Provided by: libgenome-model-tools-music-perl_0.04-3_all 
NAME
PopulationPathScan - apply PathScan test to populations rather than just single
individuals
SYNOPSIS
use PopulationPathScan;
my $obj = PopulationPathScan->new ($ref_to_list_of_gene_lengths);
$obj->assign ($number_of_compartments);
$obj->preprocess ($background_mutation_rate);
$pval = $obj->population_pval_approx ($ref_to_list_of_hits_per_sample);
$pval = $obj->population_pval_exact ($ref_to_list_of_hits_per_sample);
DESCRIPTION
The "PathScan" package is implemented strictly as a test of a set of genes, e.g. a
pathway, for a single individual. Specifically, knowing the gene lengths in the pathway,
the number of genes that have at least one mutation, and the estimated background mutation
rate, one can test the null hypothesis that these observed mutations are well-explained
simply by the mechanism of random background mutation. However, it will often be the case
that data for a pathway will be available for many individuals, meaning that we now have
many tests of the given (single) hypothesis. (This should not be confused with the
scenario of multiple hypothesis testing.) The set of values contains much more
information than a single value, suggesting that significance must be judged on the basis
of the collective result. For example, while no single p-value by itself may exceed the
chosen statistical threshold, the overall set of probabilities may still give the
impression of significance. Properly combining such numbers is a necessary, but not
entirely trivial task. This package basically serves as a high-level interface to first
perform individual tests using the methods of "PathScan", and then to properly combine the
resulting p-values using the methods of "CombinePvals".
AUTHOR
Michael C. Wendl
mwendl@wustl.edu
Copyright (C) 2009 Washington University
This program is free software; you can redistribute it and/or modify it under the terms of
the GNU General Public License as published by the Free Software Foundation; either
version 2 of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License along with this program;
if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston,
MA 02111-1307, USA.
METHODS
The available methods are listed below.
new
The object constructor takes a mandatory, but otherwise un-ordered reference to a list of
gene lengths comprising the biological group (e.g. a pathway) whose mutation significance
is to be analyzed using the PathScan paradigm.
my $obj = PopulationPathScan->new ([474, 1038, 285, ...]);
The method checks to make sure that all elements are legitimate lengths, i.e. integers
exceeding 3.
assign
This method assigns the manner in which genes will be internally organized for passing to
the PathScan calculation component. The main consideration here is how the list may be
compartmentalized for greater computational efficiency, though at some loss of accuracy,
for the PathScan calculation. If the gene list is long, exact calculation is generally
infeasible. The method takes a single argument representing the number of compartments
(or sub-lists) the lengths will be divided into, e.g. 1 represents a single list, i.e.
exact computation, 2 indicates two lists, 3 three lists, etc.
$obj->assign (3);
The values are then organized internally such that the smallest genes are grouped
together, then the slightly larger ones, and so forth. Generally, 3 or 4 lists give
reasonable balance between accuracy and computation (Wendl et al., in progress).
preprocess
This method pre-processes the population-level calculation, specifically, it sets up and
executes the PathScan module to obtain the CDF associated with the given gene set and
background mutation rate. It takes the latter as an argument.
$obj->preprocess (0.0000027);
Executing this method will take various amounts of CPU time, depending upon the level of
accuracy and the number of genes in the calculation.
The method optionally takes the list of the number of mutated genes in the group for each
sample as a second argument, if this information is known at this point
$obj->preprocess (0.0000027, [4, 5, 7, 3, 0, ...]);
and it is usually better to use this form because the internals will compute only a
truncated CDF that is just sufficient to process this list, rather than computing the full
CDF. Not only is speed improved, but this helps avoid overflow errors for large pathways.
population_pval_exact
This method performs the population-level calculation using exact enumeration. It takes
the list of the number of mutated genes in the group for each sample, e.g. each patient's
whole genome sequence, for example
patient 1: 4 genes in the pathway are mutated
patient 2: 5 genes in the pathway are mutated
patient 3: 7 genes in the pathway are mutated
patient 4: 3 genes in the pathway are mutated
patient 5: 0 genes in the pathway are mutated
: : : : : : : : :
which is invoked as
$pval = $obj->population_pval_exact ([4, 5, 7, 3, 0, ...]);
Most scenarios will not actually be able to make use of this method because enumeration of
all possible cases is rarely computationally feasible. This method will mostly be useful
for examining small test cases.
population_pval_approx
This method performs the population-level calculation using Lancaster's approximate
transform correction. It takes, as a mandatory argument, the list of the number of
mutated genes in the group for each sample, e.g. each patient's whole genome sequence.
$pval = $obj->population_pval_approx ([4, 5, 7, 3, 0, ...]);
You must pass the list of hits, even if you already passed this list earlier to the pre-
processing method. Most cases will use this method because exact combination of
individual probability values is rarely computationally feasible. Note that Lancaster's
method typically gives much better (more accurate) results than Fisher's "standard" chi-
square transform.
• Fisher, R. A. (1958) Statistical Methods for Research Workers, 13-th Ed. Revised,
Hafner Publishing Co., New York.
• Lancaster, H. O. (1949) The Combination of Probabilities Arising from Data in Discrete
Distributions, Biometrika 36(3/4), 370-382.
perl v5.22.1 Genome::Model::Tools::Music::PathScan::PopulationPathScan(3pm)