Genewise Negative Binomial Generalized Linear Models
Fit a negative binomial generalized log-linear model to the read counts for each gene. Conduct genewise statistical tests for a given coefficient or coefficient contrast.
## S3 method for class 'DGEList' glmFit(y, design=NULL, dispersion=NULL, prior.count=0.125, start=NULL, ...) ## S3 method for class 'SummarizedExperiment' glmFit(y, design=NULL, dispersion=NULL, prior.count=0.125, start=NULL, ...) ## Default S3 method: glmFit(y, design=NULL, dispersion=NULL, offset=NULL, lib.size=NULL, weights=NULL, prior.count=0.125, start=NULL, ...) glmLRT(glmfit, coef=ncol(glmfit$design), contrast=NULL)
y |
an object that contains the raw counts for each library (the measure of expression level); alternatively, a matrix of counts, or a |
design |
numeric matrix giving the design matrix for the genewise linear models. Must be of full column rank. Defaults to a single column of ones, equivalent to treating the columns as replicate libraries. |
dispersion |
numeric scalar, vector or matrix of negative binomial dispersions. Can be a common value for all genes, a vector of dispersion values with one for each gene, or a matrix of dispersion values with one for each observation. If |
offset |
numeric matrix of same size as |
weights |
optional numeric matrix giving prior weights for the observations (for each library and gene) to be used in the GLM calculations. |
lib.size |
numeric vector of length |
prior.count |
average prior count to be added to observation to shrink the estimated log-fold-changes towards zero. |
start |
optional numeric matrix of initial estimates for the linear model coefficients. |
... |
other arguments are passed to lower level fitting functions. |
glmfit |
a |
coef |
integer or character vector indicating which coefficients of the linear model are to be tested equal to zero. Values must be columns or column names of |
contrast |
numeric vector or matrix specifying one or more contrasts of the linear model coefficients to be tested equal to zero. Number of rows must equal to the number of columns of |
glmFit
and glmLRT
implement generalized linear model (glm) methods developed by McCarthy et al (2012).
glmFit
fits genewise negative binomial glms, all with the same design matrix but possibly different dispersions, offsets and weights.
When the design matrix defines a one-way layout, or can be re-parametrized to a one-way layout, the glms are fitting very quickly using mglmOneGroup
.
Otherwise the default fitting method, implemented in mglmLevenberg
, uses a Fisher scoring algorithm with Levenberg-style damping.
Positive prior.count
cause the returned coefficients to be shrunk in such a way that fold-changes between the treatment conditions are decreased.
In particular, infinite fold-changes are avoided.
Larger values cause more shrinkage.
The returned coefficients are affected but not the likelihood ratio tests or p-values.
glmLRT
conducts likelihood ratio tests for one or more coefficients in the linear model.
If coef
is used, the null hypothesis is that all the coefficients indicated by coef
are equal to zero.
If contrast
is non-null, then the null hypothesis is that the specified contrasts of the coefficients are equal to zero.
For example, a contrast of c(0,1,-1)
, assuming there are three coefficients, would test the hypothesis that the second and third coefficients are equal.
glmFit
produces an object of class DGEGLM
containing components counts
, samples
, genes
and abundance
from y
plus the following new components:
design |
design matrix as input. |
weights |
matrix of weights as input. |
df.residual |
numeric vector of residual degrees of freedom, one for each gene. |
offset |
numeric matrix of linear model offsets. |
dispersion |
vector of dispersions used for the fit. |
coefficients |
numeric matrix of estimated coefficients from the glm fits, on the natural log scale, of size |
unshrunk.coefficients |
numeric matrix of estimated coefficients from the glm fits when no log-fold-changes shrinkage is applied, on the natural log scale, of size |
fitted.values |
matrix of fitted values from glm fits, same number of rows and columns as |
deviance |
numeric vector of deviances, one for each gene. |
glmLRT
produces objects of class DGELRT
with the same components as for glmFit
plus the following:
table |
data frame with the same rows as |
comparison |
character string describing the coefficient or the contrast being tested. |
The data frame table
contains the following columns:
logFC |
log2-fold change of expression between conditions being tested. |
logCPM |
average log2-counts per million, the average taken over all libraries in |
LR |
likelihood ratio statistics. |
PValue |
p-values. |
Davis McCarthy and Gordon Smyth
McCarthy, DJ, Chen, Y, Smyth, GK (2012). Differential expression analysis of multifactor RNA-Seq experiments with respect to biological variation. Nucleic Acids Research 40, 4288-4297. https://doi.org/10.1093/nar/gks042
Low-level computations are done by mglmOneGroup
or mglmLevenberg
.
topTags
displays results from glmLRT
.
nlibs <- 3 ngenes <- 100 dispersion.true <- 0.1 # Make first gene respond to covariate x x <- 0:2 design <- model.matrix(~x) beta.true <- cbind(Beta1=2,Beta2=c(2,rep(0,ngenes-1))) mu.true <- 2^(beta.true %*% t(design)) # Generate count data y <- rnbinom(ngenes*nlibs,mu=mu.true,size=1/dispersion.true) y <- matrix(y,ngenes,nlibs) colnames(y) <- c("x0","x1","x2") rownames(y) <- paste("gene",1:ngenes,sep=".") d <- DGEList(y) # Normalize d <- calcNormFactors(d) # Fit the NB GLMs fit <- glmFit(d, design, dispersion=dispersion.true) # Likelihood ratio tests for trend results <- glmLRT(fit, coef=2) topTags(results) # Estimate the dispersion (may be unreliable with so few genes) d <- estimateGLMCommonDisp(d, design, verbose=TRUE)
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