OpenMS  2.8.0
Public Types | Public Member Functions | Static Public Attributes | Protected Member Functions | Protected Attributes | List of all members
PeptideIndexing Class Reference

Refreshes the protein references for all peptide hits in a vector of PeptideIdentifications and adds target/decoy information. More...

#include <OpenMS/ANALYSIS/ID/PeptideIndexing.h>

Inheritance diagram for PeptideIndexing:
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Collaboration diagram for PeptideIndexing:
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Public Types

enum  ExitCodes {
  EXECUTION_OK , DATABASE_EMPTY , PEPTIDE_IDS_EMPTY , ILLEGAL_PARAMETERS ,
  UNEXPECTED_RESULT
}
 Exit codes. More...
 
enum class  Unmatched { IS_ERROR , WARN , REMOVE , SIZE_OF_UNMATCHED }
 Action to take when peptide hits could not be matched. More...
 
enum class  MissingDecoy { IS_ERROR , WARN , SILENT , SIZE_OF_MISSING_DECOY }
 
- Public Types inherited from ProgressLogger
enum  LogType { CMD , GUI , NONE }
 Possible log types. More...
 

Public Member Functions

 PeptideIndexing ()
 Default constructor. More...
 
 ~PeptideIndexing () override
 Default destructor. More...
 
ExitCodes run (std::vector< FASTAFile::FASTAEntry > &proteins, std::vector< ProteinIdentification > &prot_ids, std::vector< PeptideIdentification > &pep_ids)
 forward for old interface and pyOpenMS; use other run() methods for more control More...
 
ExitCodes run (FASTAContainer< TFI_File > &proteins, std::vector< ProteinIdentification > &prot_ids, std::vector< PeptideIdentification > &pep_ids)
 Re-index peptide identifications honoring enzyme cutting rules, ambiguous amino acids and target/decoy hits. More...
 
ExitCodes run (FASTAContainer< TFI_Vector > &proteins, std::vector< ProteinIdentification > &prot_ids, std::vector< PeptideIdentification > &pep_ids)
 Same as run() with TFI_File, but for proteins which are already in memory. More...
 
const StringgetDecoyString () const
 Which string is used to determine if a protein is a decoy or not. More...
 
bool isPrefix () const
 Is the decoy string position a prefix or suffix? More...
 
- Public Member Functions inherited from DefaultParamHandler
 DefaultParamHandler (const String &name)
 Constructor with name that is displayed in error messages. More...
 
 DefaultParamHandler (const DefaultParamHandler &rhs)
 Copy constructor. More...
 
virtual ~DefaultParamHandler ()
 Destructor. More...
 
virtual DefaultParamHandleroperator= (const DefaultParamHandler &rhs)
 Assignment operator. More...
 
virtual bool operator== (const DefaultParamHandler &rhs) const
 Equality operator. More...
 
void setParameters (const Param &param)
 Sets the parameters. More...
 
const ParamgetParameters () const
 Non-mutable access to the parameters. More...
 
const ParamgetDefaults () const
 Non-mutable access to the default parameters. More...
 
const StringgetName () const
 Non-mutable access to the name. More...
 
void setName (const String &name)
 Mutable access to the name. More...
 
const std::vector< String > & getSubsections () const
 Non-mutable access to the registered subsections. More...
 
- Public Member Functions inherited from ProgressLogger
 ProgressLogger ()
 Constructor. More...
 
virtual ~ProgressLogger ()
 Destructor. More...
 
 ProgressLogger (const ProgressLogger &other)
 Copy constructor. More...
 
ProgressLoggeroperator= (const ProgressLogger &other)
 Assignment Operator. More...
 
void setLogType (LogType type) const
 Sets the progress log that should be used. The default type is NONE! More...
 
LogType getLogType () const
 Returns the type of progress log being used. More...
 
void startProgress (SignedSize begin, SignedSize end, const String &label) const
 Initializes the progress display. More...
 
void setProgress (SignedSize value) const
 Sets the current progress. More...
 
void endProgress () const
 Ends the progress display. More...
 
void nextProgress () const
 increment progress by 1 (according to range begin-end) More...
 

Static Public Attributes

static char const *const AUTO_MODE
 name of enzyme/specificity which signals that the enzyme/specificity should be taken from meta information More...
 
static const std::array< std::string,(Size) Unmatched::SIZE_OF_UNMATCHEDnames_of_unmatched
 
static const std::array< std::string,(Size) MissingDecoy::SIZE_OF_MISSING_DECOYnames_of_missing_decoy
 

Protected Member Functions

void updateMembers_ () override
 This method is used to update extra member variables at the end of the setParameters() method. More...
 
template<typename T >
ExitCodes run_ (FASTAContainer< T > &proteins, std::vector< ProteinIdentification > &prot_ids, std::vector< PeptideIdentification > &pep_ids)
 
- Protected Member Functions inherited from DefaultParamHandler
void defaultsToParam_ ()
 Updates the parameters after the defaults have been set in the constructor. More...
 

Protected Attributes

String decoy_string_ {}
 
bool prefix_ { false }
 
MissingDecoy missing_decoy_action_ = MissingDecoy::IS_ERROR
 
String enzyme_name_ {}
 
String enzyme_specificity_ {}
 
bool write_protein_sequence_ { false }
 
bool write_protein_description_ { false }
 
bool keep_unreferenced_proteins_ { false }
 
Unmatched unmatched_action_ = Unmatched::IS_ERROR
 
bool IL_equivalent_ { false }
 
Int aaa_max_ {0}
 
Int mm_max_ {0}
 
- Protected Attributes inherited from DefaultParamHandler
Param param_
 Container for current parameters. More...
 
Param defaults_
 Container for default parameters. This member should be filled in the constructor of derived classes! More...
 
std::vector< Stringsubsections_
 Container for registered subsections. This member should be filled in the constructor of derived classes! More...
 
String error_name_
 Name that is displayed in error messages during the parameter checking. More...
 
bool check_defaults_
 If this member is set to false no checking if parameters in done;. More...
 
bool warn_empty_defaults_
 If this member is set to false no warning is emitted when defaults are empty;. More...
 
- Protected Attributes inherited from ProgressLogger
LogType type_
 
time_t last_invoke_
 
ProgressLoggerImplcurrent_logger_
 

Additional Inherited Members

- Static Public Member Functions inherited from DefaultParamHandler
static void writeParametersToMetaValues (const Param &write_this, MetaInfoInterface &write_here, const String &key_prefix="")
 Writes all parameters to meta values. More...
 
- Static Protected Member Functions inherited from ProgressLogger
static String logTypeToFactoryName_ (LogType type)
 Return the name of the factory product used for this log type. More...
 
- Static Protected Attributes inherited from ProgressLogger
static int recursion_depth_
 

Detailed Description

Refreshes the protein references for all peptide hits in a vector of PeptideIdentifications and adds target/decoy information.

All peptide and protein hits are annotated with target/decoy information, using the meta value "target_decoy". For proteins the possible values are "target" and "decoy", depending on whether the protein accession contains the decoy pattern (parameter decoy_string) as a suffix or prefix, respectively (see parameter prefix). For peptides, the possible values are "target", "decoy" and "target+decoy", depending on whether the peptide sequence is found only in target proteins, only in decoy proteins, or in both. The target/decoy information is crucial for the FalseDiscoveryRate tool. (For FDR calculations, "target+decoy" peptide hits count as target hits.)

Note
Make sure that your protein names in the database contain a correctly formatted decoy string. This can be ensured by using DecoyDatabase. If the decoy identifier is not recognized successfully, all proteins will be assumed to stem from the target-part of the query.
E.g., "sw|P33354_DECOY|YEHR_ECOLI Uncharacterized lipop..." is invalid, since the tool has no knowledge of how SwissProt entries are build up. A correct identifier could be "DECOY_sw|P33354|YEHR_ECOLI Uncharacterized li ..." or "sw|P33354|YEHR_ECOLI_DECOY Uncharacterized li", depending on whether you are using prefix or suffix annotation.

Some helpful target/decoy statistics will be reported when done.

By default this tool will fail if an unmatched peptide occurs, i.e. if the database does not contain the corresponding protein. You can force it to return successfully in this case by setting '-unmatched_action' to accept or even remove those hits.

Search engines (such as X!Tandem) will replace ambiguous amino acids ('B', 'J', 'Z' and 'X') in the protein database with unambiguous amino acids in the reported peptides, e.g. exchange 'X' with 'H'. This will cause such peptides to not be found by exactly matching their sequences to the protein database. However, we can recover these cases by using tolerant search for ambiguous amino acids in the protein sequence. This is done by default with up to three amino acids per peptide hit. If you only want exact matches, set aaa_max to zero (but expect that unmatched peptides might occur)!

Leucine/Isoleucine: Further complications can arise due to the presence of the isobaric amino acids isoleucine ('I') and leucine ('L') in protein sequences. Since the two have the exact same chemical composition and mass, they generally cannot be distinguished by mass spectrometry. If a peptide containing 'I' was reported as a match for a spectrum, a peptide containing 'L' instead would be an equally good match (and vice versa). To account for this inherent ambiguity, setting the flag IL_equivalent causes 'I' and 'L' to be considered as indistinguishable.
For example, if the sequence "PEPTIDE" (matching "Protein1") was identified as a search hit, but the database additionally contained "PEPTLDE" (matching "Protein2"), running PeptideIndexer with the IL_equivalent option would report both "Protein1" and "Protein2" as accessions for "PEPTIDE". (This is independent of ambiguous matching via aaa_max.) Additionally, setting this flag will convert all 'J's in any protein sequence to 'I'. This way, no tolerant search is required for 'J' (but is still possible for all the other ambiguous amino acids). If write_protein_sequences is requested and IL_equivalent is set as well, both the I/L-version and unmodified protein sequences need to be stored internally. This requires some extra memory, roughly equivalent to the size of the FASTA database file itself.

Enzyme specificity: Once a peptide sequence is found in a protein sequence, this does not imply that the hit is valid! This is where enzyme specificity comes into play. By default, the enzyme and the specificity used during search is derived from metadata in the idXML files ('auto' setting).

We make two exceptions to any specificity constraints: 1) for peptides starting at the second or third position of a protein are still considered N-terminally specific, since the residues can be cleaved off in vivo; X!Tandem reports these peptides. For example, the two peptides ABAR and LABAR would both match a protein starting with MLABAR. 2) adventitious cleavage at Asp|Pro (Aspartate/D | Proline/P) is allowed for all enzymes (as supported by X!Tandem), i.e. counts as a proper cleavage site (see http://www.thegpm.org/tandem/release.html).

You can relax the requirements further by choosing semi-tryptic (only one of two "internal" termini must match requirements) or none (essentially allowing all hits, no matter their context). These settings should not be used (due to high risk of reporting false positives), unless the search engine was instructed to search peptides in the same way (but then the default 'auto' setting will do the correct thing).

X!Tandem treats any occurrence of 'X' as stop codon (and thus as cleavage site). The resulting peptide will be non- or semi-tryptic. Those hits will not be matched and need to be removed using '-unmatched_action' (do not use termini specificity to cheat around it! It adds more false hits!).

The FASTA file should not contain duplicate protein accessions (since accessions are not validated) if a correct unique-matching annotation is important (target/decoy annotation is still correct).

Threading: This tool support multiple threads (threads option) to speed up computation, at the cost of little extra memory.

Member Enumeration Documentation

◆ ExitCodes

enum ExitCodes

Exit codes.

Enumerator
EXECUTION_OK 
DATABASE_EMPTY 
PEPTIDE_IDS_EMPTY 
ILLEGAL_PARAMETERS 
UNEXPECTED_RESULT 

◆ MissingDecoy

enum MissingDecoy
strong
Enumerator
IS_ERROR 
WARN 
SILENT 
SIZE_OF_MISSING_DECOY 

◆ Unmatched

enum Unmatched
strong

Action to take when peptide hits could not be matched.

Enumerator
IS_ERROR 

throws an error (and returns no results)

WARN 

skips annotation with target/decoy but returns with 'success'

REMOVE 

removes unmatched hits entirely and returns with 'success'

SIZE_OF_UNMATCHED 

Constructor & Destructor Documentation

◆ PeptideIndexing()

Default constructor.

◆ ~PeptideIndexing()

~PeptideIndexing ( )
override

Default destructor.

Member Function Documentation

◆ getDecoyString()

const String& getDecoyString ( ) const

Which string is used to determine if a protein is a decoy or not.

◆ isPrefix()

bool isPrefix ( ) const

Is the decoy string position a prefix or suffix?

◆ run() [1/3]

ExitCodes run ( FASTAContainer< TFI_File > &  proteins,
std::vector< ProteinIdentification > &  prot_ids,
std::vector< PeptideIdentification > &  pep_ids 
)

Re-index peptide identifications honoring enzyme cutting rules, ambiguous amino acids and target/decoy hits.

Template parameter 'T' can be either TFI_File or TFI_Vector. If the data is already available, use TFI_Vector and pass the vector. If the data is still in a FASTA file and its not needed afterwards for additional processing, use TFI_File and pass the filename.

PeptideIndexer refreshes target/decoy information and mapping of peptides to proteins. The target/decoy information is crucial for the FalseDiscoveryRate tool. (For FDR calculations, "target+decoy" peptide hits count as target hits.)

PeptideIndexer allows for ambiguous amino acids (B|J|Z|X) in the protein database, but not in the peptide sequences. For the latter only I/L can be treated as equivalent (see 'IL_equivalent' flag), but 'J' is not allowed.

Enzyme cutting rules and partial specificity can be specified.

Resulting protein hits appear in the order of the FASTA file, except for orphaned proteins, which will appear first with an empty target_decoy metavalue. Duplicate protein accessions & sequences will not raise a warning, but create multiple hits (PeptideIndexer scans over the FASTA file once for efficiency reasons, and thus might not see all accessions & sequences at once).

All peptide and protein hits are annotated with target/decoy information, using the meta value "target_decoy". For proteins the possible values are "target" and "decoy", depending on whether the protein accession contains the decoy pattern (parameter decoy_string) as a suffix or prefix, respectively (see parameter prefix).

Peptide hits are annotated with metavalue 'protein_references', and if matched to at least one protein also with metavalue 'target_decoy'. The possible values for 'target_decoy' are "target", "decoy" and "target+decoy", depending on whether the peptide sequence is found only in target proteins, only in decoy proteins, or in both. The metavalue is not present, if the peptide is unmatched.

Runtime: PeptideIndexer is usually very fast (loading and storing the data takes the most time) and search speed can be further improved (linearly), but using more threads. Avoid allowing too many (>=4) ambiguous amino acids if your database contains long stretches of 'X' (exponential search space).

Parameters
proteinsA list of proteins – either read piecewise from a FASTA file or as existing vector of FASTAEntries.
prot_idsResulting protein identifications associated to pep_ids (will be re-written completely)
pep_idsPeptide identifications which should be search within proteins and then linked to prot_ids
Returns
Exit status codes.

◆ run() [2/3]

ExitCodes run ( FASTAContainer< TFI_Vector > &  proteins,
std::vector< ProteinIdentification > &  prot_ids,
std::vector< PeptideIdentification > &  pep_ids 
)

Same as run() with TFI_File, but for proteins which are already in memory.

◆ run() [3/3]

ExitCodes run ( std::vector< FASTAFile::FASTAEntry > &  proteins,
std::vector< ProteinIdentification > &  prot_ids,
std::vector< PeptideIdentification > &  pep_ids 
)

forward for old interface and pyOpenMS; use other run() methods for more control

◆ run_()

ExitCodes run_ ( FASTAContainer< T > &  proteins,
std::vector< ProteinIdentification > &  prot_ids,
std::vector< PeptideIdentification > &  pep_ids 
)
protected

◆ updateMembers_()

void updateMembers_ ( )
overrideprotectedvirtual

This method is used to update extra member variables at the end of the setParameters() method.

Also call it at the end of the derived classes' copy constructor and assignment operator.

The default implementation is empty.

Reimplemented from DefaultParamHandler.

Member Data Documentation

◆ aaa_max_

Int aaa_max_ {0}
protected

◆ AUTO_MODE

char const* const AUTO_MODE
static

name of enzyme/specificity which signals that the enzyme/specificity should be taken from meta information

◆ decoy_string_

String decoy_string_ {}
protected

◆ enzyme_name_

String enzyme_name_ {}
protected

◆ enzyme_specificity_

String enzyme_specificity_ {}
protected

◆ IL_equivalent_

bool IL_equivalent_ { false }
protected

◆ keep_unreferenced_proteins_

bool keep_unreferenced_proteins_ { false }
protected

◆ missing_decoy_action_

MissingDecoy missing_decoy_action_ = MissingDecoy::IS_ERROR
protected

◆ mm_max_

Int mm_max_ {0}
protected

◆ names_of_missing_decoy

const std::array<std::string, (Size)MissingDecoy::SIZE_OF_MISSING_DECOY> names_of_missing_decoy
static

◆ names_of_unmatched

const std::array<std::string, (Size)Unmatched::SIZE_OF_UNMATCHED> names_of_unmatched
static

◆ prefix_

bool prefix_ { false }
protected

◆ unmatched_action_

Unmatched unmatched_action_ = Unmatched::IS_ERROR
protected

◆ write_protein_description_

bool write_protein_description_ { false }
protected

◆ write_protein_sequence_

bool write_protein_sequence_ { false }
protected