added coloured axis barplots

2020-01-22 15:09:21 +00:00 · 2020-01-22 15:09:21 +00:00 · cae9c550a4
commit cae9c550a4
parent 2df031c02a
4 changed files with 697 additions and 4 deletions
--- a/mcsm_analysis/pyrazinamide/scripts/.Rhistory
+++ b/mcsm_analysis/pyrazinamide/scripts/.Rhistory
@ -2,6 +2,202 @@ getwd()
 setwd("~/git/LSHTM_analysis/mcsm_analysis/pyrazinamide/scripts/plotting")
 getwd()
 source("../Header_TT.R")
-source("../combining_two_df.R")
+source("../barplot_colour_function.R")
-source("../combining_two_df.R")
+############################################################
-source("../combining_two_df.R")
+# Output dir for plots
 ############################################################
 out_dir = "~/git/Data/pyrazinamide/output/plots"
 source("subcols_axis.R")
 table(mut_pos_cols$lab_bg)
 #blue   cornflowerblue    green       purple    white  yellow
 #2        2                2            4       117     3
 sum( table(mut_pos_cols$lab_bg) ) == nrow(mut_pos_cols) # should  be True
 table(mut_pos_cols$lab_bg2)
 #green white
 #2   128
 sum( table(mut_pos_cols$lab_bg2) ) ==  nrow(mut_pos_cols) # should  be True
 table(mut_pos_cols$lab_fg)
 #black white
 #124     6
 sum( table(mut_pos_cols$lab_fg) ) ==  nrow(mut_pos_cols) # should  be True
 # very important!
 my_axis_colours = mut_pos_cols$lab_fg
 # now clear mut_pos_cols
 rm(mut_pos_cols)
 ###########################
 # 2: Plot: DUET scores
 ###########################
 #==========================
 # Plot 2: Barplot with scores (unordered)
 # corresponds to DUET_outcome
 # Stacked Barplot with colours: DUET_outcome @ position coloured by
 # stability scores. This is a barplot where each bar corresponds
 # to a SNP and is coloured by its corresponding DUET stability value.
 # Normalised values (range between -1 and 1 ) to aid visualisation
 # NOTE: since barplot plots discrete values, colour = score, so number of
 # colours will be equal to the no. of unique normalised scores
 # rather than a continuous scale
 # will require generating the colour scale separately.
 #============================
 # sanity checks
 upos = unique(my_df$Position)
 str(my_df$DUET_outcome)
 colnames(my_df)
 #===========================
 # Data preparation for plots
 #===========================
 #!!!!!!!!!!!!!!!!!
 # REASSIGNMENT
 df <- my_df
 #!!!!!!!!!!!!!!!!!
 rm(my_df)
 # sanity checks
 # should be a factor
 is.factor(df$DUET_outcome)
 #TRUE
 table(df$DUET_outcome)
 #Destabilizing   Stabilizing
 #288              47
 # should be -1 and 1
 min(df$ratioDUET)
 max(df$ratioDUET)
 # sanity checks
 # very important!!!!
 tapply(df$ratioDUET, df$DUET_outcome, min)
 #Destabilizing   Stabilizing
 #-1.0000000     0.01065719
 tapply(df$ratioDUET, df$DUET_outcome, max)
 #Destabilizing   Stabilizing
 #-0.003875969     1.0000000
 # check unique values in normalised data
 u = unique(df$ratioDUET) # 323
 # %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
 # Run this section if rounding is to be used
 # specify number for rounding
 n = 3
 df$ratioDUETR = round(df$ratioDUET, n)  # 335, 40
 u = unique(df$ratioDUETR) # 287
 # create an extra column called group which contains the "gp name and score"
 # so colours can be generated for each unique values in this column
 my_grp = df$ratioDUETR
 df$group <- paste0(df$DUET_outcome, "_", my_grp, sep = "")  # 335,41
 # Call the function to create the palette based on the group defined above
 colours <- ColourPalleteMulti(df, "DUET_outcome", "my_grp")
 my_title = "Protein stability (DUET)"
 library(ggplot2)
 # axis label size
 my_xaxls = 13
 my_yaxls = 15
 # axes text size
 my_xaxts = 15
 my_yaxts = 15
 # no ordering of x-axis according to frequency
 g = ggplot(df, aes(factor(Position, ordered = T)))
 g +
 geom_bar(aes(fill = group), colour = "grey") +
 scale_fill_manual( values = colours
 , guide = 'none') +
 theme( axis.text.x = element_text(size = my_xaxls
 , angle = 90
 , hjust = 1
 , vjust = 0.4)
 , axis.text.y = element_text(size = my_yaxls
 , angle = 0
 , hjust = 1
 , vjust = 0)
 , axis.title.x = element_text(size = my_xaxts)
 , axis.title.y = element_text(size = my_yaxts ) ) +
 labs(title = my_title
 , x = "Position"
 , y = "Frequency")
 class(df$lab_bg)
 # make this a named vector
 # define cartesian coord
 my_xlim = length(unique(df$Position)); my_xlim
 # axis label size
 my_xals = 15
 my_yals = 15
 # axes text size
 my_xats = 15
 my_yats = 18
 # using geom_tile
 g = ggplot(df, aes(factor(Position, ordered = T)))
 g +
 coord_cartesian(xlim = c(1, my_xlim)
 , ylim = c(0, 6)
 , clip = "off") +
 geom_bar(aes(fill = group), colour = "grey") +
 scale_fill_manual( values = colours
 , guide = 'none') +
 geom_tile(aes(,-0.8, width = 0.9, height = 0.85)
 , fill = df$lab_bg) +
 geom_tile(aes(,-1.2, width = 0.9, height = -0.2)
 , fill = df$lab_bg2) +
 # Here it's important to specify that your axis goes from 1 to max number of levels
 theme( axis.text.x = element_text(size = my_xats
 , angle = 90
 , hjust = 1
 , vjust = 0.4
 , colour = my_axis_colours)
 , axis.text.y = element_text(size = my_yats
 , angle = 0
 , hjust = 1
 , vjust = 0)
 , axis.title.x = element_text(size = my_xals)
 , axis.title.y = element_text(size = my_yals )
 , axis.ticks.x = element_blank()
 ) +
 labs(title = my_title
 , x = "Position"
 , y = "Frequency")
 class(df$lab_bg)
 # make this a named vector
 # define cartesian coord
 my_xlim = length(unique(df$Position)); my_xlim
 # axis label size
 my_xals = 18
 my_yals = 18
 # axes text size
 my_xats = 14
 my_yats = 18
 my_plot_name = "barplot_PS_acoloured.svg"
 out_file = paste0(out_dir, "/", my_plot_name); outfile
 svg(outfile, width = 26, height = 4)
 svg(out_file, width = 26, height = 4)
 # using geom_tile
 g = ggplot(df, aes(factor(Position, ordered = T)))
 outFile = g +
 coord_cartesian(xlim = c(1, my_xlim)
 , ylim = c(0, 6)
 , clip = "off"
 ) +
 geom_bar(aes(fill = group), colour = "grey") +
 scale_fill_manual( values = colours
 , guide = 'none') +
 #  geom_tile(aes(,-0.6, width = 0.9, height = 0.7)
 #            , fill = df$lab_bg) +
 #  geom_tile(aes(,-1, width = 0.9, height = 0.3)
 #            , fill = df$lab_bg2) +
 geom_tile(aes(,-0.8, width = 0.9, height = 0.85)
 , fill = df$lab_bg) +
 geom_tile(aes(,-1.2, width = 0.9, height = -0.2)
 , fill = df$lab_bg2) +
 # Here it's important to specify that your axis goes from 1 to max number of levels
 theme( axis.text.x = element_text(size = my_xats
 , angle = 90
 , hjust = 1
 , vjust = 0.4
 , colour = my_axis_colours)
 , axis.text.y = element_text(size = my_yats
 , angle = 0
 , hjust = 1
 , vjust = 0)
 , axis.title.x = element_text(size = my_xals)
 , axis.title.y = element_text(size = my_yals )
 , axis.ticks.x = element_blank()
 ) +
 labs(title = ""
 , x = "Position"
 , y = "Frequency")
 print(outFile)
 dev.off()
--- a/mcsm_analysis/pyrazinamide/scripts/plotting/barplots_subcolours_aa_PS.R
+++ b/mcsm_analysis/pyrazinamide/scripts/plotting/barplots_subcolours_aa_PS.R
@ -0,0 +1,292 @@
 getwd()
 setwd("~/git/LSHTM_analysis/mcsm_analysis/pyrazinamide/scripts/plotting")
 getwd()
 ############################################################
 # 1: Installing and loading required packages and functions
 ############################################################
 source("../Header_TT.R")
 source("../barplot_colour_function.R")
 ############################################################
 # Output dir for plots
 ############################################################
 out_dir = "~/git/Data/pyrazinamide/output/plots"
 ############################################################
 # 2: call script the prepares the data with columns containing
 # colours for axis labels
 ############################################################
 source("subcols_axis.R")
 # this should return
 #mut_pos_cols: 130, 4
 #my_df: 335, 39
 # clear excess variable
 # "mut_pos_cols" is just for inspection in case you need to cross check
 # position numbers and colours
 # open file from deskptop ("sample_axis_cols") for cross checking
 table(mut_pos_cols$lab_bg)
 sum( table(mut_pos_cols$lab_bg) ) == nrow(mut_pos_cols) # should  be True
 table(mut_pos_cols$lab_bg2)
 sum( table(mut_pos_cols$lab_bg2) ) ==  nrow(mut_pos_cols) # should  be True
 table(mut_pos_cols$lab_fg)
 sum( table(mut_pos_cols$lab_fg) ) ==  nrow(mut_pos_cols) # should  be True
 # very important!
 my_axis_colours = mut_pos_cols$lab_fg
 # now clear mut_pos_cols
 rm(mut_pos_cols) 
 ###########################
 # 2: Plot: DUET scores
 ###########################
 #==========================
 # Plot 2: Barplot with scores (unordered)
 # corresponds to DUET_outcome
 # Stacked Barplot with colours: DUET_outcome @ position coloured by 
 # stability scores. This is a barplot where each bar corresponds 
 # to a SNP and is coloured by its corresponding DUET stability value.
 # Normalised values (range between -1 and 1 ) to aid visualisation
 # NOTE: since barplot plots discrete values, colour = score, so number of
 # colours will be equal to the no. of unique normalised scores 
 # rather than a continuous scale
 # will require generating the colour scale separately.
 #============================
 # sanity checks
 upos = unique(my_df$Position)
 str(my_df$DUET_outcome)
 colnames(my_df)
 #=========================== 
 # Data preparation for plots
 #===========================
 #!!!!!!!!!!!!!!!!!
 # REASSIGNMENT
 df <- my_df
 #!!!!!!!!!!!!!!!!!
 rm(my_df)
 # sanity checks
 # should be a factor
 is.factor(df$DUET_outcome)
 #TRUE
 table(df$DUET_outcome)
 # should be -1 and 1
 min(df$ratioDUET)
 max(df$ratioDUET)
 # sanity checks
 # very important!!!!
 tapply(df$ratioDUET, df$DUET_outcome, min)
 tapply(df$ratioDUET, df$DUET_outcome, max)
 # My colour FUNCTION: based on group and subgroup
 # in my case;
 # df = df
 # group = DUET_outcome
 # subgroup = normalised score i.e ratioDUET
 # Prepare data: round off ratioDUET scores
 # round off to 3 significant digits:
 # 323 if no rounding is performed: used to generate the original graph
 # 287 if rounded to 3 places
 # FIXME: check if reducing precicion creates any ML prob
 # check unique values in normalised data
 u = unique(df$ratioDUET) 
 # %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
 # Run this section if rounding is to be used
 # specify number for rounding
 n = 3 
 df$ratioDUETR = round(df$ratioDUET, n)  
 u = unique(df$ratioDUETR)
 # create an extra column called group which contains the "gp name and score" 
 # so colours can be generated for each unique values in this column
 my_grp = df$ratioDUETR
 df$group <- paste0(df$DUET_outcome, "_", my_grp, sep = "") 
 # ELSE
 # uncomment the below if rounding is not required
 #my_grp = df$ratioDUET
 #df$group <- paste0(df$DUET_outcome, "_", my_grp, sep = "")  
 # %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
 #******************
 # generate plot
 #******************
 # Call the function to create the palette based on the group defined above
 colours <- ColourPalleteMulti(df, "DUET_outcome", "my_grp")
 my_title = "Protein stability (DUET)"
 library(ggplot2)
 # axis label size
 my_xaxls = 13
 my_yaxls = 15
 # axes text size
 my_xaxts = 15
 my_yaxts = 15
 # no ordering of x-axis according to frequency
 g = ggplot(df, aes(factor(Position, ordered = T)))
 g + 
  geom_bar(aes(fill = group), colour = "grey") +
  scale_fill_manual( values = colours
                     , guide = 'none') +
  theme( axis.text.x = element_text(size = my_xaxls
                                    , angle = 90
                                    , hjust = 1
                                    , vjust = 0.4)
         , axis.text.y = element_text(size = my_yaxls 
                                      , angle = 0
                                      , hjust = 1
                                      , vjust = 0)
         , axis.title.x = element_text(size = my_xaxts)
         , axis.title.y = element_text(size = my_yaxts ) ) +
  labs(title = my_title
       , x = "Position"
       , y = "Frequency")
 #========================
 # plot with axis colours
 #========================
 class(df$lab_bg)
 # make this a named vector
 # define cartesian coord
 my_xlim = length(unique(df$Position)); my_xlim
 # axis label size
 my_xals = 15
 my_yals = 15
 # axes text size
 my_xats = 15
 my_yats = 18
 # using geom_tile
 g = ggplot(df, aes(factor(Position, ordered = T)))
 g + 
  coord_cartesian(xlim = c(1, my_xlim)
                  , ylim = c(0, 6)
                  , clip = "off") +
  geom_bar(aes(fill = group), colour = "grey") +
  scale_fill_manual( values = colours
                     , guide = 'none') +
  geom_tile(aes(,-0.8, width = 0.9, height = 0.85)
            , fill = df$lab_bg) +
  geom_tile(aes(,-1.2, width = 0.9, height = -0.2)
            , fill = df$lab_bg2) +
  # Here it's important to specify that your axis goes from 1 to max number of levels
  theme( axis.text.x = element_text(size = my_xats
                                    , angle = 90
                                    , hjust = 1
                                    , vjust = 0.4
                                    , colour = my_axis_colours)
         , axis.text.y = element_text(size = my_yats 
                                      , angle = 0
                                      , hjust = 1
                                      , vjust = 0)
         , axis.title.x = element_text(size = my_xals)
         , axis.title.y = element_text(size = my_yals ) 
         , axis.ticks.x = element_blank()
  ) +
  labs(title = my_title
       , x = "Position"
       , y = "Frequency")
 #========================
 # output plot as svg/png
 #========================
 class(df$lab_bg)
 # make this a named vector
 # define cartesian coord
 my_xlim = length(unique(df$Position)); my_xlim
 # axis label size
 my_xals = 18
 my_yals = 18
 # axes text size
 my_xats = 14
 my_yats = 18
 # set output dir for plots
 #getwd()
 #setwd("~/git/Data/pyrazinamide/output/plots") 
 #getwd()
 plot_name = "barplot_PS_acoloured.svg"
 my_plot_name = paste0(out_dir, "/", plot_name); my_plot_name
 svg(my_plot_name, width = 26, height = 4)
 g = ggplot(df, aes(factor(Position, ordered = T)))
 outFile = g + 
  coord_cartesian(xlim = c(1, my_xlim)
                  , ylim = c(0, 6)
                  , clip = "off"
  ) +
  geom_bar(aes(fill = group), colour = "grey") +
  scale_fill_manual( values = colours
                     , guide = 'none') +
 #  geom_tile(aes(,-0.6, width = 0.9, height = 0.7)
 #            , fill = df$lab_bg) +
 #  geom_tile(aes(,-1, width = 0.9, height = 0.3)
 #            , fill = df$lab_bg2) +
  geom_tile(aes(,-0.8, width = 0.9, height = 0.85)
            , fill = df$lab_bg) +
  geom_tile(aes(,-1.2, width = 0.9, height = -0.2)
            , fill = df$lab_bg2) +
 # Here it's important to specify that your axis goes from 1 to max number of levels
  theme( axis.text.x = element_text(size = my_xats
                                    , angle = 90
                                    , hjust = 1
                                    , vjust = 0.4
                                    , colour = my_axis_colours)
         , axis.text.y = element_text(size = my_yats 
                                      , angle = 0
                                      , hjust = 1
                                      , vjust = 0)
         , axis.title.x = element_text(size = my_xals)
         , axis.title.y = element_text(size = my_yals ) 
         , axis.ticks.x = element_blank()
  ) +
  labs(title = ""
       , x = "Position"
       , y = "Frequency")
 print(outFile)
 dev.off()
 # for sanity and good practice
 #rm(df)
--- a/mcsm_analysis/pyrazinamide/scripts/plotting/lineage_dist_PS.R
+++ b/mcsm_analysis/pyrazinamide/scripts/plotting/lineage_dist_PS.R
@ -7,7 +7,7 @@ getwd()
 ########################################################################
 source("../Header_TT.R")
-#source("barplot_colour_function.R")
+#source("../barplot_colour_function.R")
 #require(data.table)
 ########################################################################
--- a/mcsm_analysis/pyrazinamide/scripts/plotting/subcols_axis.R
+++ b/mcsm_analysis/pyrazinamide/scripts/plotting/subcols_axis.R
@ -0,0 +1,205 @@
 getwd()
 setwd("~/git/LSHTM_analysis/mcsm_analysis/pyrazinamide/scripts/plotting")
 getwd()
 ############################################################
 # 1: Installing and loading required packages and functions
 ############################################################
 #source("../Header_TT.R")
 #source("../barplot_colour_function.R")
 #library(tidyverse)
 ###########################
 #2: Read file: normalised file, output of step 4 mcsm pipeline
 ###########################
 #my_df <- read.csv("../../Data/mcsm_complex1_normalised.csv"
 #                  , row.names = 1
 #                  , stringsAsFactors = F
 #                  , header = T)
 # call script combining_df
 source("../combining_two_df.R")
 #---------------------- PAY ATTENTION
 # the above changes the working dir
 #  from Plotting to Scripts"
 #---------------------- PAY ATTENTION
 #==========================
 # This will return:
 # df with NA for pyrazinamide:
 #merged_df2 
 #merged_df2_comp 
 # df without NA for pyrazinamide:
 #merged_df3 
 #merged_df3_comp 
 #==========================
 ###########################
 # Data to choose: 
 # We will be using the small dfs
 # to generate the coloured axis
 ###########################
 # uncomment as necessary
 #!!!!!!!!!!!!!!!!!!!!!!!
 # REASSIGNMENT
 my_df  = merged_df3
 #my_df  = merged_df3_comp
 #!!!!!!!!!!!!!!!!!!!!!!!
 # delete variables not required
 rm(merged_df2, merged_df2_comp, merged_df3, merged_df3_comp)
 str(my_df)
 my_df$Position
 c1 = my_df[my_df$Mutationinformation == "L4S",]
 # order my_df by Position
 my_df_o = my_df[order(my_df$Position),]
 head(my_df_o$Position); tail(my_df_o$Position)
 c2 = my_df_o[my_df_o$Mutationinformation == "L4S",]
 # sanity check
 if (sum(table(c1 == c2)) == ncol(my_df)){
  print ("Sanity check passsd")
 }else{
  print ("Error!: Please debug your code")
 }
 rm(my_df, c1, c2)
 # create a new df with unique position numbers and cols
 Position = unique(my_df_o$Position) #130
 Position_cols = as.data.frame(Position)
 head(Position_cols) ; tail(Position_cols)
 # specify active site residues and bg colour
 Position = c(49, 51, 57, 71
             , 8, 96, 138
             , 13, 68
             , 103, 137
             , 133, 134) #13
 lab_bg = rep(c("purple" 
               , "yellow"
               , "cornflowerblue"
               , "blue"
               , "green"), times = c(4, 3, 2, 2, 2)
 )
 # second bg colour for active site residues
 #lab_bg2 = rep(c("white" 
 #                , "green" , "white", "green"
 #                , "white"
 #                , "white"
 #                , "white"), times = c(4
 #                                      , 1, 1, 1
 #                                      , 2
 #                                      , 2
 #                                      , 2)
 #)
 # revised: leave the second box coloured as the first one incase there is no second colour
 lab_bg2 = rep(c("purple" 
                , "green" , "yellow", "green"
                , "cornflowerblue"
                , "blue"
                , "green"), times = c(4
                                      , 1, 1, 1
                                      , 2
                                      , 2
                                      , 2)
 )
 # fg colour for labels for active site residues
 #lab_fg = rep(c("white" 
 #               , "black"
 #               , "black"
 #               , "white"
 #               , "black"), times = c(4, 3, 2, 2, 2))
 # revised: make the purple ones black
 # fg colour for labels for active site residues
 lab_fg = rep(c("black" 
               , "black"
               , "black"
               , "white"
               , "black"), times = c(4, 3, 2, 2, 2))               
 # combined df with active sites, bg and fg colours
 aa_cols_ref = data.frame(Position
                         , lab_bg
                         , lab_bg2
                         , lab_fg
                         , stringsAsFactors = F) #13, 4
 str(Position_cols); class(Position_cols)
 str(aa_cols_ref); class(aa_cols_ref)
 # since Position is int and numeric in the two dfs resp, 
 # converting numeric to int for consistency
 aa_cols_ref$Position = as.integer(aa_cols_ref$Position)
 class(aa_cols_ref$Position)
 #===========
 # Merge 1: merging Positions df (Position_cols) and
 # active site cols (aa_cols_ref)
 # linking column: "Position"
 # This is so you can have colours defined for all 130 positions
 #===========
 head(Position_cols$Position); head(aa_cols_ref$Position)
 mut_pos_cols = merge(Position_cols, aa_cols_ref
            , by = "Position"
            , all.x = TRUE) 
 head(mut_pos_cols)
 # replace NA's 
 # :column "lab_bg" with "white"
 # : column "lab_fg" with "black"
 mut_pos_cols$lab_bg[is.na(mut_pos_cols$lab_bg)] <- "white"
 mut_pos_cols$lab_bg2[is.na(mut_pos_cols$lab_bg2)] <- "white"
 mut_pos_cols$lab_fg[is.na(mut_pos_cols$lab_fg)] <- "black"
 head(mut_pos_cols)
 #===========
 # Merge 2: Merge mut_pos_cols with mcsm df
 # Now combined the 130 positions with aa colours with 
 # the mcsm_data
 #===========
 # dfs to merge
 df0 = my_df_o
 df1 = mut_pos_cols
 # check the column on which merge will be performed
 head(df0$Position); tail(df0$Position)
 head(df1$Position); tail(df1$Position)
 # should now have 3 extra columns
 my_df = merge(df0, df1
              , by = "Position"
              , all.x = TRUE)
 # sanity check
 my_df[my_df$Position == "49",]
 my_df[my_df$Position == "13",]
 my_df$Position
 # clear variables
 rm(aa_cols_ref
   , df0
   , df1
   , my_df_o
   , Position_cols
   , lab_bg
   , lab_bg2
   , lab_fg
   , Position
   )