mqmscan: Genome scan with a multiple QTL model (MQM)

In qtl: Tools for Analyzing QTL Experiments

Genome scan with a multiple QTL model (MQM)

Description

Genome scan with a multiple QTL model.

Usage

mqmscan(cross, cofactors=NULL, pheno.col = 1,
  model=c("additive","dominance"), forceML=FALSE,
  cofactor.significance=0.02, em.iter=1000,
  window.size=25.0, step.size=5.0,
  logtransform = FALSE, estimate.map = FALSE,
  plot=FALSE, verbose=FALSE, outputmarkers=TRUE,
  multicore=TRUE, batchsize=10, n.clusters=1, test.normality=FALSE,off.end=0
  )

Arguments

cross	An object of class cross. See read.cross for details.
cofactors	List of cofactors to be analysed as cofactors in backward elimination procedure when building the QTL model. See mqmsetcofactors on how-to manually set cofactors for backward elimination. Or use mqmautocofactors for automatic selection of cofactors. Only three kind of (integer) values are allowed in the cofactor list. (0: no cofactor at this marker, 1: Use this marker as an additive cofactor, 2: Use this marker as an sexfactor (Dominant cofactor))
pheno.col	Column number in the phenotype matrix which should be used as the phenotype. This can be a vector of integers; One may also give a character strings matching the phenotype names. Finally, one may give a numeric vector of phenotypeIDs. This should consist of integers with 0 < value < no. phenotypes.
model	When scanning for QTLs should haplotype dominance be considered in an F2 intercross. Using the dominance model we scan for additive effects but also allow an additional effect where AA+AB versus BB and AA versus AB+BB. This setting is ignored for BC and RIL populations
forceML	Specify which statistical method to use to estimate variance components to use when QTL modeling and mapping. Default usage is the Restricted maximum likelihood approach (REML). With this option a user can disable REML and use maximum likelihood.
cofactor.significance	Significance level at which a cofactor is considered significant. This is estimated using an analysis of deviance, and compared to the level specified by the user. The cofactors that dont reach this level of statistical significance are NOT used in the mapping stage. Value between 0 and 1
em.iter	Maximum number of iterations for the EM algorithm to converge
window.size	Window size for mapping QTL locations, this parameter is used in the interval mapping stage. When calculating LOD scores at a genomic position all cofactors within window.size are dropped to estimate the (unbiased) effect of the location under interest.
step.size	Step size used in interval mapping. A lower step.size parameter increases the number of output points, this creates a smoother QTL profile
off.end	Distance (in cM) past the terminal markers on each chromosome to which the genotype simulations will be carried.
logtransform	Indicate if the algorithm should do a log transformation on the trait data in the pheno.col
estimate.map	Should Re-estimation of the marker locations on the genetic map occur before mapping QTLs. This method is deprecated rather use the est.map function in R/qtl. This is because no map is returned into the crossobject. The old map remains in the cross object.
plot	plot the results (default FALSE)
verbose	verbose output
outputmarkers	If TRUE (the default), the results include the marker locations as well as along a grid of pseudomarkers; if FALSE, the results include only the grid positions.
multicore	Use multicore (if available)
batchsize	Number of traits being analyzed as a batch.
n.clusters	Number of child processes to split the job into.
test.normality	If TRUE, test whether the phenotype follows a normal distribution via mqmtestnormal.

Value

When scanning a single phenotype the function returns a scanone object.

The object contains a matrix of three columns for LOD scores, information content and LOD*information content with pseudo markers sorted in increasing order. For more information on the scanone object see: scanone

Note

The resulting scanone object itself can be visualized using the standard R/qtl plotting routines (plot.scanone) or specialized function to show the mqm model (mqmplot.singletrait) and QTL profile. If cofactors were specified the QTL model used in scanning is also returned as a named attribute of the scanone object called mqmmodel. It can be extracted from the resulting scanone object by using the mqmgetmodel function or the attr function.

Also note the estimate.map parameter does not return its re-estimated genetic map, altough it is used internally. When scanning multiple genotypes a mqmmulti object is created. This object is just a list composed of scanone objects. The results for a single trait can be obtained from the mqmmulti object, in scanone format.

Author(s)

Ritsert C Jansen; Danny Arends; Pjotr Prins; Karl W Broman broman@wisc.edu

See Also

• The MQM tutorial: https://rqtl.org/tutorials/MQM-tour.pdf

• MQM - MQM description and references

• mqmscan - Main MQM single trait analysis

• mqmscanall - Parallellized traits analysis

• mqmaugment - Augmentation routine for estimating missing data

• mqmautocofactors - Set cofactors using marker density

• mqmsetcofactors - Set cofactors at fixed locations

• mqmpermutation - Estimate significance levels

• scanone - Single QTL scanning

Examples

data(map10)                    # Genetic map modeled after mouse

# simulate a cross (autosomes 1-10)
qtl <- c(3,15,1,0)             # QTL model: chr, pos'n, add've & dom effects
cross <- sim.cross(map10[1:10],qtl,n=100,missing.prob=0.01)

# MQM
crossaug <- mqmaugment(cross)  # Augmentation
cat(crossaug$mqm$Nind,'real individuals retained in dataset',
    crossaug$mqm$Naug,'individuals augmented\n')

result <- mqmscan(crossaug)    # Scan

# show LOD interval of the QTL on chr 3
lodint(result,chr=3)

qtl documentation built on Sept. 11, 2024, 5:43 p.m.