LSHTM_analysis/scripts/plotting/mcsm_affinity_data_only.R

#source("~/git/LSHTM_analysis/config/pnca.R")
#source("~/git/LSHTM_analysis/config/alr.R")
#source("~/git/LSHTM_analysis/config/gid.R")
#source("~/git/LSHTM_analysis/config/embb.R")
#source("~/git/LSHTM_analysis/config/katg.R")
source("~/git/LSHTM_analysis/config/rpob.R")

source("/home/tanu/git/LSHTM_analysis/my_header.R")
#########################################################
# TASK: Generate averaged affinity values 
# across all affinity tools for a given structure
# as applicable...
#########################################################

#=======
# output
#=======
outdir_images = paste0("~/git/Writing/thesis/images/results/", tolower(gene))

#OutFile1
outfile_mean_aff = paste0(outdir_images, "/", tolower(gene)
                                , "_mean_affinity_all.csv")
print(paste0("Output file:", outfile_mean_aff))

#OutFile2
outfile_mean_aff_priorty = paste0(outdir_images, "/", tolower(gene)
                          , "_mean_affinity_priority.csv")
print(paste0("Output file:", outfile_mean_aff_priorty))

#%%===============================================================

#=============
# Input
#=============
df3_filename = paste0("/home/tanu/git/Data/", drug, "/output/", tolower(gene), "_merged_df3.csv")
df3 = read.csv(df3_filename)
length(df3$mutationinformation)

# mut_info checks
table(df3$mutation_info)
table(df3$mutation_info_orig)
table(df3$mutation_info_labels_orig)

# used in plots and analyses
table(df3$mutation_info_labels) # different, and matches dst_mode
table(df3$dst_mode)

# create column based on dst mode with different colname
table(is.na(df3$dst))
table(is.na(df3$dst_mode))

#===============
# Create column: sensitivity mapped to dst_mode
#===============
df3$sensitivity = ifelse(df3$dst_mode == 1, "R", "S")
table(df3$sensitivity)

length(unique((df3$mutationinformation)))
all_colnames = as.data.frame(colnames(df3))
common_cols  = c("mutationinformation"
                 , "X5uhc_position"
                 , "X5uhc_offset"
                 , "position"
                 , "dst_mode"
                 , "mutation_info_labels"
                 , "sensitivity"
                 , "ligand_distance"
                 , "interface_dist")

all_colnames$`colnames(df3)`[grep("scaled", all_colnames$`colnames(df3)`)]
all_colnames$`colnames(df3)`[grep("outcome", all_colnames$`colnames(df3)`)]

#===================
# stability cols
#===================
raw_cols_stability =  c("duet_stability_change"
                        , "deepddg"
                        , "ddg_dynamut2"
                        , "ddg_foldx")

scaled_cols_stability = c("duet_scaled"       
                           , "deepddg_scaled"   
                           , "ddg_dynamut2_scaled"
                           , "foldx_scaled")

outcome_cols_stability = c("duet_outcome"
                           , "deepddg_outcome"
                           , "ddg_dynamut2_outcome"
                           , "foldx_outcome")

#===================
# affinity cols
#===================
raw_cols_affinity =  c("ligand_affinity_change"
                       , "mmcsm_lig"
                       , "mcsm_ppi2_affinity"
                       , "mcsm_na_affinity")

scaled_cols_affinity = c("affinity_scaled" 
                         , "mmcsm_lig_scaled" 
                         , "mcsm_ppi2_scaled" 
                         , "mcsm_na_scaled" )

outcome_cols_affinity  = c( "ligand_outcome"
                            , "mmcsm_lig_outcome"
                            , "mcsm_ppi2_outcome"
                            , "mcsm_na_outcome")

#===================
# conservation cols
#===================
# raw_cols_conservation =  c("consurf_score"
#                            , "snap2_score"
#                            , "provean_score")
# 
# scaled_cols_conservation = c("consurf_scaled"
#                              , "snap2_scaled"
#                              , "provean_scaled")
# 
# # CANNOT strictly be used, as categories are not identical with conssurf missing altogether
# outcome_cols_conservation = c("provean_outcome"
#                               , "snap2_outcome"
#                               #consurf outcome doesn't exist
# )

######################################################################
cols_to_consider = colnames(df3)[colnames(df3)%in%c(common_cols
                                                    , raw_cols_affinity
                                                    , scaled_cols_affinity
                                                    , outcome_cols_affinity
                                                    , raw_cols_stability
                                                    , scaled_cols_stability
                                                    , outcome_cols_stability             
                                                    )]

cols_to_extract  = cols_to_consider[cols_to_consider%in%c(common_cols
                                                          #, raw_cols_affinity
                                                          , scaled_cols_stability
                                                          , scaled_cols_affinity)]

df3_plot = df3[, cols_to_extract]

# FIXME: ADD distance to NA when SP replies
DistCutOff_colnames = c("ligand_distance", "interface_dist")
DistCutOff = 10

#df3_affinity_filtered = df3_plot[ (df3_plot$ligand_distance<10 | df3_plot$interface_dist <10),]
df3_affinity_filtered = df3_plot[ (df3_plot$ligand_distance<10 & df3_plot$interface_dist <10),]

c0u = unique(df3_affinity_filtered$position)
length(c0u)

foo = df3_affinity_filtered[df3_affinity_filtered$ligand_distance<10,]
bar = df3_affinity_filtered[df3_affinity_filtered$interface_dist<10,]

wilcox.test(foo$mmcsm_lig_scaled~foo$sensitivity)
wilcox.test(foo$mmcsm_lig~foo$sensitivity)

wilcox.test(foo$affinity_scaled~foo$sensitivity)
wilcox.test(foo$ligand_affinity_change~foo$sensitivity)

wilcox.test(bar$mcsm_na_scaled~bar$sensitivity)
wilcox.test(bar$mcsm_na_affinity~bar$sensitivity)

wilcox.test(bar$mcsm_ppi2_scaled~bar$sensitivity)
wilcox.test(bar$mcsm_ppi2_affinity~bar$sensitivity)

##############################################################
df = df3_affinity_filtered
sum(is.na(df))
df2 = na.omit(df)                           # Apply na.omit function

gene_dist_cols = colnames(df2)[colnames(df2)%in%DistCutOff_colnames]
gene_aff_cols = colnames(df2)[colnames(df2)%in%scaled_cols_affinity]
gene_stab_cols = colnames(df2)[colnames(df2)%in%scaled_cols_stability]

sel_cols = c("mutationinformation", "position", gene_stab_cols, gene_dist_cols,  gene_aff_cols)
df3 = df2[, sel_cols]

give_col=function(x,y,df=df3){
  df[df$position==x,y]
}

for (i in unique(df3$position) ){
  #print(i)
  biggest     = max(abs(give_col(i,gene_aff_cols)))
  
  df3[df3$position==i,'abs_max_effect'] = biggest
  df3[df3$position==i,'effect_type']= names(
    give_col(i,gene_aff_cols)[which(
      abs(
        give_col(i,gene_aff_cols)
      ) == biggest, arr.ind=T
    )[, "col"]])
  
  effect_name = unique(df3[df3$position==i,'effect_type'])
  
  # get index/rowname for value of max effect, and then use it to get the original sign
  # here
  #df3[df3$position==i,c(effect_name)]
  #which(abs(df3[df3$position==i,c('position',effect_name)][effect_name])==biggest, arr.ind=T)
  ind = rownames(which(abs(df3[df3$position==i
                                     ,c('position', effect_name)][effect_name])== biggest
                       , arr.ind=T))
  df3[df3$position==i,'effect_sign'] = sign(df3[effect_name][ind,])
}






#%%============================================================
# output
write.csv(combined_df, outfile_mean_ens_st_aff
          , row.names = F)
cat("Finished writing file:\n"
    , outfile_mean_ens_st_aff
    , "\nNo. of rows:", nrow(combined_df)
    , "\nNo. of cols:", ncol(combined_df))

# end of script
#===============================================================