This function is used to plot the estimated QTL effects along selected chromosomes. For a backcross, there will be only one line, representing the additive effect. For an intercross, there will be two lines, representing the additive and dominance effects.
effectscan(cross, pheno.col=1, chr, get.se=FALSE, draw=TRUE,
gap=25, ylim, mtick=c("line","triangle"),
add.legend=TRUE, alternate.chrid=FALSE, …)An object of class cross.
Column number in the phenotype matrix which to be drawn in the plot. One may also give a character string matching a phenotype name.
Optional vector indicating the chromosomes to be drawn in
the plot. This should be a vector of character strings referring to
chromosomes by name; numeric values are converted to strings. Refer
to chromosomes with a preceding - to have all chromosomes but
those considered. A logical (TRUE/FALSE) vector may also be used.
If TRUE, estimated standard errors are calculated.
If TRUE, draw the figure.
Gap separating chromosomes (in cM).
Y-axis limits (optional).
Tick mark type for markers.
If TRUE, add a legend.
If TRUE and more than one chromosome is plotted, alternate the placement of chromosome axis labels, so that they may be more easily distinguished.
Passed to the function plot when it
is called.
The results are returned silently, as an object of class
"effectscan", which is the same as the form returned by the
function scanone, though with estimated effects
where LOD scores might be. That is, it is a data frame with the first
two columns being chromosome ID and position (in cM), and subsequent
columns being estimated effects, and (if get.se=TRUE) standard
errors.
The results of sim.geno are required for taking
account of missing genotype information.
For a backcross, the additive effect is estimated as the difference between the phenotypic averages for heterozygotes and homozygotes.
For recombinant inbred lines, the additive effect is estimated as half the difference between the phenotypic averages for the two homozygotes.
For an intercross, the additive and dominance effects are estimated from linear regression on \(a\) and \(d\) with \(a\) = -1, 0, 1, for the AA, AB and BB genotypes, respectively, and \(d\) = 0, 1, 0, for the AA, AB and BB genotypes, respectively.
As usual, the X chromosome is a bit more complicated. We estimate separate additive effects for the two sexes, and for the two directions within females.
There is an internal function plot.effectscan that creates
the actual plot by calling plot.scanone. In the case
get.se=TRUE, colored regions indicate \(\pm\) 1 SE.
Sen, . and Churchill, G. A. (2001) A statistical framework for quantitative trait mapping. Genetics 159, 371--387.
# NOT RUN {
data(fake.f2)
# }
# NOT RUN {
fake.f2 <- sim.geno(fake.f2, step=2.5, n.draws=16)
# allelic effect on whole genome
effectscan(fake.f2)
# on chromosome 13, include standard errors
effectscan(fake.f2, chr="13", mtick="triangle", get.se=TRUE)
# }
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