#logo plots # one for multiple muts # --> select/drop down option to filter count of nsSNPs # --> select/drop down option for colour # --> should include WT # Data used #tab_mt # mutant logo plot #tab_wt # wt logo plot # Make it hover over position and then get the corresponding data table! #%%====================================================================== #================== # logo data: OR #================== # NOTE: my_logo_col LogoPlotSnps <- function(plot_df , x_axis_colname = "position" , symbol_mut_colname = "mutant_type" , symbol_wt_colname = "mutant_type" , omit_snp_count = c(0) # can be 1, 2, etc. , my_logo_col = "chemistry" , x_lab = "Position" , y_lab = "Count" , x_ats = 14 # text size , x_tangle = 90 # text angle , y_ats = 22 , y_tangle = 0 , x_tts = 20 # title size , y_tts = 23 , leg_pos = "none" # can be top, left, right and bottom or c(0.8, 0.9) , leg_dir = "horizontal" #can be vertical or horizontal , leg_ts = 20 # leg text size , leg_tts = 16 # leg title size ) { ############################################ # Data processing for logo plot for nsSNPS ############################################ setDT(plot_df)[, mut_pos_occurrence := .N, by = .(eval(parse(text=x_axis_colname)))] table(plot_df[[x_axis_colname]]) table(plot_df$mut_pos_occurrence) max_mut = max(table(plot_df[[x_axis_colname]])) # Subset Data as specified by user pos_freqC = c(1:max_mut) cat("\nDisplaying nsSNP position frequency:\n") print(table(plot_df$mut_pos_occurrence)) if ( (length(omit_snp_count) ==1) && (omit_snp_count == 0) ){ my_data_snp = plot_df u = unique(my_data_snp[[x_axis_colname]]) max_mult_mut = max(table(my_data_snp[[x_axis_colname]])) cat("\nNo filtering requested:" , "\nTotal no. of nsSNPs:", sum(table(plot_df$mut_pos_occurrence)) , "\nTotal no. of nsSNPs omitted:", sum(table(plot_df$mut_pos_occurrence)[omit_snp_count]) , "\nDim of data:", dim(my_data_snp) , "\nNo. of positions:", length(u) , "\nMax no. of muts at any position:", max_mult_mut) } else { my_data_snp = subset(plot_df, !(mut_pos_occurrence%in%omit_snp_count) ) exp_nrows = sum(table(plot_df$mut_pos_occurrence)) - sum(table(plot_df$mut_pos_occurrence)[omit_snp_count]) got_rows = sum(table(my_data_snp$mut_pos_occurrence)) u = unique(my_data_snp[[x_axis_colname]]) max_mult_mut = max(table(my_data_snp[[x_axis_colname]])) if (got_rows == exp_nrows) { cat("\nPass: Position with the stated nsSNP frequency filtered:", omit_snp_count , "\nTotal no. of nsSNPs:", sum(table(plot_df$mut_pos_occurrence)) , "\nTotal no. of nsSNPs omitted:", sum(table(plot_df$mut_pos_occurrence)[omit_snp_count]) , "\nDim of subsetted data:", dim(my_data_snp) , "\nNo. of positions:", length(u) , "\nMax no. of muts at any position:", max_mult_mut) } else { cat("\nFAIL:Position with the stated nsSNP frequency COULD NOT be filtered..." , "\nExpected:",exp_nrows , "\nGot:", got_rows ) } } #-------------------------------------- # matrix for mutant type # frequency of mutant type by position #--------------------------------------- table(my_data_snp[[symbol_mut_colname]], my_data_snp[[x_axis_colname]]) tab_mt = table(my_data_snp[[symbol_mut_colname]], my_data_snp[[x_axis_colname]]) class(tab_mt) # unclass to convert to matrix tab_mt = unclass(tab_mt) if (is.matrix(tab_mt)){ cat("\nPASS: Mutant matrix successfully created..." , "\nRownames of mutant matrix:", rownames(tab_mt) , "\nColnames of mutant matrix:", colnames(tab_mt)) } else{ tab_mt = as.matrix(tab_mt, rownames = T) if (is.matrix(tab_mt)){ cat("\nCreating mutant matrix..." , "\nRownames of mutant matrix:", rownames(tab_mt) , "\nColnames of mutant matrix:", colnames(tab_mt)) } } #------------------------------------- # matrix for wild type # frequency of wild type by position #------------------------------------- tab_wt = table(my_data_snp[[symbol_wt_colname]], my_data_snp[[x_axis_colname]]); tab_wt tab_wt = unclass(tab_wt) # Important: remove wt duplicates #wt = my_data_snp[, c("position", "wild_type")] wt = my_data_snp %>% select(x_axis_colname, symbol_wt_colname) wt = wt[!duplicated(wt),] wt tab_wt = table(wt[[symbol_wt_colname]], wt[[x_axis_colname]]); tab_wt # should all be 1 if ( identical(colnames(tab_mt), colnames(tab_wt) ) && identical(ncol(tab_mt), ncol(tab_wt)) ){ cat("\nPASS: Wild type matrix successfully created" , "\nDim of wt matrix:", dim(tab_wt) , "\nDim of mutant matrix:", dim(tab_mt) , "\n" , "\nRownames of mutant matrix:", rownames(tab_wt) , "\nColnames of mutant matrix:", colnames(tab_wt)) } ###################################### # Generating plots with given y_axis ##################################### if (my_logo_col %in% c('clustalx','taylor')) { cat("\nSelected colour scheme:", my_logo_col , "\nUsing black theme\n") theme_bgc = "black" xfont_bgc = "white" yfont_bgc = "white" xtt_col = "white" ytt_col = "white" } if (my_logo_col %in% c('chemistry', 'hydrophobicity')) { cat('\nSelected colour scheme:', my_logo_col , "\nUsing grey theme") theme_bgc = "grey" xfont_bgc = "black" yfont_bgc = "black" xtt_col = "black" ytt_col = "black" } #LogoSnps_P mut_logo_p = ggseqlogo(tab_mt , method = "custom" , col_scheme = my_logo_col) + theme( # panel.grid = element_blank(), # axis.text.x = element_text(size = x_ats # , angle = x_tangle # , hjust = 1 # , vjust = 0.4 # , colour = xfont_bgc) # , axis.text.y = element_text(size = y_ats # , angle = y_tangle # , hjust = 1 # , vjust = 0 # , colour = yfont_bgc) , axis.title.x = element_text(size = x_tts , colour = xtt_col) , axis.title.y = element_text(size = y_tts , colour = ytt_col) , legend.title = element_text(size = y_tts , colour = ytt_col) , legend.text = element_text(size = leg_ts) , legend.position = leg_pos , legend.direction = leg_dir , plot.background = element_rect(fill = theme_bgc))+ #theme(text = element_text(family = "FreeSans"))+ # theme_logo(base_size = 18)+ # scale_x_continuous(breaks = 1:ncol(tab_mt) # , labels = colnames(tab_mt))+ # scale_y_continuous(breaks = 1:max_mult_mut # , limits = c(0, max_mult_mut)) + scale_x_discrete(x_lab , labels = colnames(tab_mt) , limits = factor(1:ncol(tab_mt)))+ scale_y_continuous(y_lab , breaks = 1:max_mult_mut , limits = c(0, max_mult_mut))#+ # ylab(y_lab)+xlab(x_lab) return(mut_logo_p) } LogoPlotSnps(plot_df = merged_df3 , x_axis_colname = "position" , symbol_mut_colname = "mutant_type" , symbol_wt_colname = "mutant_type" , omit_snp_count = c(0)# can be 1, 2, etc. , my_logo_col = "chemistry" , x_lab = "Position" , y_lab = "Count" , x_ats = 1 # text size , x_tangle = 90 # text angle , y_ats = 1 , y_tangle = 0 , x_tts = 20 # title size , y_tts = 20 , leg_pos = "top" # can be top, left, right and bottom or c(0.8, 0.9) , leg_dir = "horizontal" #can be vertical or horizontal , leg_ts = 20 # leg text size , leg_tts = 16 # leg title size )