
action="append",
default=[],
help="Path to IEDB-style affinity data (e.g. mhc_ligand_full.csv)")
parser.add_argument(
"--data-systemhc-atlas",
action="append",
default=[],
help="Path to systemhc-atlas-style mass-spec data")
parser.add_argument(
action="store_true",
default=False,
help="Include mass-spec observations in IEDB")
parser.add_argument(
"--out-csv",
required=True,
help="Result file")
"Negative": (5000.0, ">"),
"Positive": (500.0, "<"), # used for mass-spec hits
"Positive-High": (100.0, "<"),
"Positive-Intermediate": (1000.0, "<"),
"Positive-Low": (5000.0, "<"),
QUALITATIVE_TO_AFFINITY = dict(
(key, value[0]) for (key, value)
in QUALITATIVE_TO_AFFINITY_AND_INEQUALITY.items())
QUALITATIVE_TO_INEQUALITY = dict(
(key, value[1]) for (key, value)
in QUALITATIVE_TO_AFFINITY_AND_INEQUALITY.items())
EXCLUDE_IEDB_ALLELES = [
"HLA class I",
"HLA class II",
]
def load_data_kim2014(filename):
df = pandas.read_table(filename)
print("Loaded kim2014 data: %s" % str(df.shape))
df["measurement_source"] = "kim2014"
df["measurement_value"] = df.meas
df["measurement_type"] = (df.inequality == "=").map({
True: "quantitative",
False: "qualitative",
})
df["original_allele"] = df.mhc
df["peptide"] = df.sequence
df["allele"] = df.mhc.map(normalize_allele_name)
print("Dropping un-parseable alleles: %s" % ", ".join(
df.ix[df.allele == "UNKNOWN"]["mhc"].unique()))
df = df.ix[df.allele != "UNKNOWN"]
print("Loaded kim2014 data: %s" % str(df.shape))
return df
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def load_data_systemhc_atlas(filename, min_probability=0.99):
df = pandas.read_csv(filename)
print("Loaded systemhc atlas data: %s" % str(df.shape))
df["measurement_source"] = "systemhc-atlas"
df["measurement_value"] = QUALITATIVE_TO_AFFINITY["Positive"]
df["measurement_inequality"] = "<"
df["measurement_type"] = "qualitative"
df["original_allele"] = df.top_allele
df["peptide"] = df.search_hit
df["allele"] = df.top_allele.map(normalize_allele_name)
print("Dropping un-parseable alleles: %s" % ", ".join(
str(x) for x in df.ix[df.allele == "UNKNOWN"]["top_allele"].unique()))
df = df.loc[df.allele != "UNKNOWN"]
print("Systemhc atlas data now: %s" % str(df.shape))
print("Dropping data points with probability < %f" % min_probability)
df = df.loc[df.prob >= min_probability]
print("Systemhc atlas data now: %s" % str(df.shape))
print("Removing duplicates")
df = df.drop_duplicates(["allele", "peptide"])
print("Systemhc atlas data now: %s" % str(df.shape))
return df
def load_data_iedb(iedb_csv, include_qualitative=True, include_mass_spec=False):
iedb_df = pandas.read_csv(iedb_csv, skiprows=1, low_memory=False)
print("Loaded iedb data: %s" % str(iedb_df.shape))
print("Selecting only class I")
iedb_df = iedb_df.ix[
iedb_df["MHC allele class"].str.strip().str.upper() == "I"
]
print("New shape: %s" % str(iedb_df.shape))
print("Dropping known unusuable alleles")
iedb_df = iedb_df.ix[
~iedb_df["Allele Name"].isin(EXCLUDE_IEDB_ALLELES)
]
iedb_df = iedb_df.ix[
(~iedb_df["Allele Name"].str.contains("mutant")) &
(~iedb_df["Allele Name"].str.contains("CD1"))
]
iedb_df["allele"] = iedb_df["Allele Name"].map(normalize_allele_name)
print("Dropping un-parseable alleles: %s" % ", ".join(
iedb_df.ix[iedb_df.allele == "UNKNOWN"]["Allele Name"].unique()))
iedb_df = iedb_df.ix[iedb_df.allele != "UNKNOWN"]
print("IEDB measurements per allele:\n%s" % iedb_df.allele.value_counts())
quantitative = iedb_df.ix[iedb_df["Units"] == "nM"].copy()
quantitative["measurement_type"] = "quantitative"
quantitative["measurement_inequality"] = quantitative[
"Measurement Inequality"
].fillna("=")
print("Quantitative measurements: %d" % len(quantitative))
qualitative = iedb_df.ix[iedb_df["Units"].isnull()].copy()
qualitative["measurement_type"] = "qualitative"
print("Qualitative measurements: %d" % len(qualitative))
if not include_mass_spec:
qualitative = qualitative.ix[
(~qualitative["Method/Technique"].str.contains("mass spec"))
].copy()
qualitative["Quantitative measurement"] = (
qualitative["Qualitative Measure"].map(QUALITATIVE_TO_AFFINITY))
qualitative["measurement_inequality"] = (
qualitative["Qualitative Measure"].map(QUALITATIVE_TO_INEQUALITY))
print("Qualitative measurements (possibly after dropping MS): %d" % (
len(qualitative)))
iedb_df = pandas.concat(
(
([quantitative]) +
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ignore_index=True)
print("IEDB measurements per allele:\n%s" % iedb_df.allele.value_counts())
print("Subselecting to valid peptides. Starting with: %d" % len(iedb_df))
iedb_df["Description"] = iedb_df.Description.str.strip()
iedb_df = iedb_df.ix[
iedb_df.Description.str.match("^[ACDEFGHIKLMNPQRSTVWY]+$")
]
print("Now: %d" % len(iedb_df))
print("Annotating last author and category")
iedb_df["last_author"] = iedb_df.Authors.map(
lambda x: (
x.split(";")[-1]
.split(",")[-1]
.split(" ")[-1]
.strip()
.replace("*", ""))).values
iedb_df["category"] = (
iedb_df["last_author"] + " - " + iedb_df["Method/Technique"]).values
train_data = pandas.DataFrame()
train_data["peptide"] = iedb_df.Description.values
train_data["measurement_value"] = iedb_df[
"Quantitative measurement"
].values
train_data["measurement_source"] = iedb_df.category.values
train_data["measurement_inequality"] = iedb_df.measurement_inequality.values
train_data["allele"] = iedb_df["allele"].values
train_data["original_allele"] = iedb_df["Allele Name"].values
train_data["measurement_type"] = iedb_df["measurement_type"].values
train_data = train_data.drop_duplicates().reset_index(drop=True)
return train_data
def run():
args = parser.parse_args(sys.argv[1:])
dfs = []
for filename in args.data_iedb:
df = load_data_iedb(filename, include_mass_spec=args.include_iedb_mass_spec)
dfs.append(df)
for filename in args.data_kim2014:
df = load_data_kim2014(filename)
df["allele_peptide"] = df.allele + "_" + df.peptide
# Give precedence to IEDB data.
if dfs:
iedb_df = dfs[0]
iedb_df["allele_peptide"] = iedb_df.allele + "_" + iedb_df.peptide
print("Dropping kim2014 data present in IEDB.")
df = df.ix[
~df.allele_peptide.isin(iedb_df.allele_peptide)
]
print("Kim2014 data now: %s" % str(df.shape))
dfs.append(df)
for filename in args.data_systemhc_atlas:
df = load_data_systemhc_atlas(filename)
dfs.append(df)
df = pandas.concat(dfs, ignore_index=True)
print("Combined df: %s" % (str(df.shape)))
print("Removing combined duplicates")
df = df.drop_duplicates(["allele", "peptide", "measurement_value"])
print("New combined df: %s" % (str(df.shape)))
df = df[[
"allele",
"peptide",
"measurement_value",
"measurement_type",
"measurement_source",
"original_allele",
]].sort_values(["allele", "peptide"]).dropna()
print("Final combined df: %s" % (str(df.shape)))
df.to_csv(args.out_csv, index=False)
print("Wrote: %s" % args.out_csv)
if __name__ == '__main__':
run()