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R/spikeIn.R
In arrayQuality: Assessing array quality on spotted arrays
Defines functions
Spike.Individual.Sensitivity
Spike.Cy5vsCy3
Spike.MM.Scatter
Spike.Sensitivity
Spike.MMplot
readAllSpikes
getSpikeIndex
getSpikeIds
readSpikeTypes
Documented in
getSpikeIds
getSpikeIndex
readAllSpikes
readSpikeTypes
Spike.Cy5vsCy3
Spike.Individual.Sensitivity
Spike.MMplot
Spike.MM.Scatter
Spike.Sensitivity
#################################################
## Separate control plot functions for MEEBO set
## Author: Agnes and Yuanyuan
## Date modified: 11/02/2005
## 06/28/2006
## Spike-ins plots -- Using limma functions
#################################################
##source("C:/MyDoc/Projects/madman/Rpacks/arrayQuality/R/SpikeIn.R")
###############################################################
## LOAD REQUIRED PACKAGES and OBJECTS
library(marray)
library(RColorBrewer)
##load("MEEBOset.RData")
###############################################################
## Spike parsing functions
###############################################################
## input: text file describing the spike-ins (names/cy3-cy5/seqID/Type)
## output: list of matrix containing info for each spike type
readSpikeTypes <- function(file="DopingTypeFile2.txt",path=NULL,cy5col="MassCy5",cy3col="MassCy3",...)
{
spikeTypes <- readSpotTypes(file=file,path=path,...)
spikeTypes <- spikeTypes[!is.na(spikeTypes[,cy5col]),]
if(length(grep("Type", as.character(colnames(spikeTypes))))>0)
spikelist <- split(spikeTypes,spikeTypes[,"Type"])
else
stop("Wrong SpikeTypeFile")
return(spikelist)
}
## Examples:
#spikes <- readSpikeTypes() ##List of matrix by different types of spikes
#spikes <- readSpikeTypes(file="StanfordDCV1.7complete.txt",
# cy5col="CY5.ng._MjDC_V1.7",cy3col="CY3.ng._MjDC_V1.7")
## -------------------------------------------------------------------------
## getSpikeIds
## Input: list of matrix, one for for each type of spike
## Output: list of list:
## For each spike-type: look at all individual spikes,
## if on array, find all replicates (using seqID) and return their MEEBO ids
##
## Some spikes are not used- Remove from search
getSpikeIds <- function(spikeList, id="SeqID", annot=MEEBOset, namecol=c("Symbol","Name"))
{
SpikeIds <- c()
if(length(namecol)>2)
namecol=namecol[1]
## find all replicated sequences/probe_Name
for(type in 1:length(spikeList))
{
usedSeq <- spikeList[[type]][!is.na(spikeList[[type]][,id]),id]
TmpIds <- lapply(spikeList[[type]][,id],
function(x){as.character(annot[grep(as.character(x),as.character(annot[,id])),"uniqID"])})
if(nchar(spikeList[[type]][1,namecol])>0)
names(TmpIds) <- spikeList[[type]][,namecol]
else
names(TmpIds) <- spikeList[[type]][,"Probe_Name"]
SpikeIds <- c(SpikeIds,list(TmpIds))
}
names(SpikeIds) <- names(spikeList)
return(SpikeIds)
}
## Example:
##test <- getSpikeIds(spikeList=spikes)
## ---------------------------------------------------------------------------
## getSpikeIndex
## Input: Input: list of matrix, one for for each type of spike
## Output: list of list:
## For each spike-type: look at all individual spikes,
## if on array, find all corresponding Meebo ids
## return index of each replicate in all-array index
getSpikeIndex <- function(spikeList,id="SeqID",annot=MEEBOset,gnames, namecol=c("Symbol","Name"))
{
if(length(namecol)>1)
namecol=namecol[1]
SpikeIds <- getSpikeIds(spikeList=spikeList,id=id,annot=annot, namecol=namecol)
SpikeIndex <- lapply(SpikeIds,function(x){lapply(x,function(y){match(y,gnames)})})
}
## Example:
##test2<- getSpikeIndex(spikes,gnames=maGeneTable(mnorm)[,"ID"])
## ---------------------------------------------------------------------------
## Get all spikes at once, no distinctions
## Input: spike type file
## Output: list of all spike-ins Meebo ids for each spike
readAllSpikes <- function(file="DopingTypeFileTest.txt",path=NULL,cy5col="MassCy5",
cy3col="MassCy3",id="SeqID",annot=MEEBOset,...)
{
## read everything into a matrix
spikesTypes <- readSpotTypes(file=file,path=path,...)
## remove missing data NA or ""
spikesTypes <- spikesTypes[!is.na(spikesTypes[,cy5col]),]
## get all replicates on array using SeqId
TmpIds <- sapply(spikesTypes[,id],
function(x){as.character(annot[grep(as.character(x),as.character(annot[,id])),"uniqID"])})
##
return(TmpIds)
}
## spikeids <- readAllSpikes()
###############################################################
## Individual Spike-type plotting functions
###############################################################
## Spike.MMplot:
## Input: results of readSpikeTypes
## output: expected ratio vs. Observed ratios, log scale
Spike.MMplot <- function(mval,spikeList, id="SeqID", gnames=RG$genes[,"ID"],
annot=MEEBOset,cy5col="MassCy5",cy3col="MassCy3",namecol="Symbol")
{
SpikeIndex <- getSpikeIndex(spikeList,id=id,annot=annot,gnames=gnames,namecol=namecol)
## print(SpikeIndex[[1]])
## print(length(spikeList))
for(type in 1:length(spikeList))
{
## print("here")
expected <- log.na(as.numeric(spikeList[[type]][,cy5col]) / as.numeric(spikeList[[type]][,cy3col]),2)
max <- max(expected,na.rm=TRUE)
min <- min(expected,na.rm=TRUE)
##set the color
##separate MJ and Ambion/Strata
if (length(SpikeIndex[[type]])>16)
{
print("More than 16 spikes")
colvect <- "blue"
##Plot dots
plot((min-1):(max+1),(min-1):(max+1),type="n",xlab="expected ratios", ylab="observed ratios",
main=spikeList[[type]][1,"Type"])
for(i in 1:length(SpikeIndex[[type]]))
{
yy <- mval[SpikeIndex[[type]][[i]]]
points(rep(expected[i],length(yy)),yy,col=colvect, pch=19,cex=1)
}
abline(0,1,lty=2)
##plot legend
plot(rep(1,length(SpikeIndex[[type]])),1:length(SpikeIndex[[type]]),
type="n", xlab="", ylab="", axes=FALSE, xlim=c(1,1))
}
else
{
colvect <- rep(brewer.pal(ceiling(length(SpikeIndex[[type]])/2),"Set1"),2)
##plot
plot((min-1):(max+1),(min-1):(max+1),type="n",xlab="expected ratios", ylab="observed ratios",
main=spikeList[[type]][1,"Type"])
for(i in 1:length(SpikeIndex[[type]]))
{
yy <- mval[SpikeIndex[[type]][[i]]]
points(rep(expected[i],length(yy)),yy,col="black", pch=LETTERS[i],cex=1.5)
if(length(grep("EC",as.character(spikeList[[type]][i,"Probe_Name"])))>0)
points(expected[i], median(yy,na.rm=TRUE), col=colvect[i], pch=19,cex=3)
else
{
points(expected[i], median(yy,na.rm=TRUE), col=colvect[i], pch=17,cex=3)
##print(median(yy,na.rm=TRUE))
}
}
abline(0,1,lty=2)
op <- par(mar=c(5,2,5,10))
plot(rep(1,length(SpikeIndex[[type]])),1:length(SpikeIndex[[type]]),
type="n", xlab="", ylab="", axes=FALSE, xlim=c(1,1))
for(i in 1:length(SpikeIndex[[type]]))
{
points(1, i,col=colvect[i],
pch=ifelse(length(grep("EC",spikeList[[type]][i,"Probe_Name"]))>0,19,17),cex=3)
axis(4,at=1:length(SpikeIndex[[type]]),
paste(LETTERS[1:length(SpikeIndex[[type]])], as.character(names(SpikeIndex[[type]])),sep=":"),
las=2,cex.axis=1.5,tick=FALSE,line=-3)
}
par(op)
}
}
}
## Example
#png("testMMplot_MJs.png",width=1000,height=1000)
#par(mfrow=c(2,2),cex.main=2,cex.lab=1.5,oma=c(4,4,4,4))
#Spike.MMplot(Mval, spikes[1],cy5col="CY5.ng._MjDC_V1.7",cy3col="CY3.ng._MjDC_V1.7")
#Spike.MMplot(Mval, spikes[2],cy5col="CY5.ng._MjDC_V1.7",cy3col="CY3.ng._MjDC_V1.7")
#dev.off()
## --------------------------------------------------------------------------------
## Spike.Sensitivity
## concentration (mass) vs raw signal for each channel
## Input: output from read.SpikeTypes
## Output: boxplot of log raw signal / log concentration
## Bg sub or not depending on input
Spike.Sensitivity <- function(rawobj,spikeList, id="SeqID", gnames=RG$genes[,"ID"], annot=MEEBOset,cy5col="MassCy5",cy3col="MassCy3",namecol=c("Name","Symbol"))
{
if(length(namecol)>2)
namecol <- namecol[1]
SpikeIndex <- getSpikeIndex(spikeList,id=id,annot=annot,gnames=gnames,namecol=namecol)
for(type in 1:length(spikeList))
{
expectedR <- log.na(as.numeric(spikeList[[type]][,cy5col]),2)
expectedG <- log.na(as.numeric(spikeList[[type]][,cy3col]),2)
max <- max(c(expectedR,expectedG),na.rm=TRUE)
min <- min(c(expectedR,expectedG),na.rm=TRUE)
Cy5 <- c()
Cy3 <- c()
massCy5 <- c()
massCy3 <- c()
for(i in 1:length(SpikeIndex[[type]]))
{
##yy <- maLR(rawobj)[SpikeIndex[[type]][[i]]]
yy <- log.na(rawobj$R[SpikeIndex[[type]][[i]]],2)
Cy5 <- c(Cy5,yy)
massCy5 <- c(massCy5,rep(expectedR[i],length(yy)))
yy <- log.na(rawobj$G[SpikeIndex[[type]][[i]]],2)
Cy3 <- c(Cy3,yy)
massCy3 <- c(massCy3,rep(expectedG[i],length(yy)))
}
resCy5<- split(data.frame(cbind(massCy5,Cy5)),factor(massCy5))
resCy3<- split(data.frame(cbind(massCy3,Cy3)),factor(massCy3))
plot((min-1):(max+1),(min-1):(max+1),type="n",xlab="Log2 mass",
ylab="Signal intensity",ylim=c(0,16),xlim=c(0,10),
main=paste(spikeList[[type]][1,"Type"],"Cy5",sep=" "))
for(i in 1:length(resCy5))
{
boxplot(resCy5[[i]][,2], at=resCy5[[i]][1,1],col="red",add=TRUE)
}
plot((min-1):(max+1),(min-1):(max+1),type="n",xlab="Log2 mass",
ylab="Signal intensity",ylim=c(0,16),xlim=c(0,10),
main=paste(spikeList[[type]][1,"Type"],"Cy3",sep=" "))
for(i in 1:length(resCy3))
{
boxplot(resCy3[[i]][,2], at=resCy3[[i]][1,1],col="green",add=TRUE)
}
}
}
## Example
#png("Sensitivity.png", width=800,height=1000)
#par(mfrow=c(2,2))
#Spike.Sensitivity(nbg,spikes)
#dev.off()
## --------------------------------------------------------------------
## Spike.MM.Scatter
# MMplot: scatter plot + expected ratio superimposed
## Input: results from readSpikeTypes
## Output: scatter plot of observed ratio and expected ratio for each spike
Spike.MM.Scatter <- function(mval,spikeList, id="SeqID", gnames=RG$genes[,"ID"], annot=MEEBOset,
cy5col="CY5.ng._MjDC_V1.7",cy3col="CY3.ng._MjDC_V1.7",namecol=NULL)
{
SpikeIndex <- getSpikeIndex(spikeList,id=id,annot=annot,gnames=gnames,namecol=namecol)
yrange <- range(mval[unlist(SpikeIndex)],na.rm=TRUE)
for(type in 1:length(SpikeIndex))
{
expected <- log.na(as.numeric(spikeList[[type]][,cy5col]) / as.numeric(spikeList[[type]][,cy3col]),2)
##set the color
#if (length(SpikeIndex[[type]])>16)
# colvect <- "blue"
#else
# colvect <- rep(brewer.pal(ceiling(length(SpikeIndex[[type]])/2),"Set1"),2)
##plot
yrange <- range(yrange,expected,na.rm=TRUE)
plot(1:length(SpikeIndex[[type]]),1:length(SpikeIndex[[type]]),
type="n",xlab="", ylab="Observed ratios",ylim=yrange,axes=FALSE,
main=spikeList[[type]][1,"Type"])
for(i in 1:length(SpikeIndex[[type]]))
{
yy <- mval[SpikeIndex[[type]][[i]]]
points(rep(i,length(yy)),yy,col="black", pch=18,cex=1.5)
points(i,expected[i],pch=19,cex=2,col="red")
}
abline(h=c(-2,-1,0,1,2),lty=2)
axis(1,at=1:length(SpikeIndex[[type]]),labels=names(SpikeIndex[[type]]),las=2)
axis(2,las=2);box()
}
}
## Example
#png("MM.scatter.png", width=600,height=800)
#par(mar=c(7,4,4,4),mfrow=c(2,1),oma=c(2,2,2,2))
#Spike.MM.Scatter(Mval,spikes)
#dev.off()
##-------------------------------------------------------------------------
## Cy3 vs Cy5 raw signal, linear scale
## Bg sub depends on input
## All spikes
## Input: spikeTypes: results of readSpotTypes
Spike.Cy5vsCy3 <- function(rawobj,spikesTypes, id="SeqID",
annot=MEEBOset,gnames=RG$genes[,"ID"],
cy5col="CY5.ng._MjDC_V1.7",cy3col="CY3.ng._MjDC_V1.7",...)
{
## read everything into a matrix
## spikesTypes <- readSpotTypes(file=file,path=path)
## remove missing data NA or ""
spikesTypes <- spikesTypes[!is.na(spikesTypes[,cy5col]),]
## get all replicates on array using SeqId
TmpIds <- sapply(spikesTypes[,id],
function(x){as.character(annot[grep(as.character(x),as.character(annot[,id])),"uniqID"])})
## Get the colors
## expectedRatio <- spikesTypes[,cy5col]/spikesTypes[,cy3col]
expectedRatio <- as.numeric(spikesTypes[,cy5col])/as.numeric(spikesTypes[,cy3col])
ratioSpiked <- sort(unique(expectedRatio))
colvect <- rainbow(length(ratioSpiked))
indexcol <- match(expectedRatio,ratioSpiked)
## Get the plot
axisrange <- range(log.na(c(rawobj$R,rawobj$G),2),na.rm=TRUE)
axisrange[2] <- axisrange[2]+1.5
plot(1:length(TmpIds),1:length(TmpIds),type="n",xlim=axisrange,
ylim=axisrange,xlab="Log2 Cy5 signal", ylab="Log2 Cy3 signal",
main="Comparison of Cy5 and Cy3 raw signal intensity")
for(i in 1:length(TmpIds))
{
index <- match(TmpIds[[i]],as.character(gnames))
points(log.na(rawobj$R[index,],2),log.na(rawobj$G[index,],2),
##pch=18,col=1)
pch=18,col=colvect[indexcol[i]])
}
legend(axisrange[2]-2.2,axisrange[2]-0.5,"Expected log2 ratios",
bty="n",cex=0.7)
legend(axisrange[2]-1,axisrange[2]-1,pch=18,col=colvect,bty="o",
as.character(log2(ratioSpiked)))
abline(0,1,lty=2)
}
##----------------------------------------------------------------
## Spike.Sensitivity indivudual boxplots
## concentration (mass) vs raw signal for each channel
## Input: output from read.SpikeTypes
## Output: boxplot of log raw signal ordered by input mass
## Bg sub or not depending on input
##Example
#png("testIndiBplot.png",width=1000,height=1000)
#par(mfrow=c(2,2), oma=c(3,3,3,3),mar=c(5,4,5,4))
#Spike.Individual.Sensitivity(RGsub,spikeList,namecol="Symbol")
#dev.off()
Spike.Individual.Sensitivity <- function(rawobj,spikeList=NULL, id="SeqID", gnames=RG$genes[,"ID"], annot=MEEBOset,cy5col="MassCy5",cy3col="MassCy3",namecol=c("Name","Symbol"),ctllist=MEEBOctrl,DEBUG=FALSE)
{
if(DEBUG) print("Starting Spike.Individual.Sensitivity")
if(length(namecol)>1)
namecol <- namecol[1]
# Aval <- (log.na(rawobj$R,2) + log.na(rawobj$G,2))/2
spikeIndex <- getSpikeIndex(spikeList,id=id,annot=annot,gnames=gnames,namecol=namecol)
goodNegCtl <- ctllist[[11]][!is.na(match(ctllist[[11]], rownames(rawobj$R)))]
negCtlCy5 <- log.na(rawobj$R[goodNegCtl,],2)
negCtlCy3 <- log.na(rawobj$G[goodNegCtl,],2)
for(type in 1:length(spikeIndex))
{
orderCy5 <- sort(as.numeric(spikeList[[type]][,cy5col]),index.return=TRUE)$ix
orderCy3 <- sort(as.numeric(spikeList[[type]][,cy3col]),index.return=TRUE)$ix
plot(1:(length(spikeIndex[[type]])+1),1:(length(spikeIndex[[type]])+1),
type="n",ylim=c(0,16),xlab="",axes=FALSE,
ylab="Log2 signal",main=paste(spikeList[[type]][1,"Type"]," : log2(Cy5) by increasing concentration",sep=" "))
boxplot(negCtlCy5,add=TRUE,col="blue",at=1,axes=FALSE,na.rm=TRUE)
for(j in 1:length(orderCy5))
{
boxplot(log.na(rawobj$R[spikeIndex[[type]][[orderCy5[j]]],],2),add=TRUE,col="red",
at=(j+1),axes=FALSE,na.rm=TRUE)
}
axis(1,at=1:(length(orderCy5)+1),labels=c("Neg Ctrl",spikeList[[type]][orderCy5,namecol]),las=2)
axis(2,las=2, at=seq(0,16,2));box()
# axis(4, at=quantile(Aval, c(0.25,0.5,0.75,0.9,1), na.rm=TRUE),
# label=c(0.25,0.5,0.75,0.9,1), las= 2)
# abline(h=quantile(Aval, c(0.25,0.5,0.75,0.9,1), na.rm=TRUE),lwd=2,lty=2)
plot(1:(length(spikeIndex[[type]])+1),1:(length(spikeIndex[[type]])+1),
type="n",ylim=c(0,16),xlab="",axes=FALSE,
ylab="Log2 signal",main=paste(spikeList[[type]][1,"Type"]," : log2(Cy3) by increasing concentration",sep=" "))
boxplot(negCtlCy3,add=TRUE,col="blue",at=1,axes=FALSE)
for(j in 1:length(orderCy3))
{
boxplot(log.na(rawobj$G[spikeIndex[[type]][[orderCy3[j]]],],2),add=TRUE,col="green",
at=(j+1),axes=FALSE)
}
axis(1,at=1:(length(orderCy3)+1),labels=c("Neg Ctrl",spikeList[[type]][orderCy3,namecol]),las=2)
axis(2,las=2,at=seq(0,16,2));box()
}
}
##Spike.Individual.Sensitivity(RGsub,spikeList[1],namecol="Symbol")
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Defines functions Spike.Individual.Sensitivity Spike.Cy5vsCy3 Spike.MM.Scatter Spike.Sensitivity Spike.MMplot readAllSpikes getSpikeIndex getSpikeIds readSpikeTypes
Documented in getSpikeIds getSpikeIndex readAllSpikes readSpikeTypes Spike.Cy5vsCy3 Spike.Individual.Sensitivity Spike.MMplot Spike.MM.Scatter Spike.Sensitivity
#################################################
## Separate control plot functions for MEEBO set
## Author: Agnes and Yuanyuan
## Date modified: 11/02/2005
## 06/28/2006
## Spike-ins plots -- Using limma functions
#################################################
##source("C:/MyDoc/Projects/madman/Rpacks/arrayQuality/R/SpikeIn.R")
###############################################################
## LOAD REQUIRED PACKAGES and OBJECTS
library(marray)
library(RColorBrewer)
##load("MEEBOset.RData")
###############################################################
## Spike parsing functions
###############################################################
## input: text file describing the spike-ins (names/cy3-cy5/seqID/Type)
## output: list of matrix containing info for each spike type
readSpikeTypes <- function(file="DopingTypeFile2.txt",path=NULL,cy5col="MassCy5",cy3col="MassCy3",...)
{
spikeTypes <- readSpotTypes(file=file,path=path,...)
spikeTypes <- spikeTypes[!is.na(spikeTypes[,cy5col]),]
if(length(grep("Type", as.character(colnames(spikeTypes))))>0)
spikelist <- split(spikeTypes,spikeTypes[,"Type"])
else
stop("Wrong SpikeTypeFile")
return(spikelist)
}
## Examples:
#spikes <- readSpikeTypes() ##List of matrix by different types of spikes
#spikes <- readSpikeTypes(file="StanfordDCV1.7complete.txt",
# cy5col="CY5.ng._MjDC_V1.7",cy3col="CY3.ng._MjDC_V1.7")
## -------------------------------------------------------------------------
## getSpikeIds
## Input: list of matrix, one for for each type of spike
## Output: list of list:
## For each spike-type: look at all individual spikes,
## if on array, find all replicates (using seqID) and return their MEEBO ids
##
## Some spikes are not used- Remove from search
getSpikeIds <- function(spikeList, id="SeqID", annot=MEEBOset, namecol=c("Symbol","Name"))
{
SpikeIds <- c()
if(length(namecol)>2)
namecol=namecol[1]
## find all replicated sequences/probe_Name
for(type in 1:length(spikeList))
{
usedSeq <- spikeList[[type]][!is.na(spikeList[[type]][,id]),id]
TmpIds <- lapply(spikeList[[type]][,id],
function(x){as.character(annot[grep(as.character(x),as.character(annot[,id])),"uniqID"])})
if(nchar(spikeList[[type]][1,namecol])>0)
names(TmpIds) <- spikeList[[type]][,namecol]
else
names(TmpIds) <- spikeList[[type]][,"Probe_Name"]
SpikeIds <- c(SpikeIds,list(TmpIds))
}
names(SpikeIds) <- names(spikeList)
return(SpikeIds)
}
## Example:
##test <- getSpikeIds(spikeList=spikes)
## ---------------------------------------------------------------------------
## getSpikeIndex
## Input: Input: list of matrix, one for for each type of spike
## Output: list of list:
## For each spike-type: look at all individual spikes,
## if on array, find all corresponding Meebo ids
## return index of each replicate in all-array index
getSpikeIndex <- function(spikeList,id="SeqID",annot=MEEBOset,gnames, namecol=c("Symbol","Name"))
{
if(length(namecol)>1)
namecol=namecol[1]
SpikeIds <- getSpikeIds(spikeList=spikeList,id=id,annot=annot, namecol=namecol)
SpikeIndex <- lapply(SpikeIds,function(x){lapply(x,function(y){match(y,gnames)})})
}
## Example:
##test2<- getSpikeIndex(spikes,gnames=maGeneTable(mnorm)[,"ID"])
## ---------------------------------------------------------------------------
## Get all spikes at once, no distinctions
## Input: spike type file
## Output: list of all spike-ins Meebo ids for each spike
readAllSpikes <- function(file="DopingTypeFileTest.txt",path=NULL,cy5col="MassCy5",
cy3col="MassCy3",id="SeqID",annot=MEEBOset,...)
{
## read everything into a matrix
spikesTypes <- readSpotTypes(file=file,path=path,...)
## remove missing data NA or ""
spikesTypes <- spikesTypes[!is.na(spikesTypes[,cy5col]),]
## get all replicates on array using SeqId
TmpIds <- sapply(spikesTypes[,id],
function(x){as.character(annot[grep(as.character(x),as.character(annot[,id])),"uniqID"])})
##
return(TmpIds)
}
## spikeids <- readAllSpikes()
###############################################################
## Individual Spike-type plotting functions
###############################################################
## Spike.MMplot:
## Input: results of readSpikeTypes
## output: expected ratio vs. Observed ratios, log scale
Spike.MMplot <- function(mval,spikeList, id="SeqID", gnames=RG$genes[,"ID"],
annot=MEEBOset,cy5col="MassCy5",cy3col="MassCy3",namecol="Symbol")
{
SpikeIndex <- getSpikeIndex(spikeList,id=id,annot=annot,gnames=gnames,namecol=namecol)
## print(SpikeIndex[[1]])
## print(length(spikeList))
for(type in 1:length(spikeList))
{
## print("here")
expected <- log.na(as.numeric(spikeList[[type]][,cy5col]) / as.numeric(spikeList[[type]][,cy3col]),2)
max <- max(expected,na.rm=TRUE)
min <- min(expected,na.rm=TRUE)
##set the color
##separate MJ and Ambion/Strata
if (length(SpikeIndex[[type]])>16)
{
print("More than 16 spikes")
colvect <- "blue"
##Plot dots
plot((min-1):(max+1),(min-1):(max+1),type="n",xlab="expected ratios", ylab="observed ratios",
main=spikeList[[type]][1,"Type"])
for(i in 1:length(SpikeIndex[[type]]))
{
yy <- mval[SpikeIndex[[type]][[i]]]
points(rep(expected[i],length(yy)),yy,col=colvect, pch=19,cex=1)
}
abline(0,1,lty=2)
##plot legend
plot(rep(1,length(SpikeIndex[[type]])),1:length(SpikeIndex[[type]]),
type="n", xlab="", ylab="", axes=FALSE, xlim=c(1,1))
}
else
{
colvect <- rep(brewer.pal(ceiling(length(SpikeIndex[[type]])/2),"Set1"),2)
##plot
plot((min-1):(max+1),(min-1):(max+1),type="n",xlab="expected ratios", ylab="observed ratios",
main=spikeList[[type]][1,"Type"])
for(i in 1:length(SpikeIndex[[type]]))
{
yy <- mval[SpikeIndex[[type]][[i]]]
points(rep(expected[i],length(yy)),yy,col="black", pch=LETTERS[i],cex=1.5)
if(length(grep("EC",as.character(spikeList[[type]][i,"Probe_Name"])))>0)
points(expected[i], median(yy,na.rm=TRUE), col=colvect[i], pch=19,cex=3)
else
{
points(expected[i], median(yy,na.rm=TRUE), col=colvect[i], pch=17,cex=3)
##print(median(yy,na.rm=TRUE))
}
}
abline(0,1,lty=2)
op <- par(mar=c(5,2,5,10))
plot(rep(1,length(SpikeIndex[[type]])),1:length(SpikeIndex[[type]]),
type="n", xlab="", ylab="", axes=FALSE, xlim=c(1,1))
for(i in 1:length(SpikeIndex[[type]]))
{
points(1, i,col=colvect[i],
pch=ifelse(length(grep("EC",spikeList[[type]][i,"Probe_Name"]))>0,19,17),cex=3)
axis(4,at=1:length(SpikeIndex[[type]]),
paste(LETTERS[1:length(SpikeIndex[[type]])], as.character(names(SpikeIndex[[type]])),sep=":"),
las=2,cex.axis=1.5,tick=FALSE,line=-3)
}
par(op)
}
}
}
## Example
#png("testMMplot_MJs.png",width=1000,height=1000)
#par(mfrow=c(2,2),cex.main=2,cex.lab=1.5,oma=c(4,4,4,4))
#Spike.MMplot(Mval, spikes[1],cy5col="CY5.ng._MjDC_V1.7",cy3col="CY3.ng._MjDC_V1.7")
#Spike.MMplot(Mval, spikes[2],cy5col="CY5.ng._MjDC_V1.7",cy3col="CY3.ng._MjDC_V1.7")
#dev.off()
## --------------------------------------------------------------------------------
## Spike.Sensitivity
## concentration (mass) vs raw signal for each channel
## Input: output from read.SpikeTypes
## Output: boxplot of log raw signal / log concentration
## Bg sub or not depending on input
Spike.Sensitivity <- function(rawobj,spikeList, id="SeqID", gnames=RG$genes[,"ID"], annot=MEEBOset,cy5col="MassCy5",cy3col="MassCy3",namecol=c("Name","Symbol"))
{
if(length(namecol)>2)
namecol <- namecol[1]
SpikeIndex <- getSpikeIndex(spikeList,id=id,annot=annot,gnames=gnames,namecol=namecol)
for(type in 1:length(spikeList))
{
expectedR <- log.na(as.numeric(spikeList[[type]][,cy5col]),2)
expectedG <- log.na(as.numeric(spikeList[[type]][,cy3col]),2)
max <- max(c(expectedR,expectedG),na.rm=TRUE)
min <- min(c(expectedR,expectedG),na.rm=TRUE)
Cy5 <- c()
Cy3 <- c()
massCy5 <- c()
massCy3 <- c()
for(i in 1:length(SpikeIndex[[type]]))
{
##yy <- maLR(rawobj)[SpikeIndex[[type]][[i]]]
yy <- log.na(rawobj$R[SpikeIndex[[type]][[i]]],2)
Cy5 <- c(Cy5,yy)
massCy5 <- c(massCy5,rep(expectedR[i],length(yy)))
yy <- log.na(rawobj$G[SpikeIndex[[type]][[i]]],2)
Cy3 <- c(Cy3,yy)
massCy3 <- c(massCy3,rep(expectedG[i],length(yy)))
}
resCy5<- split(data.frame(cbind(massCy5,Cy5)),factor(massCy5))
resCy3<- split(data.frame(cbind(massCy3,Cy3)),factor(massCy3))
plot((min-1):(max+1),(min-1):(max+1),type="n",xlab="Log2 mass",
ylab="Signal intensity",ylim=c(0,16),xlim=c(0,10),
main=paste(spikeList[[type]][1,"Type"],"Cy5",sep=" "))
for(i in 1:length(resCy5))
{
boxplot(resCy5[[i]][,2], at=resCy5[[i]][1,1],col="red",add=TRUE)
}
plot((min-1):(max+1),(min-1):(max+1),type="n",xlab="Log2 mass",
ylab="Signal intensity",ylim=c(0,16),xlim=c(0,10),
main=paste(spikeList[[type]][1,"Type"],"Cy3",sep=" "))
for(i in 1:length(resCy3))
{
boxplot(resCy3[[i]][,2], at=resCy3[[i]][1,1],col="green",add=TRUE)
}
}
}
## Example
#png("Sensitivity.png", width=800,height=1000)
#par(mfrow=c(2,2))
#Spike.Sensitivity(nbg,spikes)
#dev.off()
## --------------------------------------------------------------------
## Spike.MM.Scatter
# MMplot: scatter plot + expected ratio superimposed
## Input: results from readSpikeTypes
## Output: scatter plot of observed ratio and expected ratio for each spike
Spike.MM.Scatter <- function(mval,spikeList, id="SeqID", gnames=RG$genes[,"ID"], annot=MEEBOset,
cy5col="CY5.ng._MjDC_V1.7",cy3col="CY3.ng._MjDC_V1.7",namecol=NULL)
{
SpikeIndex <- getSpikeIndex(spikeList,id=id,annot=annot,gnames=gnames,namecol=namecol)
yrange <- range(mval[unlist(SpikeIndex)],na.rm=TRUE)
for(type in 1:length(SpikeIndex))
{
expected <- log.na(as.numeric(spikeList[[type]][,cy5col]) / as.numeric(spikeList[[type]][,cy3col]),2)
##set the color
#if (length(SpikeIndex[[type]])>16)
# colvect <- "blue"
#else
# colvect <- rep(brewer.pal(ceiling(length(SpikeIndex[[type]])/2),"Set1"),2)
##plot
yrange <- range(yrange,expected,na.rm=TRUE)
plot(1:length(SpikeIndex[[type]]),1:length(SpikeIndex[[type]]),
type="n",xlab="", ylab="Observed ratios",ylim=yrange,axes=FALSE,
main=spikeList[[type]][1,"Type"])
for(i in 1:length(SpikeIndex[[type]]))
{
yy <- mval[SpikeIndex[[type]][[i]]]
points(rep(i,length(yy)),yy,col="black", pch=18,cex=1.5)
points(i,expected[i],pch=19,cex=2,col="red")
}
abline(h=c(-2,-1,0,1,2),lty=2)
axis(1,at=1:length(SpikeIndex[[type]]),labels=names(SpikeIndex[[type]]),las=2)
axis(2,las=2);box()
}
}
## Example
#png("MM.scatter.png", width=600,height=800)
#par(mar=c(7,4,4,4),mfrow=c(2,1),oma=c(2,2,2,2))
#Spike.MM.Scatter(Mval,spikes)
#dev.off()
##-------------------------------------------------------------------------
## Cy3 vs Cy5 raw signal, linear scale
## Bg sub depends on input
## All spikes
## Input: spikeTypes: results of readSpotTypes
Spike.Cy5vsCy3 <- function(rawobj,spikesTypes, id="SeqID",
annot=MEEBOset,gnames=RG$genes[,"ID"],
cy5col="CY5.ng._MjDC_V1.7",cy3col="CY3.ng._MjDC_V1.7",...)
{
## read everything into a matrix
## spikesTypes <- readSpotTypes(file=file,path=path)
## remove missing data NA or ""
spikesTypes <- spikesTypes[!is.na(spikesTypes[,cy5col]),]
## get all replicates on array using SeqId
TmpIds <- sapply(spikesTypes[,id],
function(x){as.character(annot[grep(as.character(x),as.character(annot[,id])),"uniqID"])})
## Get the colors
## expectedRatio <- spikesTypes[,cy5col]/spikesTypes[,cy3col]
expectedRatio <- as.numeric(spikesTypes[,cy5col])/as.numeric(spikesTypes[,cy3col])
ratioSpiked <- sort(unique(expectedRatio))
colvect <- rainbow(length(ratioSpiked))
indexcol <- match(expectedRatio,ratioSpiked)
## Get the plot
axisrange <- range(log.na(c(rawobj$R,rawobj$G),2),na.rm=TRUE)
axisrange[2] <- axisrange[2]+1.5
plot(1:length(TmpIds),1:length(TmpIds),type="n",xlim=axisrange,
ylim=axisrange,xlab="Log2 Cy5 signal", ylab="Log2 Cy3 signal",
main="Comparison of Cy5 and Cy3 raw signal intensity")
for(i in 1:length(TmpIds))
{
index <- match(TmpIds[[i]],as.character(gnames))
points(log.na(rawobj$R[index,],2),log.na(rawobj$G[index,],2),
##pch=18,col=1)
pch=18,col=colvect[indexcol[i]])
}
legend(axisrange[2]-2.2,axisrange[2]-0.5,"Expected log2 ratios",
bty="n",cex=0.7)
legend(axisrange[2]-1,axisrange[2]-1,pch=18,col=colvect,bty="o",
as.character(log2(ratioSpiked)))
abline(0,1,lty=2)
}
##----------------------------------------------------------------
## Spike.Sensitivity indivudual boxplots
## concentration (mass) vs raw signal for each channel
## Input: output from read.SpikeTypes
## Output: boxplot of log raw signal ordered by input mass
## Bg sub or not depending on input
##Example
#png("testIndiBplot.png",width=1000,height=1000)
#par(mfrow=c(2,2), oma=c(3,3,3,3),mar=c(5,4,5,4))
#Spike.Individual.Sensitivity(RGsub,spikeList,namecol="Symbol")
#dev.off()
Spike.Individual.Sensitivity <- function(rawobj,spikeList=NULL, id="SeqID", gnames=RG$genes[,"ID"], annot=MEEBOset,cy5col="MassCy5",cy3col="MassCy3",namecol=c("Name","Symbol"),ctllist=MEEBOctrl,DEBUG=FALSE)
{
if(DEBUG) print("Starting Spike.Individual.Sensitivity")
if(length(namecol)>1)
namecol <- namecol[1]
# Aval <- (log.na(rawobj$R,2) + log.na(rawobj$G,2))/2
spikeIndex <- getSpikeIndex(spikeList,id=id,annot=annot,gnames=gnames,namecol=namecol)
goodNegCtl <- ctllist[[11]][!is.na(match(ctllist[[11]], rownames(rawobj$R)))]
negCtlCy5 <- log.na(rawobj$R[goodNegCtl,],2)
negCtlCy3 <- log.na(rawobj$G[goodNegCtl,],2)
for(type in 1:length(spikeIndex))
{
orderCy5 <- sort(as.numeric(spikeList[[type]][,cy5col]),index.return=TRUE)$ix
orderCy3 <- sort(as.numeric(spikeList[[type]][,cy3col]),index.return=TRUE)$ix
plot(1:(length(spikeIndex[[type]])+1),1:(length(spikeIndex[[type]])+1),
type="n",ylim=c(0,16),xlab="",axes=FALSE,
ylab="Log2 signal",main=paste(spikeList[[type]][1,"Type"]," : log2(Cy5) by increasing concentration",sep=" "))
boxplot(negCtlCy5,add=TRUE,col="blue",at=1,axes=FALSE,na.rm=TRUE)
for(j in 1:length(orderCy5))
{
boxplot(log.na(rawobj$R[spikeIndex[[type]][[orderCy5[j]]],],2),add=TRUE,col="red",
at=(j+1),axes=FALSE,na.rm=TRUE)
}
axis(1,at=1:(length(orderCy5)+1),labels=c("Neg Ctrl",spikeList[[type]][orderCy5,namecol]),las=2)
axis(2,las=2, at=seq(0,16,2));box()
# axis(4, at=quantile(Aval, c(0.25,0.5,0.75,0.9,1), na.rm=TRUE),
# label=c(0.25,0.5,0.75,0.9,1), las= 2)
# abline(h=quantile(Aval, c(0.25,0.5,0.75,0.9,1), na.rm=TRUE),lwd=2,lty=2)
plot(1:(length(spikeIndex[[type]])+1),1:(length(spikeIndex[[type]])+1),
type="n",ylim=c(0,16),xlab="",axes=FALSE,
ylab="Log2 signal",main=paste(spikeList[[type]][1,"Type"]," : log2(Cy3) by increasing concentration",sep=" "))
boxplot(negCtlCy3,add=TRUE,col="blue",at=1,axes=FALSE)
for(j in 1:length(orderCy3))
{
boxplot(log.na(rawobj$G[spikeIndex[[type]][[orderCy3[j]]],],2),add=TRUE,col="green",
at=(j+1),axes=FALSE)
}
axis(1,at=1:(length(orderCy3)+1),labels=c("Neg Ctrl",spikeList[[type]][orderCy3,namecol]),las=2)
axis(2,las=2,at=seq(0,16,2));box()
}
}
##Spike.Individual.Sensitivity(RGsub,spikeList[1],namecol="Symbol")
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