Provided by: libbio-perl-perl_1.6.923-1_all
NAME
Bio::Matrix::PSM::ProtMatrix - SiteMatrixI implementation, holds a position scoring matrix (or position weight matrix) with log-odds scoring information.
SYNOPSIS
use Bio::Matrix::PSM::ProtMatrix; # Create from memory by supplying probability matrix hash both as strings or # arrays where the frequencies Hash entries of the form lN refer to an array # of position-specific log-odds scores for amino acid N. Hash entries of the # form pN represent the position-specific probability of finding amino acid N. my %param = ( 'id' => 'A. thaliana protein atp1', '-e_val' => $score, 'lS' => [ '-2', '3', '-3', '2', '-3', '1', '1', '3' ], 'lF' => [ '-1', '-4', '0', '-5', '0', '-5', '-4', '-4' ], 'lT' => [ '-1', '1', '0', '1', '-2', '-1', '0', '1' ], 'lN' => [ '-3', '-1', '-2', '3', '-5', '5', '-2', '0' ], 'lK' => [ '-2', '0', '-3', '2', '-3', '2', '-3', '-1' ], 'lY' => [ '-2', '-3', '-3', '-4', '-3', '-4', '-4', '-4' ], 'lE' => [ '-3', '4', '-3', '2', '-4', '-2', '-3', '2' ], 'lV' => [ '0', '-2', '1', '-4', '1', '-4', '-1', '-3' ], 'lQ' => [ '-1', '0', '-2', '3', '-4', '1', '-3', '0' ], 'lM' => [ '8', '-3', '8', '-3', '1', '-3', '-3', '-3' ], 'lC' => [ '-2', '-3', '-3', '-4', '-3', '-4', '-3', '-3' ], 'lL' => [ '1', '-3', '1', '-4', '3', '-4', '-2', '-4' ], 'lA' => [ '-2', '1', '-2', '0', '-2', '-2', '2', '2' ], 'lW' => [ '-2', '-4', '-3', '-5', '-4', '-5', '-5', '-5' ], 'lP' => [ '-3', '-2', '-4', '-3', '-1', '-3', '6', '-3' ], 'lH' => [ '-2', '-2', '-3', '-2', '-5', '-2', '-2', '-3' ], 'lD' => [ '-4', '-1', '-3', '1', '-3', '-1', '-3', '4' ], 'lR' => [ '-2', '-1', '-3', '0', '-4', '4', '-4', '-3' ], 'lI' => [ '0', '-3', '0', '-4', '6', '-4', '-2', '-2' ], 'lG' => [ '-4', '-2', '-4', '-2', '-5', '-3', '-1', '-2' ], 'pS' => [ '0', '33', '0', '16', '1', '12', '11', '25' ], 'pF' => [ '0', '0', '2', '0', '3', '0', '0', '0' ], 'pT' => [ '0', '8', '7', '10', '1', '2', '7', '8' ], 'pN' => [ '0', '0', '2', '13', '0', '36', '1', '4' ], 'pK' => [ '0', '5', '0', '13', '1', '15', '0', '2' ], 'pY' => [ '0', '0', '0', '0', '0', '0', '0', '0' ], 'pE' => [ '0', '41', '1', '12', '0', '0', '0', '15' ], 'pV' => [ '0', '3', '9', '0', '2', '0', '3', '1' ], 'pQ' => [ '0', '0', '0', '15', '0', '4', '0', '3' ], 'pM' => [ '100', '0', '66', '0', '2', '0', '0', '0' ], 'pC' => [ '0', '0', '0', '0', '0', '0', '0', '0' ], 'pL' => [ '0', '0', '8', '0', '25', '0', '4', '0' ], 'pA' => [ '0', '10', '1', '9', '2', '0', '22', '16' ], 'pW' => [ '0', '0', '0', '0', '0', '0', '0', '0' ], 'pP' => [ '0', '0', '0', '0', '3', '1', '45', '0' ], 'pH' => [ '0', '0', '0', '0', '0', '0', '1', '0' ], 'pD' => [ '0', '0', '1', '7', '2', '2', '0', '22' ], 'pR' => [ '0', '0', '0', '3', '0', '27', '0', '0' ], 'pI' => [ '0', '0', '3', '0', '59', '1', '2', '3' ], 'pG' => [ '0', '0', '0', '1', '0', '0', '4', '1' ], ); my $matrix = Bio::Matrix::PSM::ProtMatrix( %param ); my $site = Bio::Matrix::PSM::ProtMatrix->new(%param); # Or get it from a file: use Bio::Matrix::PSM::IO; my $psmIO = Bio::Matrix::PSM::IO->new(-file => $file, -format => 'psi-blast'); while (my $psm = $psmIO->next_psm) { #Now we have a Bio::Matrix::PSM::Psm object, # see Bio::Matrix::PSM::PsmI for details #This is a Bio::Matrix::PSM::ProtMatrix object now my $matrix = $psm->matrix; } # Get a simple consensus, where alphabet is: # {A, R, N, D, C, Q, E, G, H, I, L, K, M, F, P, S, T, W, Y, V,} # choosing the highest probability or N if prob is too low my $consensus = $site->consensus; # Retrieving and using regular expressions: my $regexp = $site->regexp; my $count = grep($regexp,$seq); my $count = ($seq=~ s/$regexp/$1/eg); print "Motif $mid is present $count times in this sequence\n";
DESCRIPTION
ProtMatrix is designed to provide some basic methods when working with position scoring (weight) matrices related to protein sequences. A protein PSM consists of 20 vectors with 20 frequencies (one per amino acid per position). This is the minimum information you should provide to construct a PSM object. The vectors can be provided as strings with frequencies where the frequency is {0..a} and a=1. This is the way MEME compressed representation of a matrix and it is quite useful when working with relational DB. If arrays are provided as an input (references to arrays actually) they can be any number, real or integer (frequency or count). When creating the object the constructor will check for positions that equal 0. If such is found it will increase the count for all positions by one and recalculate the frequency. Potential bug - if you are using frequencies and one of the positions is 0 it will change significantly. However, you should never have frequency that equals 0. Throws an exception if: You mix as an input array and string (for example A matrix is given as array, C - as string). The position vector is (0,0,0,0). One of the probability vectors is shorter than the rest. Summary of the methods I use most frequently (details bellow): iupac - return IUPAC compliant consensus as a string score - Returns the score as a real number IC - information content. Returns a real number id - identifier. Returns a string accession - accession number. Returns a string next_pos - return the sequence probably for each letter, IUPAC symbol, IUPAC probability and simple sequence consenus letter for this position. Rewind at the end. Returns a hash. pos - current position get/set. Returns an integer. regexp - construct a regular expression based on IUPAC consensus. For example AGWV will be [Aa][Gg][AaTt][AaCcGg] width - site width get_string - gets the probability vector for a single base as a string. get_array - gets the probability vector for a single base as an array. get_logs_array - gets the log-odds vector for a single base as an array. New methods, which might be of interest to anyone who wants to store PSM in a relational database without creating an entry for each position is the ability to compress the PSM vector into a string with losing usually less than 1% of the data. this can be done with: my $str=$matrix->get_compressed_freq('A'); or my $str=$matrix->get_compressed_logs('A'); Loading from a database should be done with new, but is not yet implemented. However you can still uncompress such string with: my @arr=Bio::Matrix::PSM::_uncompress_string ($str,1,1); for PSM or my @arr=Bio::Matrix::PSM::_uncompress_string ($str,1000,2); for log odds
FEEDBACK
Mailing Lists User feedback is an integral part of the evolution of this and other Bioperl modules. Send your comments and suggestions preferably to one of the Bioperl mailing lists. Your participation is much appreciated. bioperl-l@bioperl.org - General discussion http://bioperl.org/wiki/Mailing_lists - About the mailing lists Support Please direct usage questions or support issues to the mailing list: bioperl-l@bioperl.org rather than to the module maintainer directly. Many experienced and reponsive experts will be able look at the problem and quickly address it. Please include a thorough description of the problem with code and data examples if at all possible. Reporting Bugs Report bugs to the Bioperl bug tracking system to help us keep track the bugs and their resolution. Bug reports can be submitted via the web: https://redmine.open-bio.org/projects/bioperl/
AUTHOR - James Thompson
Email tex@biosysadmin.com
APPENDIX
new Title : new Usage : my $site = Bio::Matrix::PSM::ProtMatrix->new( %probs, %logs, -IC => $ic, -e_val => $score, -id => $mid -model => \%model ); Function : Creates a new Bio::Matrix::PSM::ProtMatrix object from memory Throws : If inconsistent data for all vectors (all 20 amino acids) is provided, if you mix input types (string vs array) or if a position freq is 0. Example : Returns : Bio::Matrix::PSM::ProtMatrix object Args : Hash references to log-odds scores and probabilities for position-specific scoring info, e-value (optional), information content (optional), id (optional), model for background distribution of proteins (optional). alphabet Title : Returns an array (or array reference if desired) to the alphabet Usage : Function : Returns an array (or array reference) containing all of the allowable characters for this matrix. Throws : Example : Returns : Array or arrary reference. Args : _calculate_consensus Title : _calculate_consensus Usage : Function : Calculates the consensus sequence for this matrix. Throws : Example : Returns : Args : next_pos Title : next_pos Usage : Function : Retrives the next position features: frequencies for all 20 amino acids, log-odds scores for all 20 amino acids at this position, the main (consensus) letter at this position, the probability for the consensus letter to occur at this position and the relative current position as an integer. Throws : Example : Returns : hash (or hash reference) (pA,pR,pN,pD,...,logA,logR,logN,logD,aa,prob,rel) - pN entries represent the probability for amino acid N to be at this position - logN entries represent the log-odds score for having amino acid N at this position - aa is the consensus amino acid - prob is the probability for the consensus amino acid to be at this position - rel is the relative index of the current position (integer) Args : none curpos Title : curpos Usage : Function : Gets/sets the current position. Throws : Example : Returns : Current position (integer). Args : New position (integer). e_val Title : e_val Usage : Function : Gets/sets the e-value Throws : Example : Returns : Args : real number IC Title : IC Usage : Function : Position-specific information content. Throws : Example : Returns : Information content for current position. Args : Information content for current position. accession_number Title : accession_number Usage : Function: accession number, this will be unique id for the ProtMatrix object as well for any other object, inheriting from ProtMatrix. Throws : Example : Returns : New accession number (string) Args : Accession number (string) consensus Title : consensus Usage : Function : Returns the consensus sequence for this PSM. Throws : if supplied with thresold outisde 5..10 range Example : Returns : string Args : (optional) threshold value 5 to 10 (corresponds to 50-100% at each position get_string Title : get_string Usage : Function: Returns given probability vector as a string. Useful if you want to store things in a rel database, where arrays are not first choice Throws : If the argument is outside {A,C,G,T} Example : Returns : string Args : character {A,C,G,T} width Title : width Usage : Function : Returns the length of the site Throws : Example : Returns : number Args : get_array Title : get_array Usage : Function : Returns an array with frequencies for a specified amino acid. Throws : Example : Returns : Array representing frequencies for specified amino acid. Args : Single amino acid (character). get_logs_array Title : get_logs_array Usage : Function : Returns an array with log_odds for a specified base Throws : Example : Returns : Array representing log-odds scores for specified amino acid. Args : Single amino acid (character). id Title : id Usage : Function : Gets/sets the site id Throws : Example : Returns : string Args : string regexp Title : regexp Usage : Function : Returns a case-insensitive regular expression which matches the IUPAC convention. X's in consensus sequence will match anything. Throws : Example : Returns : string Args : Threshold for calculating consensus sequence (number in range 0-100 representing a percentage). Threshold defaults to 20. regexp_array Title : regexp_array Usage : Function : Returns an array of position-specific regular expressions. X's in consensus sequence will match anything. Throws : Example : Returns : Array of position-specific regular expressions. Args : Threshold for calculating consensus sequence (number in range 0-100 representing a percentage). Threshold defaults to 20. Notes : Simply calls regexp method in list context. _compress_array Title : _compress_array Usage : Function : Will compress an array of real signed numbers to a string (ie vector of bytes) -127 to +127 for bi-directional(signed) and 0..255 for unsigned ; Throws : Example : Internal stuff Returns : String Args : array reference, followed by max value and direction (optional, defaults to 1), direction of 1 is unsigned, anything else is signed. _uncompress_string Title : _uncompress_string Usage : Function : Will uncompress a string (vector of bytes) to create an array of real signed numbers (opposite to_compress_array) Throws : Example : Internal stuff Returns : string, followed by max value and direction (optional, defaults to 1), direction of 1 is unsigned, anything else is signed. Args : array get_compressed_freq Title : get_compressed_freq Usage : Function: A method to provide a compressed frequency vector. It uses one byte to code the frequence for one of the probability vectors for one position. Useful for relational database. Improvment of the previous 0..a coding. Throws : Example : my $strA=$self->get_compressed_freq('A'); Returns : String Args : char sequence_match_weight Title : sequence_match_weight Usage : Function : This method will calculate the score of a match, based on the PSM if such is associated with the matrix object. Returns undef if no PSM data is available. Throws : if the length of the sequence is different from the matrix width Example : my $score=$matrix->sequence_match_weight('ACGGATAG'); Returns : Floating point Args : string _to_IUPAC Title : _to_IUPAC Usage : Function: Converts a single position to IUPAC compliant symbol and returns its probability. Currently returns the most likely amino acid/probability combination. Throws : Example : Returns : char, real number representing an amino acid and a probability. Args : real numbers for all 20 amino acids (ordered by alphabet contained in $self->{_alphabet}, minimum probability threshold. _to_cons Title : _to_cons Usage : Function: Converts a single position to simple consensus character and returns its probability. Currently just calls the _to_IUPAC subroutine. Throws : Example : Returns : char, real number Args : real numbers for A,C,G,T (positional) get_all_vectors Title : get_all_vectors Usage : Function : returns all possible sequence vectors to satisfy the PFM under a given threshold Throws : If threshold outside of 0..1 (no sense to do that) Example : my @vectors = $self->get_all_vectors(4); Returns : Array of strings Args : (optional) floating