MakeAffectedTrees: Make affected trees

Description

A function which makes trees based on historical data with affection status based on penetrance data.

Usage

MakeAffectedTrees(n = 1, g = 4, gdown = 2, frequencies.df = NULL, demographics.df = NULL, benign.boolean=FALSE)

Arguments

An integer giving the number of affected trees to simulate.

An integer giving the number of ancestral generations of the proband to simulate.

gdown

An integer giving the number of descendent generations of the proband to simulate.

frequencies.df

A dataframe giving the penetrance of the desired affection. For convenience this can be one of the included penetrance data frames (BRCA1Frequencies.df, BRCA2Frequencies.df, MLH1Frequencies.df), or a user defined penetrance similar to one of those. This defaults to BRCA1Frequencies.df.

demographics.df

A dataframe giving the demographics to use. This defaults to USDemographics.df which gives historic data on US demographics. Alternatively, the user can choose ChinaDemographics.df or input their own dataframe.

benign.boolean

A boolean variable which tells the program to simulate disease status for a benign variant when benign.boolean is TRUE.

Value

Returns a tree with affection status. The result is a dataframe with the following columns if using the defaults. If using other penetrance data, column names will differ slightly. Returns a tree with affection status. The result is a dataframe with the following columns if using the defaults. If using other penetrance data, column names will differ slightly.

Examples

Run this code


  ## Not run: 
# 
#     #summaries of all the data
#     str(BRCA1Frequencies.df)
#     str(BRCA2Frequencies.df)
#     str(MLH1Frequencies.df)
#     str(USDemographics.df)
#     str(ChinaDemographics.df)
# 
#     #Make a tree with no affection status, g=4 generations above, gdown=2 generations below,
#     #seed.age=50, and demographics.df=NULL which defaults to USDemographics.df.
#     tree1=MakeTree()
# 
#     #Make a tree using Chinese demographics instead.
#     tree2=MakeTree(demographics.df=ChinaDemographics.df)
# 
#     #Add affection statust to tree2 using BRCA1Frequencies.df which gives the BRCA1
#     #penetrance function
#     tree1a=AddAffectedToTree(tree.f=tree1,frequencies.df=BRCA1Frequencies.df)
# 
#     #make a tree with affection status (same as running MakeTree() and then AddAffectedToTree())
#     tree3=MakeAffectedTrees(n=1,g=2,gdown=2,frequencies.df=MLH1Frequencies.df)
#     #tree4=MakeAffectedTrees(n=1,g=2,gdown=2,frequencies.df=BRCA2Frequencies.df)
# 
# 
#     #Depending on the size of the pedigree generated, probands (defined here as members of the
#     #pedigree who are carriers of the genotype with the disease) may not always be present in
#     #the pedigree.  To alleviate this problem in this example we manually generate a pedigree.
#     #Note that this is from the Mohammadi paper where the Likelihood method originates from.
#     ped=data.frame(degree=c(3,2,2,3,3,1,1,2,2,3), momid=c(3,NA,7,3,3,NA,NA,7,NA,8),
#       dadid=c(2,NA,6,2,2,NA,NA,6,NA,9), id=1:10, age=c(45,60,50,31,41,68,65,55,62,43),
#       female=c(1,0,1,0,1,0,1,1,0,1), y.born=0, dead=0, geno=2, famid=1, bBRCA1.d=0, oBRCA1.d=0,
#       bBRCA1.aoo=NA, oBRCA1.aoo=NA, proband=0)
#     ped$y.born=2010-ped$age
#     ped$geno[c(1,3)]=1
#     ped$bBRCA1.d[c(1,3)]=1
#     ped$bBRCA1.aoo[1]=45
#     ped$bBRCA1.aoo[3]=50
#     ped$proband[1]=1
# 
#     ped=ped[c(6,7,2,3,8,9,1,4,5,10),]
# 
#     #Calculate the likelihood ratio
#     CalculateLikelihoodRatio(ped=ped, affected.vector={ped$bBRCA1.d|ped$oBRCA1.d}, gene="BRCA1")
# 
#     #Plot the pedigree
#     PlotPedigree(ped, affected.vector={ped$bBRCA1.d|ped$oBRCA1.d})
# 
#     #Rank and plot the members of the pedigree with unknown genotypes
#     RankMembers(ped=ped, affected.vector={ped$bBRCA1.d|ped$oBRCA1.d}, gene="BRCA1")
#   ## End(Not run)

Run the code above in your browser using DataLab

Description

Usage

Arguments

Value

See Also

Examples