lmFit {limma} | R Documentation |
Fit linear model for each gene given a series of arrays
lmFit(object, design=NULL, ndups=1, spacing=1, block=NULL, correlation, weights=NULL, method="ls", ...)
object |
A matrix-like data object containing log-ratios or log-expression values for a series of arrays, with rows corresponding to genes and columns to samples.
Any type of data object that can be processed by |
design |
the design matrix of the microarray experiment, with rows corresponding to arrays and columns to coefficients to be estimated. Defaults to the unit vector meaning that the arrays are treated as replicates. |
ndups |
positive integer giving the number of times each distinct probe is printed on each array. |
spacing |
positive integer giving the spacing between duplicate occurrences of the same probe, |
block |
vector or factor specifying a blocking variable on the arrays. Has length equal to the number of arrays. Must be |
correlation |
the inter-duplicate or inter-technical replicate correlation |
weights |
non-negative observation weights. Can be a numeric matrix of individual weights, of same size as the object expression matrix, or a numeric vector of array weights with length equal to |
method |
fitting method; |
... |
other optional arguments to be passed to |
This function fits multiple linear models by weighted or generalized least squares.
It accepts data from a experiment involving a series of microarrays with the same set of probes.
A linear model is fitted to the expression data for each probe.
The expression data should be log-ratios for two-color array platforms or log-expression values for one-channel platforms.
(To fit linear models to the individual channels of two-color array data, see lmscFit
.)
The coefficients of the fitted models describe the differences between the RNA sources hybridized to the arrays.
The probe-wise fitted model results are stored in a compact form suitable for further processing by other functions in the limma package.
The function allows for missing values and accepts quantitative weights through the weights
argument.
It also supports two different correlation structures.
If block
is not NULL
then different arrays are assumed to be correlated.
If block
is NULL
and ndups
is greater than one then replicate spots on the same array are assumed to be correlated.
It is not possible at this time to fit models with both a block structure and a duplicate-spot correlation structure simultaneously.
If object
is a matrix then it should contain log-ratios or log-expression data with rows corresponding to probes and columns to arrays.
(A numeric vector is treated the same as a matrix with one column.)
For objects of other classes, a matrix of expression values is taken from the appropriate component or slot of the object.
If object
is of class MAList
or marrayNorm
, then the matrix of log-ratios (M-values) is extracted.
If object
is of class ExpressionSet
, then the expression matrix is extracted.
(This may contain log-expression or log-ratio values, depending on the platform.)
If object
is of class PLMset
then the matrix of chip coefficients chip.coefs
is extracted.
The arguments design
, ndups
, spacing
and weights
will be extracted from the data object
if available and do not normally need to set explicitly in the call.
On the other hand, if any of these are set in the function call then they will over-ride the slots or components in the data object
.
If object
is an PLMset
, then weights are computed as 1/pmax(object@se.chip.coefs, 1e-05)^2
.
If object
is an ExpressionSet
object, then weights are not computed.
If the argument block
is used, then it is assumed that ndups=1
.
The correlation
argument has a default value of 0.75
, but in normal use this default value should not be relied on and the correlation value should be estimated using the function duplicateCorrelation
.
The default value is likely to be too high in particular if used with the block
argument.
The actual linear model computations are done by passing the data to one the lower-level functions lm.series
, gls.series
or mrlm
.
The function mrlm
is used if method="robust"
.
If method="ls"
, then gls.series
is used if a correlation structure has been specified, i.e., if ndups>1
or block
is non-null and correlation
is different from zero.
If method="ls"
and there is no correlation structure, lm.series
is used.
An MArrayLM
object containing the result of the fits.
The rownames of object
are preserved in the fit object and can be retrieved by rownames(fit)
where fit
is output from lmFit
.
The column names of design
are preserved as column names and can be retrieved by colnames(fit)
.
Gordon Smyth
lmFit
uses getEAWP
to extract expression values, gene annotation and so from the data object
.
An overview of linear model functions in limma is given by 06.LinearModels.
# Simulate gene expression data for 100 probes and 6 microarrays # Microarray are in two groups # First two probes are differentially expressed in second group # Std deviations vary between genes with prior df=4 sd <- 0.3*sqrt(4/rchisq(100,df=4)) y <- matrix(rnorm(100*6,sd=sd),100,6) rownames(y) <- paste("Gene",1:100) y[1:2,4:6] <- y[1:2,4:6] + 2 design <- cbind(Grp1=1,Grp2vs1=c(0,0,0,1,1,1)) options(digits=3) # Ordinary fit fit <- lmFit(y,design) fit <- eBayes(fit) topTable(fit,coef=2) dim(fit) colnames(fit) rownames(fit)[1:10] names(fit) # Fold-change thresholding fit2 <- treat(fit,lfc=0.1) topTreat(fit2,coef=2) # Volcano plot volcanoplot(fit,coef=2,highlight=2) # Mean-difference plot plotMD(fit,column=2) # Q-Q plot of moderated t-statistics qqt(fit$t[,2],df=fit$df.residual+fit$df.prior) abline(0,1) # Various ways of writing results to file ## Not run: write.fit(fit,file="exampleresults.txt") ## Not run: write.table(fit,file="exampleresults2.txt") # Fit with correlated arrays # Suppose each pair of arrays is a block block <- c(1,1,2,2,3,3) dupcor <- duplicateCorrelation(y,design,block=block) dupcor$consensus.correlation fit3 <- lmFit(y,design,block=block,correlation=dupcor$consensus) # Fit with duplicate probes # Suppose two side-by-side duplicates of each gene rownames(y) <- paste("Gene",rep(1:50,each=2)) dupcor <- duplicateCorrelation(y,design,ndups=2) dupcor$consensus.correlation fit4 <- lmFit(y,design,ndups=2,correlation=dupcor$consensus) dim(fit4) fit4 <- eBayes(fit4) topTable(fit4,coef=2)