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NORMALIZATION.R
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NORMALIZATION.R
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### ORIGINAL AUTHOR: Andrew Teschendorff
# The original BMIQ function from Teschendorff 2013 adjusts for the type-2 bias in
# Illumina Infinium 450k data.
# Later functions and edits were provided by yours truly, Steve Horvath.
# I changed the code so that one can calibrate methylation data to a gold standard.
# Specifically, I took version v_1.2 by Teschendorff and fixed minor issues.
# Also I made the code more robust e.g. by changing the optimization algorithm.
# Toward this end, I used the method="Nelder-Mead" in optim()
### Later functions and edits by Steve Horvath
### # Steve Horvath took version v_1.2 by Teschendorff
# and fixed minor errors. Also he made the code more robust.
# Importantly, SH changed the optimization algorithm to make it #more robust.
# SH used method="Nelder-Mead" in optim() since the other #optimization method sometimes gets stuck.
#Toward this end, the function blc was replaced by blc2.
require(RPMM)
betaEst2 = function (y, w, weights)
{
yobs = !is.na(y)
if (sum(yobs) <= 1)
return(c(1, 1))
y = y[yobs]
w = w[yobs]
weights = weights[yobs]
N = sum(weights * w)
p = sum(weights * w * y) / N
v = sum(weights * w * y * y) / N - p * p
logab = log(c(p, 1 - p)) + log(pmax(1e-06, p * (1 - p) / v -
1))
if (sum(yobs) == 2)
return(exp(logab))
opt = try(optim(
logab,
betaObjf,
ydata = y,
wdata = w,
weights = weights,
method = "Nelder-Mead",
control = list(maxit = 50)
),
silent = TRUE)
if (inherits(opt, "try-error"))
return(c(1, 1))
exp(opt$par)
} # end of function betaEst
blc2 = function (Y,
w,
maxiter = 25,
tol = 1e-06,
weights = NULL,
verbose = TRUE)
{
Ymn = min(Y[Y > 0], na.rm = TRUE)
Ymx = max(Y[Y < 1], na.rm = TRUE)
Y = pmax(Y, Ymn / 2)
Y = pmin(Y, 1 - (1 - Ymx) / 2)
Yobs = !is.na(Y)
J = dim(Y)[2]
K = dim(w)[2]
n = dim(w)[1]
if (n != dim(Y)[1])
stop("Dimensions of w and Y do not agree")
if (is.null(weights))
weights = rep(1, n)
mu = a = b = matrix(Inf, K, J)
crit = Inf
for (i in 1:maxiter) {
warn0 = options()$warn
options(warn = -1)
eta = apply(weights * w, 2, sum) / sum(weights)
mu0 = mu
for (k in 1:K) {
for (j in 1:J) {
ab = betaEst2(Y[, j], w[, k], weights)
a[k, j] = ab[1]
b[k, j] = ab[2]
mu[k, j] = ab[1] / sum(ab)
}
}
ww = array(0, dim = c(n, J, K))
for (k in 1:K) {
for (j in 1:J) {
ww[Yobs[, j], j, k] = dbeta(Y[Yobs[, j], j],
a[k, j], b[k, j], log = TRUE)
}
}
options(warn = warn0)
w = apply(ww, c(1, 3), sum, na.rm = TRUE)
wmax = apply(w, 1, max)
for (k in 1:K)
w[, k] = w[, k] - wmax
w = t(eta * t(exp(w)))
like = apply(w, 1, sum)
w = (1 / like) * w
llike = weights * (log(like) + wmax)
crit = max(abs(mu - mu0))
if (verbose)
print(crit)
if (crit < tol)
break
}
return(list(
a = a,
b = b,
eta = eta,
mu = mu,
w = w,
llike = sum(llike)
))
}
# The function BMIQcalibration was created by Steve Horvath by heavily recycling code
# from A. Teschendorff's BMIQ function.
# BMIQ stands for beta mixture quantile normalization.
# Explanation: datM is a data frame with Illumina beta values (rows are samples, colums are CpGs.
# goldstandard is a numeric vector with beta values that is used as gold standard for calibrating the columns of datM.
# The length of goldstandard has to equal the number of columns of datM.
# Example code: First we impute missing values.
# library(WGCNA); dimnames1=dimnames(datMeth)
# datMeth= data.frame(t(impute.knn(as.matrix(t(datMeth)))$data))
# dimnames(datMeth)=dimnames1
# gold.mean=as.numeric(apply(datMeth,2,mean,na.rm=TRUE))
#datMethCalibrated=BMIQcalibration(datM=datMeth,goldstandard.beta=gold.mean)
BMIQcalibration = function(datM,
goldstandard.beta,
nL = 3,
doH = TRUE,
nfit = 20000,
th1.v = c(0.2, 0.75),
th2.v = NULL,
niter = 5,
tol = 0.001,
plots = FALSE,
calibrateUnitInterval = TRUE) {
if (length(goldstandard.beta) != dim(datM)[[2]]) {
stop(
"Error in function arguments length(goldstandard.beta) !=dim(datM)[[2]]. Consider transposing datM."
)
}
if (plots) {
par(mfrow = c(2, 2))
}
beta1.v = goldstandard.beta
if (calibrateUnitInterval) {
datM = CalibrateUnitInterval(datM)
}
### estimate initial weight matrix from type1 distribution
w0.m = matrix(0, nrow = length(beta1.v), ncol = nL)
w0.m[which(beta1.v <= th1.v[1]), 1] = 1
w0.m[intersect(which(beta1.v > th1.v[1]), which(beta1.v <= th1.v[2])), 2] = 1
w0.m[which(beta1.v > th1.v[2]), 3] = 1
### fit type1
print("Fitting EM beta mixture to goldstandard probes")
set.seed(1)
rand.idx = sample(1:length(beta1.v), min(c(nfit, length(beta1.v))) , replace =
FALSE)
em1.o = blc(
matrix(beta1.v[rand.idx], ncol = 1),
w = w0.m[rand.idx, ],
maxiter = niter,
tol = tol
)
subsetclass1.v = apply(em1.o$w, 1, which.max)
subsetth1.v = c(mean(max(beta1.v[rand.idx[subsetclass1.v == 1]]), min(beta1.v[rand.idx[subsetclass1.v ==
2]])), mean(max(beta1.v[rand.idx[subsetclass1.v == 2]]), min(beta1.v[rand.idx[subsetclass1.v ==
3]])))
class1.v = rep(2, length(beta1.v))
class1.v[which(beta1.v < subsetth1.v[1])] = 1
class1.v[which(beta1.v > subsetth1.v[2])] = 3
nth1.v = subsetth1.v
print("Done")
### generate plot from estimated mixture
if (plots) {
print("Check")
tmpL.v = as.vector(rmultinom(1:nL, length(beta1.v), prob = em1.o$eta))
tmpB.v = vector()
for (l in 1:nL) {
tmpB.v = c(tmpB.v, rbeta(tmpL.v[l], em1.o$a[l, 1], em1.o$b[l, 1]))
}
plot(density(beta1.v), main = paste("Type1fit-", sep = ""))
d.o = density(tmpB.v)
points(d.o$x, d.o$y, col = "green", type = "l")
legend(
x = 0.5,
y = 3,
legend = c("obs", "fit"),
fill = c("black", "green"),
bty = "n"
)
}
### Estimate Modes
if (sum(class1.v == 1) == 1) {
mod1U = beta1.v[class1.v == 1]
}
if (sum(class1.v == 3) == 1) {
mod1M = beta1.v[class1.v == 3]
}
if (sum(class1.v == 1) > 1) {
d1U.o = density(beta1.v[class1.v == 1])
mod1U = d1U.o$x[which.max(d1U.o$y)]
}
if (sum(class1.v == 3) > 1) {
d1M.o = density(beta1.v[class1.v == 3])
mod1M = d1M.o$x[which.max(d1M.o$y)]
}
### BETA 2
for (ii in 1:dim(datM)[[1]]) {
printFlush(paste("ii=", ii))
sampleID = ii
beta2.v = as.numeric(datM[ii, ])
d2U.o = density(beta2.v[which(beta2.v < 0.4)])
d2M.o = density(beta2.v[which(beta2.v > 0.6)])
mod2U = d2U.o$x[which.max(d2U.o$y)]
mod2M = d2M.o$x[which.max(d2M.o$y)]
### now deal with type2 fit
th2.v = vector()
th2.v[1] = nth1.v[1] + (mod2U - mod1U)
th2.v[2] = nth1.v[2] + (mod2M - mod1M)
### estimate initial weight matrix
w0.m = matrix(0, nrow = length(beta2.v), ncol = nL)
w0.m[which(beta2.v <= th2.v[1]), 1] = 1
w0.m[intersect(which(beta2.v > th2.v[1]), which(beta2.v <= th2.v[2])), 2] = 1
w0.m[which(beta2.v > th2.v[2]), 3] = 1
print("Fitting EM beta mixture to input probes")
incProgress(1/dim(datM)[[1]])
# I fixed an error in the following line (replaced beta1 by beta2)
set.seed(1)
rand.idx = sample(1:length(beta2.v), min(c(nfit, length(beta2.v)), na.rm =
TRUE) , replace = FALSE)
em2.o = blc2(
Y = matrix(beta2.v[rand.idx], ncol = 1),
w = w0.m[rand.idx, ],
maxiter = niter,
tol = tol,
verbose = TRUE
)
print("Done")
### for type II probes assign to state (unmethylated, hemi or full methylation)
subsetclass2.v = apply(em2.o$w, 1, which.max)
if (sum(subsetclass2.v == 2) > 0) {
subsetth2.v = c(mean(max(beta2.v[rand.idx[subsetclass2.v == 1]]), min(beta2.v[rand.idx[subsetclass2.v ==
2]])),
mean(max(beta2.v[rand.idx[subsetclass2.v == 2]]), min(beta2.v[rand.idx[subsetclass2.v ==
3]])))
}
if (sum(subsetclass2.v == 2) == 0) {
subsetth2.v = c(
1 / 2 * max(beta2.v[rand.idx[subsetclass2.v == 1]]) + 1 / 2 * mean(beta2.v[rand.idx[subsetclass2.v ==
3]]),
1 / 3 * max(beta2.v[rand.idx[subsetclass2.v == 1]]) + 2 / 3 * mean(beta2.v[rand.idx[subsetclass2.v ==
3]])
)
}
class2.v = rep(2, length(beta2.v))
class2.v[which(beta2.v <= subsetth2.v[1])] = 1
class2.v[which(beta2.v >= subsetth2.v[2])] = 3
### generate plot
if (plots) {
tmpL.v = as.vector(rmultinom(1:nL, length(beta2.v), prob = em2.o$eta))
tmpB.v = vector()
for (lt in 1:nL) {
tmpB.v = c(tmpB.v, rbeta(tmpL.v[lt], em2.o$a[lt, 1], em2.o$b[lt, 1]))
}
plot(density(beta2.v), main = paste("Type2fit-", sampleID, sep = ""))
d.o = density(tmpB.v)
points(d.o$x, d.o$y, col = "green", type = "l")
legend(
x = 0.5,
y = 3,
legend = c("obs", "fit"),
fill = c("black", "green"),
bty = "n"
)
}
classAV1.v = vector()
classAV2.v = vector()
for (l in 1:nL) {
classAV1.v[l] = em1.o$mu[l, 1]
classAV2.v[l] = em2.o$mu[l, 1]
}
### start normalising input probes
print("Start normalising input probes")
nbeta2.v = beta2.v
### select U probes
lt = 1
selU.idx = which(class2.v == lt)
selUR.idx = selU.idx[which(beta2.v[selU.idx] > classAV2.v[lt])]
selUL.idx = selU.idx[which(beta2.v[selU.idx] < classAV2.v[lt])]
### find prob according to typeII distribution
p.v = pbeta(beta2.v[selUR.idx], em2.o$a[lt, 1], em2.o$b[lt, 1], lower.tail =
FALSE)
### find corresponding quantile in type I distribution
q.v = qbeta(p.v, em1.o$a[lt, 1], em1.o$b[lt, 1], lower.tail = FALSE)
nbeta2.v[selUR.idx] = q.v
p.v = pbeta(beta2.v[selUL.idx], em2.o$a[lt, 1], em2.o$b[lt, 1], lower.tail =
TRUE)
### find corresponding quantile in type I distribution
q.v = qbeta(p.v, em1.o$a[lt, 1], em1.o$b[lt, 1], lower.tail = TRUE)
nbeta2.v[selUL.idx] = q.v
### select M probes
lt = 3
selM.idx = which(class2.v == lt)
selMR.idx = selM.idx[which(beta2.v[selM.idx] > classAV2.v[lt])]
selML.idx = selM.idx[which(beta2.v[selM.idx] < classAV2.v[lt])]
### find prob according to typeII distribution
p.v = pbeta(beta2.v[selMR.idx], em2.o$a[lt, 1], em2.o$b[lt, 1], lower.tail =
FALSE)
### find corresponding quantile in type I distribution
q.v = qbeta(p.v, em1.o$a[lt, 1], em1.o$b[lt, 1], lower.tail = FALSE)
nbeta2.v[selMR.idx] = q.v
if (doH) {
### if TRUE also correct type2 hemimethylated probes
### select H probes and include ML probes (left ML tail is not well described by a beta-distribution).
lt = 2
selH.idx = c(which(class2.v == lt), selML.idx)
minH = min(beta2.v[selH.idx], na.rm = TRUE)
maxH = max(beta2.v[selH.idx], na.rm = TRUE)
deltaH = maxH - minH
#### need to do some patching
deltaUH = -max(beta2.v[selU.idx], na.rm = TRUE) + min(beta2.v[selH.idx], na.rm =
TRUE)
deltaHM = -max(beta2.v[selH.idx], na.rm = TRUE) + min(beta2.v[selMR.idx], na.rm =
TRUE)
## new maximum of H probes should be
nmaxH = min(nbeta2.v[selMR.idx], na.rm = TRUE) - deltaHM
## new minimum of H probes should be
nminH = max(nbeta2.v[selU.idx], na.rm = TRUE) + deltaUH
ndeltaH = nmaxH - nminH
### perform conformal transformation (shift+dilation)
## new_beta_H(i) = a + hf*(beta_H(i)-minH);
hf = ndeltaH / deltaH
### fix lower point first
nbeta2.v[selH.idx] = nminH + hf * (beta2.v[selH.idx] - minH)
}
### generate final plot to check normalisation
if (plots) {
print("Generating final plot")
d1.o = density(beta1.v)
d2.o = density(beta2.v)
d2n.o = density(nbeta2.v)
ymax = max(d2.o$y, d1.o$y, d2n.o$y)
plot(
density(beta2.v),
type = "l",
ylim = c(0, ymax),
xlim = c(0, 1),
main = paste("CheckBMIQ-", sampleID, sep = "")
)
points(d1.o$x, d1.o$y, col = "red", type = "l")
points(d2n.o$x, d2n.o$y, col = "blue", type = "l")
legend(
x = 0.5,
y = ymax,
legend = c("type1", "type2", "type2-BMIQ"),
bty = "n",
fill = c("red", "black", "blue")
)
}
datM[ii, ] = nbeta2.v
} # end of for (ii=1 loop
datM
} # end of function BMIQcalibration
CheckBMIQ = function(beta.v, design.v, pnbeta.v) {
### pnbeta is BMIQ normalised profile
type1.idx = which(design.v == 1)
type2.idx = which(design.v == 2)
beta1.v = beta.v[type1.idx]
beta2.v = beta.v[type2.idx]
pnbeta2.v = pnbeta.v[type2.idx]
} # end of function CheckBMIQ
CalibrateUnitInterval = function(datM, onlyIfOutside = TRUE) {
rangeBySample = data.frame(lapply(data.frame(t(datM)), range, na.rm = TRUE))
minBySample = as.numeric(rangeBySample[1, ])
maxBySample = as.numeric(rangeBySample[2, ])
if (onlyIfOutside) {
indexSamples = which((minBySample < 0 |
maxBySample > 1) & !is.na(minBySample) & !is.na(maxBySample))
}
if (!onlyIfOutside) {
indexSamples = 1:length(minBySample)
}
if (length(indexSamples) >= 1) {
for (i in indexSamples) {
y1 = c(0.001, 0.999)
x1 = c(minBySample[i], maxBySample[i])
lm1 = lm(y1 ~ x1)
intercept1 = coef(lm1)[[1]]
slope1 = coef(lm1)[[2]]
datM[i, ] = intercept1 + slope1 * datM[i, ]
} # end of for loop
}
datM
} #end of function for calibrating to [0,1]