R/ttmap_sgn_genes.R
In chronchi/simpleTTMap: simple Two-Tier Mapper: an interface for Two-Tier Mapper
Defines functions
ttmap_sgn_genes
create_dataframe
extract_pvalues
# extract pvalues from the dataframe. the default key is p.value
extract_pvalues <- function(dataframe){
# extract keys
df_names <- names(dataframe)
# create empty array
pvalues <- c()
tvalues <- c()
# iterate over keys to extract pvalues
for (n in df_names){
if (length(dataframe[[n]]) == 1){
pvalues <- c(pvalues, 1)
tvalues <- c(tvalues, 0)
}
else{
pvalues <- c(pvalues, dataframe[[n]]$p.value)
tvalues <- c(tvalues, dataframe[[n]]$statistic)
}
}
stats_ <- list(pvalues, tvalues)
return(stats_)
}
# create dataframe containing p.values mean deviation component,
# adjusted p-values and gene names. The input is a table wit t.test results
create_dataframe <- function(ttest_results){
# first extract p-values
stats_ <- extract_pvalues(ttest_results)
# adjust pvalues
adjus_pvalues <- p.adjust(stats_[[1]], method='BH')
# create final dataframe with gene name, deviation component, p-value and
# adjusted p-value
genes <- names(ttest_results)
mean_dev_com <- c()
for(n in genes){
if (length(ttest_results[[n]]) == 1){
estimate <- ttest_results[[n]][[1]]
}
else {
estimate <- ttest_results[[n]]$estimate
}
mean_dev_com <- c(mean_dev_com, as.numeric(estimate))
}
final_dataframe = data.frame(Gene=genes,
logFC = mean_dev_com,
t = stats_[[2]],
P.Value = stats_[[1]],
adj.P.Val = adjus_pvalues)
return(final_dataframe)
}
ttmap_sgn_genes <- function(ttmap_part2_gtlmap,
ttmap_part1_hda,
ttmap_part1_ctrl_adj,
c,
n = 2,
a = 0,
filename = "ttmap",
annot = ttmap_part1_ctrl_adj$tag.pcl,
col = "NAME",
output_directory = ".",
Relaxed = 1) {
# calculate the p values for all genes in all samples
deviation_components <- ttmap_part1_hda$Dc.Dmat
t_tests <- apply(as.matrix(deviation_components), 1,
function(x){
if(length(unique(x)) == 1){
return(unique(x))
}
else{
return(t.test(x))
}
}
)
t_results <- create_dataframe(t_tests)
# create subdirectories to save the significant genes
sub_directories <- c("all", "mid1", "mid2", "high", "low")
for (sub_dir in sub_directories) {
dir.create( file.path( output_directory, sub_dir ), recursive = TRUE)
}
if(Relaxed != 1) {
ttmap_sgn_genes_inter <- ttmap_sgn_genes_inter2
}
junk_low <- list(x = 0)
# node index
node_index = 1
# all tiers
tiers = list('all', 'low_map', 'mid1_map', 'mid2_map', 'high_map')
for (tier in tiers) {
tier_gtlmap = ttmap_part2_gtlmap[[tier]]
for(i in seq_len(length(tier_gtlmap))){
samples_in_cluster = tier_gtlmap[[i]]
A <- ttmap_sgn_genes_inter(samples_in_cluster,
ttmap_part1_hda, alpha = a)
A <- as.data.frame( as.matrix(A) )
if (dim(A)[2] == 1){
colnames(A) <- samples_in_cluster
}
# A <- cbind(annot[rownames(A), col], A)
# calculate the p-values associated for each gene.
# the null hypothesis is that the genes don't deviate
# from the control group, i.e., their deviation components
# are zero.
list_of_genes <- rownames(A)
sublist_of_results <- c()
for (gene in t_results$Gene){
result_gene = FALSE
for (sub_gene in list_of_genes) {
if (sub_gene == gene){
result_gene = TRUE
break
}
}
sublist_of_results <- c(sublist_of_results, result_gene)
}
sub_t_results = t_results[sublist_of_results,]
# append the p value and adjusted p value columns to the original
# dataframe
A <- cbind('adj_p_value'=sub_t_results$adj.P.Val, A)
A <- cbind('p_value'=sub_t_results$P.Value, A)
tier_strip = str_remove(tier, '_.*')
name_to_save = file.path(output_directory,
tier_strip,
paste( toString(node_index),
'.txt', sep=''
)
)
write.table(A,
file = name_to_save,
quote = FALSE, sep = "\t",
row.names = TRUE, col.names = NA)
node_index = node_index + 1
}
}
}
chronchi/simpleTTMap documentation built on May 12, 2020, 12:38 p.m.
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Defines functions ttmap_sgn_genes create_dataframe extract_pvalues
# extract pvalues from the dataframe. the default key is p.value
extract_pvalues <- function(dataframe){
# extract keys
df_names <- names(dataframe)
# create empty array
pvalues <- c()
tvalues <- c()
# iterate over keys to extract pvalues
for (n in df_names){
if (length(dataframe[[n]]) == 1){
pvalues <- c(pvalues, 1)
tvalues <- c(tvalues, 0)
}
else{
pvalues <- c(pvalues, dataframe[[n]]$p.value)
tvalues <- c(tvalues, dataframe[[n]]$statistic)
}
}
stats_ <- list(pvalues, tvalues)
return(stats_)
}
# create dataframe containing p.values mean deviation component,
# adjusted p-values and gene names. The input is a table wit t.test results
create_dataframe <- function(ttest_results){
# first extract p-values
stats_ <- extract_pvalues(ttest_results)
# adjust pvalues
adjus_pvalues <- p.adjust(stats_[[1]], method='BH')
# create final dataframe with gene name, deviation component, p-value and
# adjusted p-value
genes <- names(ttest_results)
mean_dev_com <- c()
for(n in genes){
if (length(ttest_results[[n]]) == 1){
estimate <- ttest_results[[n]][[1]]
}
else {
estimate <- ttest_results[[n]]$estimate
}
mean_dev_com <- c(mean_dev_com, as.numeric(estimate))
}
final_dataframe = data.frame(Gene=genes,
logFC = mean_dev_com,
t = stats_[[2]],
P.Value = stats_[[1]],
adj.P.Val = adjus_pvalues)
return(final_dataframe)
}
ttmap_sgn_genes <- function(ttmap_part2_gtlmap,
ttmap_part1_hda,
ttmap_part1_ctrl_adj,
c,
n = 2,
a = 0,
filename = "ttmap",
annot = ttmap_part1_ctrl_adj$tag.pcl,
col = "NAME",
output_directory = ".",
Relaxed = 1) {
# calculate the p values for all genes in all samples
deviation_components <- ttmap_part1_hda$Dc.Dmat
t_tests <- apply(as.matrix(deviation_components), 1,
function(x){
if(length(unique(x)) == 1){
return(unique(x))
}
else{
return(t.test(x))
}
}
)
t_results <- create_dataframe(t_tests)
# create subdirectories to save the significant genes
sub_directories <- c("all", "mid1", "mid2", "high", "low")
for (sub_dir in sub_directories) {
dir.create( file.path( output_directory, sub_dir ), recursive = TRUE)
}
if(Relaxed != 1) {
ttmap_sgn_genes_inter <- ttmap_sgn_genes_inter2
}
junk_low <- list(x = 0)
# node index
node_index = 1
# all tiers
tiers = list('all', 'low_map', 'mid1_map', 'mid2_map', 'high_map')
for (tier in tiers) {
tier_gtlmap = ttmap_part2_gtlmap[[tier]]
for(i in seq_len(length(tier_gtlmap))){
samples_in_cluster = tier_gtlmap[[i]]
A <- ttmap_sgn_genes_inter(samples_in_cluster,
ttmap_part1_hda, alpha = a)
A <- as.data.frame( as.matrix(A) )
if (dim(A)[2] == 1){
colnames(A) <- samples_in_cluster
}
# A <- cbind(annot[rownames(A), col], A)
# calculate the p-values associated for each gene.
# the null hypothesis is that the genes don't deviate
# from the control group, i.e., their deviation components
# are zero.
list_of_genes <- rownames(A)
sublist_of_results <- c()
for (gene in t_results$Gene){
result_gene = FALSE
for (sub_gene in list_of_genes) {
if (sub_gene == gene){
result_gene = TRUE
break
}
}
sublist_of_results <- c(sublist_of_results, result_gene)
}
sub_t_results = t_results[sublist_of_results,]
# append the p value and adjusted p value columns to the original
# dataframe
A <- cbind('adj_p_value'=sub_t_results$adj.P.Val, A)
A <- cbind('p_value'=sub_t_results$P.Value, A)
tier_strip = str_remove(tier, '_.*')
name_to_save = file.path(output_directory,
tier_strip,
paste( toString(node_index),
'.txt', sep=''
)
)
write.table(A,
file = name_to_save,
quote = FALSE, sep = "\t",
row.names = TRUE, col.names = NA)
node_index = node_index + 1
}
}
}
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