# Copyright 2007 by Michiel de Hoon. All rights reserved. # This code is part of the Biopython distribution and governed by its # license. Please see the LICENSE file that should have been included # as part of this package. """Code to work with the sprotXX.dat file from SwissProt. https://web.expasy.org/docs/userman.html Classes: - Record Holds SwissProt data. - Reference Holds reference data from a SwissProt record. Functions: - read Read one SwissProt record - parse Read multiple SwissProt records """ import io import re from Bio.SeqFeature import SeqFeature, SimpleLocation, Position class SwissProtParserError(ValueError): """An error occurred while parsing a SwissProt file.""" def __init__(self, *args, line=None): """Create a SwissProtParserError object with the offending line.""" super().__init__(*args) self.line = line class Record: """Holds information from a SwissProt record. Attributes: - entry_name Name of this entry, e.g. RL1_ECOLI. - data_class Either 'STANDARD' or 'PRELIMINARY'. - molecule_type Type of molecule, 'PRT', - sequence_length Number of residues. - accessions List of the accession numbers, e.g. ['P00321'] - created A tuple of (date, release). - sequence_update A tuple of (date, release). - annotation_update A tuple of (date, release). - description Free-format description. - gene_name A list of dictionaries with keys 'Name', 'Synonyms', 'OrderedLocusNames' and 'ORFNames'. - organism The source of the sequence. - organelle The origin of the sequence. - organism_classification The taxonomy classification. List of strings. (http://www.ncbi.nlm.nih.gov/Taxonomy/) - taxonomy_id A list of NCBI taxonomy id's. - host_organism A list of names of the hosts of a virus, if any. - host_taxonomy_id A list of NCBI taxonomy id's of the hosts, if any. - references List of Reference objects. - comments List of strings. - cross_references List of tuples (db, id1[, id2][, id3]). See the docs. - keywords List of the keywords. - features List of tuples (key name, from, to, description). from and to can be either integers for the residue numbers, '<', '>', or '?' - protein_existence Numerical value describing the evidence for the existence of the protein. - seqinfo tuple of (length, molecular weight, CRC32 value) - sequence The sequence. Examples -------- >>> from Bio import SwissProt >>> example_filename = "SwissProt/P68308.txt" >>> with open(example_filename) as handle: ... records = SwissProt.parse(handle) ... for record in records: ... print(record.entry_name) ... print(record.accessions) ... print(record.keywords) ... print(record.organism) ... print(record.sequence[:20] + "...") ... NU3M_BALPH ['P68308', 'P24973'] ['Electron transport', 'Membrane', 'Mitochondrion', 'Mitochondrion inner membrane', 'NAD', 'Respiratory chain', 'Translocase', 'Transmembrane', 'Transmembrane helix', 'Transport', 'Ubiquinone'] Balaenoptera physalus (Fin whale) (Balaena physalus). MNLLLTLLTNTTLALLLVFI... """ def __init__(self): """Initialize the class.""" self.entry_name = None self.data_class = None self.molecule_type = None self.sequence_length = None self.accessions = [] self.created = None self.sequence_update = None self.annotation_update = None self.description = [] self.gene_name = [] self.organism = [] self.organelle = "" self.organism_classification = [] self.taxonomy_id = [] self.host_organism = [] self.host_taxonomy_id = [] self.references = [] self.comments = [] self.cross_references = [] self.keywords = [] self.features = [] self.protein_existence = "" self.seqinfo = None self.sequence = "" class Reference: """Holds information from one reference in a SwissProt entry. Attributes: - number Number of reference in an entry. - evidence Evidence code. List of strings. - positions Describes extent of work. List of strings. - comments Comments. List of (token, text). - references References. List of (dbname, identifier). - authors The authors of the work. - title Title of the work. - location A citation for the work. """ def __init__(self): """Initialize the class.""" self.number = None self.positions = [] self.comments = [] self.references = [] self.authors = [] self.title = [] self.location = [] class FeatureTable(SeqFeature): """Stores feature annotations for specific regions of the sequence. This is a subclass of SeqFeature, defined in Bio.SeqFeature, where the attributes are used as follows: - ``location``: location of the feature on the canonical or isoform sequence; the location is stored as an instance of SimpleLocation, defined in Bio.SeqFeature, with the ref attribute set to the isoform ID referring to the canonical or isoform sequence on which the feature is defined - ``id``: unique and stable identifier (FTId), only provided for features belonging to the types CARBOHYD, CHAIN, PEPTIDE, PROPEP, VARIANT, or VAR_SEQ - ``type``: indicates the type of feature, as defined by the UniProt Knowledgebase documentation: - ACT_SITE: amino acid(s) involved in the activity of an enzyme - BINDING: binding site for any chemical group - CARBOHYD: glycosylation site; an FTId identifier to the GlyConnect database is provided if annotated there - CA_BIND: calcium-binding region - CHAIN: polypeptide chain in the mature protein - COILED: coiled-coil region - COMPBIAS: compositionally biased region - CONFLICT: different sources report differing sequences - CROSSLNK: posttransationally formed amino acid bond - DISULFID: disulfide bond - DNA_BIND: DNA-binding region - DOMAIN: domain, defined as a specific combination of secondary structures organized into a characteristic three-dimensional structure or fold - INIT_MET: initiator methionine - INTRAMEM: region located in a membrane without crossing it - HELIX: alpha-, 3(10)-, or pi-helix secondary structure - LIPID: covalent binding of a lipid moiety - METAL: binding site for a metal ion - MOD_RES: posttranslational modification (PTM) of a residue, annotated by the controlled vocabulary defined by the ptmlist.txt document on the UniProt website - MOTIF: short sequence motif of biological interest - MUTAGEN: site experimentally altered by mutagenesis - NON_CONS: non-consecutive residues - NON_STD: non-standard amino acid - NON_TER: the residue at an extremity of the sequence is not the terminal residue - NP_BIND: nucleotide phosphate-binding region - PEPTIDE: released active mature polypeptide - PROPEP: any processed propeptide - REGION: region of interest in the sequence - REPEAT: internal sequence repetition - SIGNAL: signal sequence (prepeptide) - SITE: amino-acid site of interest not represented by another feature key - STRAND: beta-strand secondary structure; either a hydrogen-bonded extended beta strand or a residue in an isolated beta-bridge - TOPO_DOM: topological domain - TRANSIT: transit peptide (mitochondrion, chloroplast, thylakoid, cyanelle, peroxisome, etc.) - TRANSMEM: transmembrane region - TURN: H-bonded turn (3-, 4-, or 5-turn) - UNSURE: uncertainties in the sequence - VARIANT: sequence variant; an FTId is provided for protein sequence variants of Hominidae (great apes and humans) - VAR_SEQ: sequence variant produced by alternative splicing, alternative promoter usage, alternative initiation, or ribosomal frameshifting - ZN_FING: zinc finger region - qualifiers A dictionary of additional information, which may include the feature evidence and free-text notes. While SwissProt includes the feature identifier code (FTId) as a qualifier, it is stored as the attribute ID of the FeatureTable object. """ def parse(source): """Read multiple SwissProt records from file. Argument source is a file-like object or a path to a file. Returns a generator object which yields Bio.SwissProt.Record() objects. """ handle = _open(source) try: while True: record = _read(handle) if not record: return yield record finally: if handle is not source: handle.close() def read(source): """Read one SwissProt record from file. Argument source is a file-like object or a path to a file. Returns a Record() object. """ handle = _open(source) try: record = _read(handle) if not record: raise ValueError("No SwissProt record found") # We should have reached the end of the record by now. # Try to read one more line to be sure: try: next(handle) except StopIteration: return record raise ValueError("More than one SwissProt record found") finally: if handle is not source: handle.close() # Everything below is considered private def _open(source): try: handle = open(source) return handle except TypeError: handle = source if handle.read(0) == "": # handle is text; assume the encoding is compatible with ASCII return handle # handle is binary; SwissProt encoding is always ASCII return io.TextIOWrapper(handle, encoding="ASCII") def _read(handle): record = None unread = "" try: line = next(handle) except StopIteration: return record key, value = line[:2], line[5:].rstrip() if key != "ID": raise SwissProtParserError("Failed to find ID in first line", line=line) record = Record() _read_id(record, line) _sequence_lines = [] for line in handle: key, value = line[:2], line[5:].rstrip() if unread: value = unread + " " + value unread = "" if key == "AC": accessions = value.rstrip(";").split("; ") record.accessions.extend(accessions) elif key == "DT": _read_dt(record, line) elif key == "DE": record.description.append(value.strip()) elif key == "GN": if value == "and": record.gene_name.append("") else: if len(record.gene_name) == 0: record.gene_name.append("") record.gene_name[-1] += value + " " elif key == "OS": record.organism.append(value) elif key == "OG": record.organelle += line[5:] elif key == "OC": cols = value.rstrip(";.").split("; ") record.organism_classification.extend(cols) elif key == "OX": _read_ox(record, line) elif key == "OH": _read_oh(record, line) elif key == "RN": reference = Reference() _read_rn(reference, value) record.references.append(reference) elif key == "RP": assert record.references, "RP: missing RN" record.references[-1].positions.append(value) elif key == "RC": assert record.references, "RC: missing RN" reference = record.references[-1] unread = _read_rc(reference, value) elif key == "RX": assert record.references, "RX: missing RN" reference = record.references[-1] _read_rx(reference, value) elif key == "RL": assert record.references, "RL: missing RN" reference = record.references[-1] reference.location.append(value) # In UniProt release 1.12 of 6/21/04, there is a new RG # (Reference Group) line, which references a group instead of # an author. Each block must have at least 1 RA or RG line. elif key == "RA": assert record.references, "RA: missing RN" reference = record.references[-1] reference.authors.append(value) elif key == "RG": assert record.references, "RG: missing RN" reference = record.references[-1] reference.authors.append(value) elif key == "RT": assert record.references, "RT: missing RN" reference = record.references[-1] reference.title.append(value) elif key == "CC": _read_cc(record, line) elif key == "DR": _read_dr(record, value) elif key == "PE": _read_pe(record, value) elif key == "KW": _read_kw(record, value) elif key == "FT": _read_ft(record, line) elif key == "SQ": cols = value.split() assert len(cols) == 7, f"I don't understand SQ line {line}" # Do more checking here? record.seqinfo = int(cols[1]), int(cols[3]), cols[5] elif key == " ": _sequence_lines.append(value.replace(" ", "").rstrip()) elif key == "//": _read_gn(record) # Join multiline data into one string record.description = " ".join(record.description) record.organism = " ".join(record.organism) record.organelle = record.organelle.rstrip() for reference in record.references: reference.authors = " ".join(reference.authors).rstrip(";") if reference.title: title = reference.title[0] for fragment in reference.title[1:]: if not title.endswith("-"): title += " " title += fragment title = title.rstrip(";") if title.startswith('"') and title.endswith('"'): title = title[1:-1] # remove quotes else: title = "" reference.title = title reference.location = " ".join(reference.location) record.sequence = "".join(_sequence_lines) return record elif key == "**": # Do this one last, as it will almost never occur. # See Bug 2353, some files from the EBI have extra lines # starting "**" (two asterisks/stars). They appear # to be unofficial automated annotations. e.g. # ** # ** ################# INTERNAL SECTION ################## # **HA SAM; Annotated by PicoHamap 1.88; MF_01138.1; 09-NOV-2003. pass else: raise SwissProtParserError(f"Unknown keyword {key!r} found", line=line) if record: raise ValueError("Unexpected end of stream.") def _read_gn(record): for i, text in enumerate(record.gene_name): tokens = text.rstrip("; ").split("; ") gene_name = {} for token in tokens: # value may include an equals sign, e.g. # GN Name=Lacc1=POX4 {ECO:0000313|EMBL:KDQ27217.1}; key, value = token.strip().split("=", 1) if key == "Name": gene_name["Name"] = value else: assert key in ("Synonyms", "OrderedLocusNames", "ORFNames") gene_name[key] = value.split(", ") record.gene_name[i] = gene_name def _read_id(record, line): cols = line[5:].split() # Prior to release 51, included with MoleculeType: # ID EntryName DataClass; MoleculeType; SequenceLength AA. # # Newer files lack the MoleculeType: # ID EntryName DataClass; SequenceLength AA. if len(cols) == 5: record.entry_name = cols[0] record.data_class = cols[1].rstrip(";") record.molecule_type = cols[2].rstrip(";") record.sequence_length = int(cols[3]) elif len(cols) == 4: record.entry_name = cols[0] record.data_class = cols[1].rstrip(";") record.molecule_type = None record.sequence_length = int(cols[2]) else: raise SwissProtParserError("ID line has unrecognised format", line=line) # check if the data class is one of the allowed values allowed = ("STANDARD", "PRELIMINARY", "IPI", "Reviewed", "Unreviewed") if record.data_class not in allowed: message = f"Unrecognized data class {record.data_class!r}" raise SwissProtParserError(message, line=line) # molecule_type should be 'PRT' for PRoTein # Note that has been removed in recent releases (set to None) if record.molecule_type not in (None, "PRT"): message = f"Unrecognized molecule type {record.molecule_type!r}" raise SwissProtParserError(message, line=line) def _read_dt(record, line): value = line[5:] uprline = value.upper() cols = value.rstrip().split() if ( "CREATED" in uprline or "LAST SEQUENCE UPDATE" in uprline or "LAST ANNOTATION UPDATE" in uprline ): # Old style DT line # ================= # e.g. # DT 01-FEB-1995 (Rel. 31, Created) # DT 01-FEB-1995 (Rel. 31, Last sequence update) # DT 01-OCT-2000 (Rel. 40, Last annotation update) # # or: # DT 08-JAN-2002 (IPI Human rel. 2.3, Created) # ... # find where the version information will be located # This is needed for when you have cases like IPI where # the release version is in a different spot: # DT 08-JAN-2002 (IPI Human rel. 2.3, Created) uprcols = uprline.split() rel_index = -1 for index in range(len(uprcols)): if "REL." in uprcols[index]: rel_index = index assert rel_index >= 0, f"Could not find Rel. in DT line: {line}" version_index = rel_index + 1 # get the version information str_version = cols[version_index].rstrip(",") # no version number if str_version == "": version = 0 # dot versioned elif "." in str_version: version = str_version # integer versioned else: version = int(str_version) date = cols[0] if "CREATED" in uprline: record.created = date, version elif "LAST SEQUENCE UPDATE" in uprline: record.sequence_update = date, version elif "LAST ANNOTATION UPDATE" in uprline: record.annotation_update = date, version else: raise SwissProtParserError("Unrecognised DT (DaTe) line", line=line) elif ( "INTEGRATED INTO" in uprline or "SEQUENCE VERSION" in uprline or "ENTRY VERSION" in uprline ): # New style DT line # ================= # As of UniProt Knowledgebase release 7.0 (including # Swiss-Prot release 49.0 and TrEMBL release 32.0) the # format of the DT lines and the version information # in them was changed - the release number was dropped. # # For more information see bug 1948 and # http://ca.expasy.org/sprot/relnotes/sp_news.html#rel7.0 # # e.g. # DT 01-JAN-1998, integrated into UniProtKB/Swiss-Prot. # DT 15-OCT-2001, sequence version 3. # DT 01-APR-2004, entry version 14. # # This is a new style DT line... # The date should be in string cols[1] # Get the version number if there is one. # For the three DT lines above: 0, 3, 14 try: version = 0 for s in cols[-1].split("."): if s.isdigit(): version = int(s) except ValueError: version = 0 date = cols[0].rstrip(",") # Re-use the historical property names, even though # the meaning has changed slightly: if "INTEGRATED" in uprline: record.created = date, version elif "SEQUENCE VERSION" in uprline: record.sequence_update = date, version elif "ENTRY VERSION" in uprline: record.annotation_update = date, version else: raise SwissProtParserError("Unrecognised DT (DaTe) line", line=line) else: raise SwissProtParserError("Failed to parse DT (DaTe) line", line=line) def _read_ox(record, line): # The OX line used to be in the simple format: # OX DESCRIPTION=ID[, ID]...; # If there are too many id's to fit onto a line, then the ID's # continue directly onto the next line, e.g. # OX DESCRIPTION=ID[, ID]... # OX ID[, ID]...; # Currently, the description is always "NCBI_TaxID". # To parse this, I need to check to see whether I'm at the # first line. If I am, grab the description and make sure # it's an NCBI ID. Then, grab all the id's. # # As of the 2014-10-01 release, there may be an evidence code, e.g. # OX NCBI_TaxID=418404 {ECO:0000313|EMBL:AEX14553.1}; # In the short term, we will ignore any evidence codes: line = line.split("{")[0] if record.taxonomy_id: ids = line[5:].rstrip().rstrip(";") else: descr, ids = line[5:].rstrip().rstrip(";").split("=") assert descr == "NCBI_TaxID", f"Unexpected taxonomy type {descr}" record.taxonomy_id.extend(ids.split(", ")) def _read_oh(record, line): # Line type OH (Organism Host) for viral hosts assert line[5:].startswith("NCBI_TaxID="), f"Unexpected {line}" line = line[16:].rstrip() assert line[-1] == "." and line.count(";") == 1, line taxid, name = line[:-1].split(";") record.host_taxonomy_id.append(taxid.strip()) record.host_organism.append(name.strip()) def _read_rn(reference, rn): # This used to be a very simple line with a reference number, e.g. # RN [1] # As of the 2014-10-01 release, there may be an evidence code, e.g. # RN [1] {ECO:0000313|EMBL:AEX14553.1} words = rn.split(None, 1) number = words[0] assert number.startswith("[") and number.endswith("]"), f"Missing brackets {number}" reference.number = int(number[1:-1]) if len(words) > 1: evidence = words[1] assert evidence.startswith("{") and evidence.endswith( "}" ), f"Missing braces {evidence}" reference.evidence = evidence[1:-1].split("|") def _read_rc(reference, value): cols = value.split(";") if value[-1] == ";": unread = "" else: cols, unread = cols[:-1], cols[-1] for col in cols: if not col: # last column will be the empty string return # The token is everything before the first '=' character. i = col.find("=") if i >= 0: token, text = col[:i], col[i + 1 :] comment = token.lstrip(), text reference.comments.append(comment) else: comment = reference.comments[-1] comment = f"{comment} {col}" reference.comments[-1] = comment return unread def _read_rx(reference, value): # The basic (older?) RX line is of the form: # RX MEDLINE; 85132727. # but there are variants of this that need to be dealt with (see below) # CLD1_HUMAN in Release 39 and DADR_DIDMA in Release 33 # have extraneous information in the RX line. Check for # this and chop it out of the line. # (noticed by katel@worldpath.net) value = value.replace(" [NCBI, ExPASy, Israel, Japan]", "") # RX lines can also be used of the form # RX PubMed=9603189; # reported by edvard@farmasi.uit.no # and these can be more complicated like: # RX MEDLINE=95385798; PubMed=7656980; # RX PubMed=15060122; DOI=10.1136/jmg 2003.012781; # We look for these cases first and deal with them warn = False if "=" in value: cols = value.split("; ") cols = [x.strip() for x in cols] cols = [x for x in cols if x] for col in cols: x = col.split("=") if len(x) != 2 or x == ("DOI", "DOI"): warn = True break assert len(x) == 2, f"I don't understand RX line {value}" reference.references.append((x[0], x[1].rstrip(";"))) # otherwise we assume we have the type 'RX MEDLINE; 85132727.' else: cols = value.split("; ") # normally we split into the three parts if len(cols) != 2: warn = True else: reference.references.append((cols[0].rstrip(";"), cols[1].rstrip("."))) if warn: import warnings from Bio import BiopythonParserWarning warnings.warn(f"Possibly corrupt RX line {value!r}", BiopythonParserWarning) def _read_cc(record, line): key, value = line[5:8], line[9:].rstrip() if key == "-!-": # Make a new comment record.comments.append(value) elif key == " ": # add to the previous comment if not record.comments: # TCMO_STRGA in Release 37 has comment with no topic record.comments.append(value) else: record.comments[-1] += " " + value def _read_dr(record, value): cols = value.rstrip(".").split("; ") record.cross_references.append(tuple(cols)) def _read_pe(record, value): pe = value.split(":") record.protein_existence = int(pe[0]) def _read_kw(record, value): # Old style - semi-colon separated, multi-line. e.g. Q13639.txt # KW Alternative splicing; Cell membrane; Complete proteome; # KW Disulfide bond; Endosome; G-protein coupled receptor; Glycoprotein; # KW Lipoprotein; Membrane; Palmitate; Polymorphism; Receptor; Transducer; # KW Transmembrane. # # New style as of 2014-10-01 release with evidence codes, e.g. H2CNN8.txt # KW Monooxygenase {ECO:0000313|EMBL:AEX14553.1}; # KW Oxidoreductase {ECO:0000313|EMBL:AEX14553.1}. # For now to match the XML parser, drop the evidence codes. for val in value.rstrip(";.").split("; "): if val.endswith("}"): # Discard the evidence code val = val.rsplit("{", 1)[0] record.keywords.append(val.strip()) def _read_ft(record, line): name = line[5:13].rstrip() if name: if line[13:21] == " ": # new-style FT line location = line[21:80].rstrip() try: isoform_id, location = location.split(":") except ValueError: isoform_id = None try: from_res, to_res = location.split("..") except ValueError: from_res = location to_res = "" qualifiers = {} else: # old-style FT line from_res = line[14:20].lstrip() to_res = line[21:27].lstrip() isoform_id = None description = line[34:75].rstrip() qualifiers = {"description": description} from_res = Position.fromstring(from_res, -1) if to_res == "": to_res = from_res + 1 else: to_res = Position.fromstring(to_res) location = SimpleLocation(from_res, to_res, ref=isoform_id) feature = FeatureTable( location=location, type=name, id=None, qualifiers=qualifiers ) record.features.append(feature) return # this line is a continuation of the previous feature feature = record.features[-1] if line[5:34] == " ": # old-style FT line description = line[34:75].rstrip() if description.startswith("/FTId="): # store the FTId as the feature ID feature.id = description[6:].rstrip(".") return # this line is a continuation of the description of the previous feature old_description = feature.qualifiers["description"] if old_description.endswith("-"): description = f"{old_description}{description}" else: description = f"{old_description} {description}" if feature.type in ("VARSPLIC", "VAR_SEQ"): # special case # Remove unwanted spaces in sequences. # During line carryover, the sequences in VARSPLIC/VAR_SEQ can get # mangled with unwanted spaces like: # 'DISSTKLQALPSHGLESIQT -> PCRATGWSPFRRSSPC LPTH' # We want to check for this case and correct it as it happens. try: first_seq, second_seq = description.split(" -> ") except ValueError: pass else: extra_info = "" # we might have more information at the end of the # second sequence, which should be in parenthesis extra_info_pos = second_seq.find(" (") if extra_info_pos != -1: extra_info = second_seq[extra_info_pos:] second_seq = second_seq[:extra_info_pos] # now clean spaces out of the first and second string first_seq = first_seq.replace(" ", "") second_seq = second_seq.replace(" ", "") # reassemble the description description = first_seq + " -> " + second_seq + extra_info feature.qualifiers["description"] = description else: # new-style FT line value = line[21:].rstrip() match = re.match(r"^/([a-z_]+)=", value) if match: qualifier_type = match.group(1) value = value[len(match.group(0)) :] if not value.startswith('"'): raise ValueError("Missing starting quote in feature") if qualifier_type == "id": if not value.endswith('"'): raise ValueError("Missing closing quote for id") feature.id = value[1:-1] else: if value.endswith('"'): value = value[1:-1] else: # continues on the next line value = value[1:] if qualifier_type in feature.qualifiers: raise ValueError( f"Feature qualifier {qualifier_type!r} already exists for feature" ) feature.qualifiers[qualifier_type] = value return # this line is a continuation of the description of the previous feature keys = list(feature.qualifiers.keys()) key = keys[-1] description = value.rstrip('"') old_description = feature.qualifiers[key] if key == "evidence" or old_description.endswith("-"): description = f"{old_description}{description}" else: description = f"{old_description} {description}" if feature.type == "VAR_SEQ": # see VARSPLIC above try: first_seq, second_seq = description.split(" -> ") except ValueError: pass else: extra_info = "" # we might have more information at the end of the # second sequence, which should be in parenthesis extra_info_pos = second_seq.find(" (") if extra_info_pos != -1: extra_info = second_seq[extra_info_pos:] second_seq = second_seq[:extra_info_pos] # now clean spaces out of the first and second string first_seq = first_seq.replace(" ", "") second_seq = second_seq.replace(" ", "") # reassemble the description description = first_seq + " -> " + second_seq + extra_info feature.qualifiers[key] = description if __name__ == "__main__": from Bio._utils import run_doctest run_doctest(verbose=0)