PoisonAlien/rnbeads.r

## rnbeads.r
####################################################################################
#
# Best-practice 450k/EPIC QC and preprocessing workflow for the PPCG project
#
# creator: Pavlo Lutsik
#
# 30.01.2021
####################################################################################

library(RnBeads)
library(grid)
library(wateRmelon)
libra

#devtools::load_all("~/RnBeads_mmbc/", reset=FALSE)
rnb.options(disk.dump.big.matrices=FALSE)
rnb.options(region.types=character(0))

# 0. Configuration (on b370-worker01)
DATA_DIR<-"../01-raw_data/GDCdata/TCGA-ACC/"
IDAT_DIR<-file.path(DATA_DIR)
#SAMPLE_SHEET<-file.path(DATA_DIR, "Annotation", "PPCA_Sample_annotation_an_PL.txt")
SAMPLE_SHEET<-file.path(DATA_DIR, "sample_table.csv")

#ID_COL="Meth_Local_Sample_ID"
ID_COL="Tumor_Sample_Barcode"

#OUT_DIR<-"/local3/PPCG/analysis/rnbeads/"
OUT_DIR<-"ACC"
dir.create(OUT_DIR, showWarnings = FALSE)

################################################### 1. Loading

sample_sheet<-read.csv(SAMPLE_SHEET, sep=",", as.is=TRUE)
rnb.options(identifiers.column=ID_COL)

#sample_sheet$barcode<-sample_sheet$Barcode
#sample_sheet$barcode<-gsub("_Grn|_Grn.idat|_Grb.idat|_Grn.idat.gz", "", sample_sheet$idat_grn_filename)

#sample_sheet<-sample_sheet[sample_sheet$Platform %in% c("450K", "450k"),]
#sample_sheet<-sample_sheet[sample_sheet[[ID_COL]] == "PPCG0388m_450k",]

#quick workaround
#sample_sheet<-sample_sheet[-which(duplicated(sample_sheet[[ID_COL]])),]

rnb.set.raw<-rnb.execute.import(data.source=list(IDAT_DIR, sample_sheet))

## save the dataset

#save.rnb.set(rnb.set.raw, path=file.path(DATA_DIR, "PPCG_rnb_set_raw"))

#################################################### 2. QC

### control boxplots
ctypes<-rnb.infinium.control.targets(rnb.set.raw@target)

plots<-lapply(ctypes, function (ct) rnb.plot.control.boxplot(rnb.set.raw, ct))
grb<-arrangeGrob(grobs=plots, respect=FALSE)

pdf(file.path(OUT_DIR, "qc_boxplots.pdf"), width=20, height=20)
grid.draw(grb)
dev.off()

### SNP heatmap

pdf(file.path(OUT_DIR, "snp_heatmap.pdf"), width=7, height=7)
rnb.plot.snp.heatmap(rnb.set.raw)
dev.off()

## experiment with the QC data

qc_data<-qc(rnb.set.raw)
qc_anno<-rnb.get.annotation(gsub("probes", "controls", rnb.set.raw@target))

colnames(qc_data[["Cy5"]])<-paste0(samples(rnb.set.raw), "_Grn")
colnames(qc_data[["Cy3"]])<-paste0(samples(rnb.set.raw), "_Red")

qc_data<-cbind(qc_anno, qc_data[["Cy5"]], qc_data[["Cy3"]])

####

qc_df<-data.frame(Sample=samples(rnb.set.raw), Group= OUT_DIR, Cohort = OUT_DIR)

## number of bad detection p-values

DPVAL_MAX<-0.05

dp<-dpval(rnb.set.raw)

qc_df$High_dpval_count<-colSums(dp>DPVAL_MAX)

p<-ggplot(qc_df, aes(x=Group, y=High_dpval_count)) + geom_violin() + geom_jitter(aes(color=Cohort, shape=Cohort))

p<-p+scale_shape_manual(values=5:13)

p<-p + ggtitle(paste("Number of detection P-values >", DPVAL_MAX))

pdf(file.path(OUT_DIR, "dpval_violin.pdf"), width=7, height=7)
print(p)
dev.off()

p<-p+scale_y_log10()

pdf(file.path(OUT_DIR, "dpval_violin_log10.pdf"), width=7, height=7)
print(p)
dev.off()

## median bead count distribution
BEAD_NUMBER_MIN<-3

bc<-covg(rnb.set.raw)

qc_df$Median_bead_counts<-colMedians(bc)

p<-ggplot(qc_df, aes(x=Group, y=Median_bead_counts)) + geom_violin() + geom_jitter(aes(color=Cohort, shape=Cohort))

p<-p+scale_shape_manual(values=5:13)

p<-p + ggtitle(paste("Median bead count"))

pdf(file.path(OUT_DIR, "bc_median.pdf"), width=7, height=7)
print(p)
dev.off()

qc_df$Low_bead_counts<-colSums(bc<BEAD_NUMBER_MIN)

p<-ggplot(qc_df, aes(x=Group, y=Low_bead_counts)) + geom_violin() + geom_jitter(aes(color=Cohort, shape=Cohort))

p<-p+scale_shape_manual(values=5:13)

p<-p + ggtitle(paste("Number of samples with bead count<",BEAD_NUMBER_MIN))

pdf(file.path(OUT_DIR, "bc_low.pdf"), width=7, height=7)
print(p)
dev.off()

###### SNP distances

mm<-meth(rnb.set.raw, row.names=TRUE)
mm.snp<-mm[grep("rs" ,rownames(mm)),]

dd.snp<-as.matrix(dist(t(mm.snp)))

dist.self<-diag(dd.snp)

snp_dist_df<-data.frame(Group="PPCG", Value=as.numeric(dd.snp[lower.tri(dd.snp)]))

p<-ggplot(snp_dist_df, aes(x=Group, y=Value)) + geom_violin() + geom_jitter(height=0)# aes(color=Cohort, shape=Cohort))

pdf(file.path(OUT_DIR, "snp_dist_distribution.pdf"), width=7, height=7)
print(p)
dev.off()


#################################################### 3. Normalization
NORM_METHOD<-"scaling"
#BG_METHOD<-"enmix.oob"
BG_METHOD<-"subtraction"


### workflow 107, the best from the internal benchmarking study
### pOOBAH filtering  + methylumi NOOB bg subtraction + watermelon nanes + BMIQ
NORM_METHOD<-"wm.nanes+bmiq"
BG_METHOD<-"methylumi.noob"

rnb.set.norm<-rnb.execute.normalization(object = rnb.set.raw, method = NORM_METHOD, bgcorr.method = BG_METHOD, verbose = TRUE)

save.rnb.set(rnb.set.norm, path=file.path(DATA_DIR, "PPCG_rnb_set_raw"))

#################################################### 4. Filtering

#### PARAMETERS
BEAD_NUMBER_MIN<-3L
DPVAL_MAX<-0.05
SNP_FILTER<-c("no", "3", "5", "any", "yes")[3L]
NON_CG_CONTEXT<-c("CC","CAG","CAH","CTG","CTH","Other")
NA_QUANTILE_PROBES<-0.01 #threshold: Maximum quantile of 'NA's allowed per site. This must be a value between 0 and 1.
NA_QUANTILE_SAMPLES<-0.002


MAX_LOW_NBEADS<-0.01
MAX_HIGH_DPVAL<-0.01

##################

## 4.1 Greedycut

#Executes the Greedycut procedure for probe and sample filtering
#based on the detection p-values, and calculates statistics on its
#iterations.
#DPVAL_MAX<-0.05
#BEAD_NUMBER_MIN<-3L

#rnb.options(filtering.greedycut.pvalue.threshold=DPVAL_MAX)
#rnb.options(filtering.coverage.threshold=BEAD_NUMBER_MIN)

if(FALSE){
  greedycut_result<-rnb.execute.greedycut(rnb.set.norm, pval.threshold=1, min.coverage=BEAD_NUMBER_MIN)

  rem<-length(greedycut_result$sites)
  qc_df$Greedycut_removed<-rem

  all<-nrow(rnb.set.norm@sites)
  cat(sprintf("[Greedycut] removed %d of %d probes\n", rem, all, 100*rem/all))

  rnb.set<-remove.sites(rnb.set.norm, greedycut_result$sites)

  if(FALSE){
    rnb.set<-remove.samples(rnb.set, greedycut_result$samples)
  }
}


## 4.1.1 POOBAH

## p-value with Out-Of-Band Array Hybridization

rnb.set.mod<-rnb.execute.pOOBAH(rnb.set,  pval.thresh=DPVAL_MAX, verbose=TRUE)

na.orig<-is.na(meth(rnb.set))
na.poobah<-is.na(meth(rnb.set.mod))
na.poobah[na.orig]<-FALSE

qc_df$pOOBAH_masked_count<-colSums(na.poobah)

#rnb.set<-rnb.set.mod


## 4.2 Mask remaining low detection and low bead number

dpval_mask_result<-rnb.execute.high.dpval.masking(rnb.set.mod, dpval.threshold=DPVAL_MAX)

dpval_mask_result$dataset.before<-NULL
rnb.set<-dpval_mask_result$dataset
dpval_mask_result$dataset<-NULL

qc_df$High_dpval_masked_count<-colSums(dpval_mask_result$mask)
rem<-sum(qc_df$High_dpval_masked_count)
all<-prod(dim(meth(rnb.set)))
cat(sprintf("[High detection p-value masking] masked %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))

######

covg_mask_result<-rnb.execute.low.coverage.masking(rnb.set, covg.threshold=BEAD_NUMBER_MIN)

covg_mask_result$dataset.before<-NULL
rnb.set<-covg_mask_result$dataset
covg_mask_result$dataset<-NULL

qc_df$Low_coverage_masked_count<-colSums(covg_mask_result$mask)
rem<-sum(qc_df$Low_coverage_masked_count)
all<-prod(dim(meth(rnb.set)))
cat(sprintf("[Low-coverage masking] masked %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))

## 4.3 Intensity artefacts

#### no specialized function yet

## 4.4 Cross-reactive probes

cross_reactive_result<-rnb.execute.cross.reactive.removal(rnb.set)

all<-nrow(rnb.set@sites)
cross_reactive_result$dataset.before<-NULL
rnb.set<-cross_reactive_result$dataset
cross_reactive_result$dataset<-NULL

rem<-length(cross_reactive_result$filtered)
qc_df$Removed_cross_reactive<-rem

cat(sprintf("[Removing cross-reactive probes] removed %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))


## 4.5. SNP-overlapping probes

### TODO: use MethylToSNP

#SNP_FILTER<-c("no", "3", "5", "any", "yes")[3L]

#*'filtering.snp'*' = "3"' Removal of sites or probes based on
#overlap with SNPs. The accepted values for this option are:

#"no" no SNP-based filtering;

#"3" filter out a probe when the last 3 bases in its target
# sequence overlap with SNP;

#"5" filter out a probe when the last 5 bases in its target
# sequence overlap with SNP;

#"any" or "yes" filter out a CpG site or probe when any
# base in its target sequence overlaps with SNP.

#Bisulfite sequencing datasets operate on sites instead of
#probes, therefore, the values '"3"' and '"5"' are treated as
#"yes"

snp_overlapping_result<-rnb.execute.snp.removal(rnb.set, snp=SNP_FILTER)

all<-nrow(rnb.set@sites)
snp_overlapping_result$dataset.before<-NULL
rnb.set<-snp_overlapping_result$dataset
snp_overlapping_result$dataset<-NULL

rem<-length(snp_overlapping_result$filtered)
qc_df$Removed_SNP_overlapping<-rem

cat(sprintf("[Removing cross-reactive probes] removed %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))

## 4.6. Non-relevant contexts
#NON_CG_CONTEXT<-c("CC","CAG","CAH","CTG","CTH","Other")

context_result<-rnb.execute.context.removal(rnb.set, contexts=NON_CG_CONTEXT)

all<-nrow(rnb.set@sites)
context_result$dataset.before<-NULL
rnb.set<-context_result$dataset
context_result$dataset<-NULL

rem<-length(context_result$filtered)
qc_df$Removed_irrelevant_context<-rem

cat(sprintf("[Removing non-CpG probes] removed %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))


## 4.7 Non-variable sites

if(FALSE){

  MIN_SD<-0.05

  variability_result<-rnb.execute.variability.removal(rnb.set, min.deviation=MIN_SD)

  variability_result$dataset.before<-NULL
  rnb.set<-variability_result$dataset
  variability_result$dataset<-NULL

  qc_df$Removed_non_variable<-length(variability_result$filtered)

}

## 4.8 Missing value removal

#NA_QUANTILE_PROBES<-0.01
#threshold: Maximum quantile of 'NA's allowed per site. This must be a
# value between 0 and 1.

na_result<-rnb.execute.na.removal(rnb.set, threshold=NA_QUANTILE_PROBES)

all<-nrow(rnb.set@sites)
na_result$dataset.before<-NULL
rnb.set<-na_result$dataset
na_result$dataset<-NULL

rem<-length(na_result$filtered)
qc_df$Removed_missing_values<-rem

cat(sprintf("[Removing NA-value probes] removed %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))


## 4.9 Sites on sex chromosomes --- irrelevant

#rnb.set<-rnb.execute.sex.removal(rnb.set)


## 4.10 Removing low-quality samples

NA_QUANTILE_SAMPLES<-0.002

na.perc<-colSums(is.na(meth(rnb.set)))/nrow(rnb.set@sites)
qc_df$Fraction_missing_values<-na.perc

pdf(file.path(OUT_DIR, "NA_count_distribution.pdf"), width=7, height=7)
hist(na.perc, breaks=100)
dev.off()

pdf(file.path(OUT_DIR, "NA_count_distribution_zoom.pdf"), width=7, height=7)
hist(na.perc, breaks=1000,xlim=c(0, 0.02))
dev.off()

low_quality_samples<-which(na.perc>NA_QUANTILE_SAMPLES)

qc_df$Low_quality<-"no"
qc_df$Low_quality[low_quality_samples]<-"yes"
cat(sprintf("[Low-quality samples] identified %d potentially low-quality samples", length(low_quality_samples), 100*length(low_quality_samples)/length(samples(rnb.set))))

write.table(qc_df, file=file.path(OUT_DIR, "QC_summary_table.txt"), sep="\t", quote=FALSE)

#################################################### 5. Postprocessing QC and validation


#################################################### 6. Export

saveRDS(rnb.set, file=file.path(OUT_DIR, "rnb.set_filtered_normalized.RDS"))
	####################################################################################
	#
	# Best-practice 450k/EPIC QC and preprocessing workflow for the PPCG project
	#
	# creator: Pavlo Lutsik
	#
	# 30.01.2021
	####################################################################################

	library(RnBeads)
	library(grid)
	library(wateRmelon)
	libra

	#devtools::load_all("~/RnBeads_mmbc/", reset=FALSE)
	rnb.options(disk.dump.big.matrices=FALSE)
	rnb.options(region.types=character(0))

	# 0. Configuration (on b370-worker01)
	DATA_DIR<-"../01-raw_data/GDCdata/TCGA-ACC/"
	IDAT_DIR<-file.path(DATA_DIR)
	#SAMPLE_SHEET<-file.path(DATA_DIR, "Annotation", "PPCA_Sample_annotation_an_PL.txt")
	SAMPLE_SHEET<-file.path(DATA_DIR, "sample_table.csv")

	#ID_COL="Meth_Local_Sample_ID"
	ID_COL="Tumor_Sample_Barcode"

	#OUT_DIR<-"/local3/PPCG/analysis/rnbeads/"
	OUT_DIR<-"ACC"
	dir.create(OUT_DIR, showWarnings = FALSE)

	################################################### 1. Loading

	sample_sheet<-read.csv(SAMPLE_SHEET, sep=",", as.is=TRUE)
	rnb.options(identifiers.column=ID_COL)

	#sample_sheet$barcode<-sample_sheet$Barcode
	#sample_sheet$barcode<-gsub("_Grn\|_Grn.idat\|_Grb.idat\|_Grn.idat.gz", "", sample_sheet$idat_grn_filename)

	#sample_sheet<-sample_sheet[sample_sheet$Platform %in% c("450K", "450k"),]
	#sample_sheet<-sample_sheet[sample_sheet[[ID_COL]] == "PPCG0388m_450k",]

	#quick workaround
	#sample_sheet<-sample_sheet[-which(duplicated(sample_sheet[[ID_COL]])),]

	rnb.set.raw<-rnb.execute.import(data.source=list(IDAT_DIR, sample_sheet))

	## save the dataset

	#save.rnb.set(rnb.set.raw, path=file.path(DATA_DIR, "PPCG_rnb_set_raw"))

	#################################################### 2. QC

	### control boxplots
	ctypes<-rnb.infinium.control.targets(rnb.set.raw@target)

	plots<-lapply(ctypes, function (ct) rnb.plot.control.boxplot(rnb.set.raw, ct))
	grb<-arrangeGrob(grobs=plots, respect=FALSE)

	pdf(file.path(OUT_DIR, "qc_boxplots.pdf"), width=20, height=20)
	grid.draw(grb)
	dev.off()

	### SNP heatmap

	pdf(file.path(OUT_DIR, "snp_heatmap.pdf"), width=7, height=7)
	rnb.plot.snp.heatmap(rnb.set.raw)
	dev.off()

	## experiment with the QC data

	qc_data<-qc(rnb.set.raw)
	qc_anno<-rnb.get.annotation(gsub("probes", "controls", rnb.set.raw@target))

	colnames(qc_data[["Cy5"]])<-paste0(samples(rnb.set.raw), "_Grn")
	colnames(qc_data[["Cy3"]])<-paste0(samples(rnb.set.raw), "_Red")

	qc_data<-cbind(qc_anno, qc_data[["Cy5"]], qc_data[["Cy3"]])

	####

	qc_df<-data.frame(Sample=samples(rnb.set.raw), Group= OUT_DIR, Cohort = OUT_DIR)

	## number of bad detection p-values

	DPVAL_MAX<-0.05

	dp<-dpval(rnb.set.raw)

	qc_df$High_dpval_count<-colSums(dp>DPVAL_MAX)

	p<-ggplot(qc_df, aes(x=Group, y=High_dpval_count)) + geom_violin() + geom_jitter(aes(color=Cohort, shape=Cohort))

	p<-p+scale_shape_manual(values=5:13)

	p<-p + ggtitle(paste("Number of detection P-values >", DPVAL_MAX))

	pdf(file.path(OUT_DIR, "dpval_violin.pdf"), width=7, height=7)
	print(p)
	dev.off()

	p<-p+scale_y_log10()

	pdf(file.path(OUT_DIR, "dpval_violin_log10.pdf"), width=7, height=7)
	print(p)
	dev.off()

	## median bead count distribution
	BEAD_NUMBER_MIN<-3

	bc<-covg(rnb.set.raw)

	qc_df$Median_bead_counts<-colMedians(bc)

	p<-ggplot(qc_df, aes(x=Group, y=Median_bead_counts)) + geom_violin() + geom_jitter(aes(color=Cohort, shape=Cohort))

	p<-p+scale_shape_manual(values=5:13)

	p<-p + ggtitle(paste("Median bead count"))

	pdf(file.path(OUT_DIR, "bc_median.pdf"), width=7, height=7)
	print(p)
	dev.off()

	qc_df$Low_bead_counts<-colSums(bc<BEAD_NUMBER_MIN)

	p<-ggplot(qc_df, aes(x=Group, y=Low_bead_counts)) + geom_violin() + geom_jitter(aes(color=Cohort, shape=Cohort))

	p<-p+scale_shape_manual(values=5:13)

	p<-p + ggtitle(paste("Number of samples with bead count<",BEAD_NUMBER_MIN))

	pdf(file.path(OUT_DIR, "bc_low.pdf"), width=7, height=7)
	print(p)
	dev.off()

	###### SNP distances

	mm<-meth(rnb.set.raw, row.names=TRUE)
	mm.snp<-mm[grep("rs" ,rownames(mm)),]

	dd.snp<-as.matrix(dist(t(mm.snp)))

	dist.self<-diag(dd.snp)

	snp_dist_df<-data.frame(Group="PPCG", Value=as.numeric(dd.snp[lower.tri(dd.snp)]))

	p<-ggplot(snp_dist_df, aes(x=Group, y=Value)) + geom_violin() + geom_jitter(height=0)# aes(color=Cohort, shape=Cohort))

	pdf(file.path(OUT_DIR, "snp_dist_distribution.pdf"), width=7, height=7)
	print(p)
	dev.off()


	#################################################### 3. Normalization
	NORM_METHOD<-"scaling"
	#BG_METHOD<-"enmix.oob"
	BG_METHOD<-"subtraction"


	### workflow 107, the best from the internal benchmarking study
	### pOOBAH filtering + methylumi NOOB bg subtraction + watermelon nanes + BMIQ
	NORM_METHOD<-"wm.nanes+bmiq"
	BG_METHOD<-"methylumi.noob"

	rnb.set.norm<-rnb.execute.normalization(object = rnb.set.raw, method = NORM_METHOD, bgcorr.method = BG_METHOD, verbose = TRUE)

	save.rnb.set(rnb.set.norm, path=file.path(DATA_DIR, "PPCG_rnb_set_raw"))

	#################################################### 4. Filtering

	#### PARAMETERS
	BEAD_NUMBER_MIN<-3L
	DPVAL_MAX<-0.05
	SNP_FILTER<-c("no", "3", "5", "any", "yes")[3L]
	NON_CG_CONTEXT<-c("CC","CAG","CAH","CTG","CTH","Other")
	NA_QUANTILE_PROBES<-0.01 #threshold: Maximum quantile of 'NA's allowed per site. This must be a value between 0 and 1.
	NA_QUANTILE_SAMPLES<-0.002


	MAX_LOW_NBEADS<-0.01
	MAX_HIGH_DPVAL<-0.01

	##################

	## 4.1 Greedycut

	#Executes the Greedycut procedure for probe and sample filtering
	#based on the detection p-values, and calculates statistics on its
	#iterations.
	#DPVAL_MAX<-0.05
	#BEAD_NUMBER_MIN<-3L

	#rnb.options(filtering.greedycut.pvalue.threshold=DPVAL_MAX)
	#rnb.options(filtering.coverage.threshold=BEAD_NUMBER_MIN)

	if(FALSE){
	greedycut_result<-rnb.execute.greedycut(rnb.set.norm, pval.threshold=1, min.coverage=BEAD_NUMBER_MIN)

	rem<-length(greedycut_result$sites)
	qc_df$Greedycut_removed<-rem

	all<-nrow(rnb.set.norm@sites)
	cat(sprintf("[Greedycut] removed %d of %d probes\n", rem, all, 100*rem/all))

	rnb.set<-remove.sites(rnb.set.norm, greedycut_result$sites)

	if(FALSE){
	rnb.set<-remove.samples(rnb.set, greedycut_result$samples)
	}
	}


	## 4.1.1 POOBAH

	## p-value with Out-Of-Band Array Hybridization

	rnb.set.mod<-rnb.execute.pOOBAH(rnb.set, pval.thresh=DPVAL_MAX, verbose=TRUE)

	na.orig<-is.na(meth(rnb.set))
	na.poobah<-is.na(meth(rnb.set.mod))
	na.poobah[na.orig]<-FALSE

	qc_df$pOOBAH_masked_count<-colSums(na.poobah)

	#rnb.set<-rnb.set.mod


	## 4.2 Mask remaining low detection and low bead number

	dpval_mask_result<-rnb.execute.high.dpval.masking(rnb.set.mod, dpval.threshold=DPVAL_MAX)

	dpval_mask_result$dataset.before<-NULL
	rnb.set<-dpval_mask_result$dataset
	dpval_mask_result$dataset<-NULL

	qc_df$High_dpval_masked_count<-colSums(dpval_mask_result$mask)
	rem<-sum(qc_df$High_dpval_masked_count)
	all<-prod(dim(meth(rnb.set)))
	cat(sprintf("[High detection p-value masking] masked %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))

	######

	covg_mask_result<-rnb.execute.low.coverage.masking(rnb.set, covg.threshold=BEAD_NUMBER_MIN)

	covg_mask_result$dataset.before<-NULL
	rnb.set<-covg_mask_result$dataset
	covg_mask_result$dataset<-NULL

	qc_df$Low_coverage_masked_count<-colSums(covg_mask_result$mask)
	rem<-sum(qc_df$Low_coverage_masked_count)
	all<-prod(dim(meth(rnb.set)))
	cat(sprintf("[Low-coverage masking] masked %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))

	## 4.3 Intensity artefacts

	#### no specialized function yet

	## 4.4 Cross-reactive probes

	cross_reactive_result<-rnb.execute.cross.reactive.removal(rnb.set)

	all<-nrow(rnb.set@sites)
	cross_reactive_result$dataset.before<-NULL
	rnb.set<-cross_reactive_result$dataset
	cross_reactive_result$dataset<-NULL

	rem<-length(cross_reactive_result$filtered)
	qc_df$Removed_cross_reactive<-rem

	cat(sprintf("[Removing cross-reactive probes] removed %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))


	## 4.5. SNP-overlapping probes

	### TODO: use MethylToSNP

	#SNP_FILTER<-c("no", "3", "5", "any", "yes")[3L]

	#'filtering.snp'' = "3"' Removal of sites or probes based on
	#overlap with SNPs. The accepted values for this option are:

	#"no" no SNP-based filtering;

	#"3" filter out a probe when the last 3 bases in its target
	# sequence overlap with SNP;

	#"5" filter out a probe when the last 5 bases in its target
	# sequence overlap with SNP;

	#"any" or "yes" filter out a CpG site or probe when any
	# base in its target sequence overlaps with SNP.

	#Bisulfite sequencing datasets operate on sites instead of
	#probes, therefore, the values '"3"' and '"5"' are treated as
	#"yes"

	snp_overlapping_result<-rnb.execute.snp.removal(rnb.set, snp=SNP_FILTER)

	all<-nrow(rnb.set@sites)
	snp_overlapping_result$dataset.before<-NULL
	rnb.set<-snp_overlapping_result$dataset
	snp_overlapping_result$dataset<-NULL

	rem<-length(snp_overlapping_result$filtered)
	qc_df$Removed_SNP_overlapping<-rem

	cat(sprintf("[Removing cross-reactive probes] removed %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))

	## 4.6. Non-relevant contexts
	#NON_CG_CONTEXT<-c("CC","CAG","CAH","CTG","CTH","Other")

	context_result<-rnb.execute.context.removal(rnb.set, contexts=NON_CG_CONTEXT)

	all<-nrow(rnb.set@sites)
	context_result$dataset.before<-NULL
	rnb.set<-context_result$dataset
	context_result$dataset<-NULL

	rem<-length(context_result$filtered)
	qc_df$Removed_irrelevant_context<-rem

	cat(sprintf("[Removing non-CpG probes] removed %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))


	## 4.7 Non-variable sites

	if(FALSE){

	MIN_SD<-0.05

	variability_result<-rnb.execute.variability.removal(rnb.set, min.deviation=MIN_SD)

	variability_result$dataset.before<-NULL
	rnb.set<-variability_result$dataset
	variability_result$dataset<-NULL

	qc_df$Removed_non_variable<-length(variability_result$filtered)

	}

	## 4.8 Missing value removal

	#NA_QUANTILE_PROBES<-0.01
	#threshold: Maximum quantile of 'NA's allowed per site. This must be a
	# value between 0 and 1.

	na_result<-rnb.execute.na.removal(rnb.set, threshold=NA_QUANTILE_PROBES)

	all<-nrow(rnb.set@sites)
	na_result$dataset.before<-NULL
	rnb.set<-na_result$dataset
	na_result$dataset<-NULL

	rem<-length(na_result$filtered)
	qc_df$Removed_missing_values<-rem

	cat(sprintf("[Removing NA-value probes] removed %d values out of %d, %1.3f %%\n", rem, all, 100*rem/all))


	## 4.9 Sites on sex chromosomes --- irrelevant

	#rnb.set<-rnb.execute.sex.removal(rnb.set)


	## 4.10 Removing low-quality samples

	NA_QUANTILE_SAMPLES<-0.002

	na.perc<-colSums(is.na(meth(rnb.set)))/nrow(rnb.set@sites)
	qc_df$Fraction_missing_values<-na.perc

	pdf(file.path(OUT_DIR, "NA_count_distribution.pdf"), width=7, height=7)
	hist(na.perc, breaks=100)
	dev.off()

	pdf(file.path(OUT_DIR, "NA_count_distribution_zoom.pdf"), width=7, height=7)
	hist(na.perc, breaks=1000,xlim=c(0, 0.02))
	dev.off()

	low_quality_samples<-which(na.perc>NA_QUANTILE_SAMPLES)

	qc_df$Low_quality<-"no"
	qc_df$Low_quality[low_quality_samples]<-"yes"
	cat(sprintf("[Low-quality samples] identified %d potentially low-quality samples", length(low_quality_samples), 100*length(low_quality_samples)/length(samples(rnb.set))))

	write.table(qc_df, file=file.path(OUT_DIR, "QC_summary_table.txt"), sep="\t", quote=FALSE)

	#################################################### 5. Postprocessing QC and validation




	#################################################### 6. Export

	saveRDS(rnb.set, file=file.path(OUT_DIR, "rnb.set_filtered_normalized.RDS"))