TFBS::Matrix::PFM(3pm)

NAME

TFBS::Matrix::PFM - class for raw position frequency matrix patterns

SYNOPSIS

o   creating a TFBS::Matrix::PFM object manually:

        my $matrixref = [ [ 12,  3,  0,  0,  4,  0 ],
                          [  0,  0,  0, 11,  7,  0 ],
                          [  0,  9, 12,  0,  0,  0 ],
                          [  0,  0,  0,  1,  1, 12 ]
                        ];
        my $pfm = TFBS::Matrix::PFM->new(-matrix => $matrixref,
                                         -name   => "MyProfile",
                                         -ID     => "M0001"
                                        );
        # or

        my $matrixstring =
            "12 3 0 0 4 0\n0 0 0 11 7 0\n0 9 12 0 0 0\n0 0 0 1 1 12";

        my $pfm = TFBS::Matrix::PFM->new(-matrixstring => $matrixstring,
                                         -name         => "MyProfile",
                                         -ID           => "M0001"
                                        );

o   retrieving a TFBS::Matix::PFM object from a database:

    (See documentation of individual TFBS::DB::* modules to learn how
    to connect to different types of pattern databases and retrieve
    TFBS::Matrix::* objects from them.)

        my $db_obj = TFBS::DB::JASPAR2->new
                        (-connect => ["dbi:mysql:JASPAR2:myhost",
                                      "myusername", "mypassword"]);
        my $pfm = $db_obj->get_Matrix_by_ID("M0001", "PFM");
        # or
        my $pfm = $db_obj->get_Matrix_by_name("MyProfile", "PFM");

o   retrieving list of individual TFBS::Matrix::PFM objects from a
    TFBS::MatrixSet object

    (See the TFBS::MatrixSet to learn how to create objects for storage
    and manipulation of multiple matrices.)

        my @pfm_list = $matrixset->all_patterns(-sort_by=>"name");

o   convert a raw frequency matrix to other matrix types:

        my $pwm = $pfm->to_PWM(); # convert to position weight matrix
        my $icm = $icm->to_ICM(); # convert to information con

DESCRIPTION

TFBS::Matrix::PFM is a class whose instances are objects representing
raw position frequency matrices (PFMs). A PFM is derived from N
nucleotide patterns of fixed size, e.g. the set of sequences

AGGCCT
AAGCCT
AGGCAT
AAGCCT
AAGCCT
AGGCAT
AGGCCT
AGGCAT
AGGTTT
AGGCAT
AGGCCT
AGGCCT

will give the matrix:

A:[ 12 3 0 0 4 0 ]
C:[ 0 0 0 11 7 0 ]
G:[ 0 9 12 0 0 0 ]
T:[ 0 0 0 1 1 12 ]

which contains the count of each nucleotide at each position in the
sequence. (If you have a set of sequences as above and want to create a TFBS::Matrix::PFM object out of them, have a look at
TFBS::PatternGen::SimplePFM module.)

PFMs are easily converted to other types of matrices, namely
information content matrices and position weight matrices. A
TFBS::Matrix::PFM object has the methods to_ICM and to_PWM which do
just that, returning a TFBS::Matrix::ICM and TFBS::Matrix::PWM objects, respectively.

FEEDBACK

Please send bug reports and other comments to the author.

AUTHOR - Boris Lenhard

Boris Lenhard <Boris.Lenhard@cgb.ki.se>

APPENDIX

The rest of the documentation details each of the object methods.
Internal methods are preceded with an underscore.

new

Title : new
Usage : my $pfm = TFBS::Matrix::PFM->new(%args)
Function: constructor for the TFBS::Matrix::PFM object
Returns : a new TFBS::Matrix::PFM object
Args : # you must specify either one of the following three:

-matrix, # reference to an array of arrays of integers

#or

-matrixstring,# a string containing four lines

# of tab- or space-delimited integers

#or

-matrixfile, # the name of a file containing four lines

# of tab- or space-delimited integers

#######

-name, # string, OPTIONAL
-ID, # string, OPTIONAL
-class, # string, OPTIONAL
-tags # an array reference, OPTIONAL

Warnings : Warns if the matrix provided has columns with different

sums. Columns with different sums contradict the usual
origin of matrix data and, unless you are absolutely sure
that column sums _should_ be different, it would be wise to check your matrices.

column_sum

Title : column_sum
Usage : my $nr_sequences = $pfm->column_sum()
Function: calculates the sum of elements of one column

(the first one by default) which normally equals the
number of sequences used to derive the PFM.

Returns : the sum of elements of one column (an integer)
Args : columnn number (starting from 1), OPTIONAL - you DO NOT

need to specify it unless you are dealing with a matrix

to_PWM

Title : to_PWM
Usage : my $pwm = $pfm->to_PWM()
Function: converts a raw frequency matrix (a TFBS::Matrix::PFM object)

to position weight matrix. At present it assumes uniform
background distribution of nucleotide frequencies.

Returns : a new TFBS::Matrix::PWM object
Args : none; in the future releases, it should be able to accept

a user defined background probability of the four
nucleotides

to_ICM

Title : to_ICM
Usage : my $icm = $pfm->to_ICM()
Function: converts a raw frequency matrix (a TFBS::Matrix::PFM object)

to information content matrix. At present it assumes uniform background distribution of nucleotide frequencies.

Returns : a new TFBS::Matrix::ICM object
Args : -small_sample_correction # undef (default), 'schneider' or 'pseudocounts'

How a PFM is converted to ICM:

For a PFM element PFM[i,k], the probability without pseudocounts is
estimated to be simply

p[i,k] = PFM[i,k] / Z

where - Z equals the column sum of the matrix i.e. the number of motifs used to construct the PFM. - i is the column index (position in the
motif) - k is the row index (a letter in the alphacer, here k is one of (A,C,G,T)

Here is how one normally calculates the pseudocount-corrected
positional probability p'[i,j]:

p'[i,k] = (PFM[i,k] + 0.25*sqrt(Z)) / (Z + sqrt(Z))

0.25 is for the flat distribution of nucleotides, and sqrt(Z) is the
recommended pseudocount weight. In the general case,

p'[i,k] = (PFM[i,k] + q[k]*B) / (Z + B)

where q[k] is the background distribution of the letter (nucleotide) k, and B an arbitrary pseudocount value or expression (for no pseudocounts B=0).

For a given position i, the deviation from random distribution in bits is calculated as (Baldi and Brunak eq. 1.9 (2ed) or 1.8 (1ed)):

- for an arbitrary alphabet of A letters:

D[i] = log2(A) + sum_for_all_k(p[i,k]*log2(p[i,k]))

- special case for nucleotides (A=4)

D[i] = 2 + sum_for_all_k(p[i,k]*log2(p[i,k]))

D[i] equals the information content of the position i in the motif. To calculate the entire ICM, you have to calculate the contrubution of
each nucleotide at a position i to D[i], i.e.

ICM[i,k] = p'[i,k] * D[i]

draw_logo

Title : draw_logo
Usage : my $gd_image = $pfm->draw_logo()
Function: draws a sequence logo; similar to the

method in TFBS::Matrix::ICM, but can automatically calculate error bars for drawing

Returns : a GD image object (see documentation of GD module)
Args : many; PFM-specific options are:

-small_sample_correction # One of

# "Schneider" (uses correction
# described by Schneider et al.
# (Schneider t et al. (1986) J.Biol.Chem. # "pseudocounts" - standard pseudocount # correction, more suitable for # PFMs with large r column sums
# If the parameter is ommited, small # sample correction is not applied

-draw_error_bars # if true, adds error bars to each position

# in the logo. To calculate the error bars, # it uses the -small_sample_connection # argument if explicitly set,
# or "Schneider" by default

For other args, see draw_logo entry in TFBS::Matrix::ICM documentation

add_PFM

Title : add_PFM
Usage : $pfm->add_PFM($another_pfm)
Function: adds the values of $pnother_pfm matrix to $pfm
Returns : reference to the updated $pfm object
Args : a TFBS::Matrix::PFM object

name
ID
class
matrix
length
revcom
rawprint
prettyprint

The above methods are common to all matrix objects. Please consult
TFBS::Matrix to find out how to use them.

perl v5.10.1 2008-01-24 TFBS::Matrix::PFM(3pm)