R/dataProcessPlotsLiP.R
In Vitek-Lab/MSstatsLiP: LiP Significance Analysis in shotgun mass spectrometry-based proteomic experiments
Defines functions
dataProcessPlotsLiP
Documented in
dataProcessPlotsLiP
#' Visualization for explanatory data analysis
#'
#' To illustrate the quantitative data and quality control of MS runs,
#' dataProcessPlotsLiP takes the quantitative data from MSstatsLiP converter
#' functions as input
#' and generate two types of figures in pdf files as output :
#' (1) profile plot (specify "ProfilePlot" in option type), to identify the
#' potential sources of variation for each protein;
#' (2) quality control plot (specify "QCPlot" in option type), to evaluate the
#' systematic bias between MS runs.
#'
#' @export
#' @importFrom data.table `:=`
#' @importFrom MSstatsPTM dataProcessPlotsPTM
#' @param data name of the list with LiP and (optionally) Protein data, which
#' can be the output of the MSstatsLiP.
#' \code{\link[MSstatsLiP]{dataSummarizationLiP}} function.
#' @param type choice of visualization. "ProfilePlot" represents profile plot of
#' log intensities across MS runs.
#' "QCPlot" represents box plots of log intensities across channels and MS runs.
#' @param ylimUp upper limit for y-axis in the log scale.
#' FALSE(Default) for Profile Plot and QC Plot uses the upper limit as rounded
#' off maximum of log2(intensities) after normalization + 3..
#' @param ylimDown lower limit for y-axis in the log scale. FALSE(Default) for
#' Profile Plot and QC Plot uses 0..
#' @param x.axis.size size of x-axis labeling for "Run" and "channel in Profile
#' Plot and QC Plot.
#' @param y.axis.size size of y-axis labels. Default is 10.
#' @param text.size size of labels represented each condition at the top of
#' Profile plot and QC plot. Default is 4.
#' @param text.angle angle of labels represented each condition at the top of
#' Profile plot and QC plot. Default is 0.
#' @param legend.size size of legend above Profile plot. Default is 7.
#' @param dot.size.profile size of dots in Profile plot. Default is 2.
#' @param ncol.guide number of columns for legends at the top of plot. Default
#' is 5.
#' @param width width of the saved pdf file. Default is 10.
#' @param height height of the saved pdf file. Default is 10.
#' @param lip.title title of all LiP QC plot
#' @param protein.title title of all Protein QC plot
#' @param which.Peptide LiP peptide list to draw plots. List can be names of
#' LiP peptides or order numbers of LiPs.
#' Default is "all", which generates all plots for each protein. For QC plot,
#' "allonly" will generate one QC plot with all proteins.
#' @param which.Protein String of protein's to plot if the user would like to
#' plot all Peptides associated with a given Protein. Default is NULL. Please do
#' not include "all" or "allonly" here.
#' @param originalPlot TRUE(default) draws original profile plots, without
#' normalization.
#' @param summaryPlot TRUE(default) draws profile plots with protein
#' summarization for each channel and MS run.
#' @param address the name of folder that will store the results. Default folder
#' is the current working directory.
#' The other assigned folder has to be existed under the current working
#' directory.
#' An output pdf file is automatically created with the default name of
#' "ProfilePlot.pdf" or "QCplot.pdf".
#' The command address can help to specify where to store the file as well as
#' how to modify the beginning of the file name.
#' If address=FALSE, plot will be not saved as pdf file but showed in window.
#' @return plot or pdf
#' @examples
#' # Use the output of the MSstatsLiP_Summarized function
#' # Profile Plot
#' dataProcessPlotsLiP(MSstatsLiP_Summarized, type = "ProfilePlot")
#'
#' # QCPlot Plot
#' dataProcessPlotsLiP(MSstatsLiP_Summarized, type = "QCPlot")
#'
dataProcessPlotsLiP <- function(data,
type = 'PROFILEPLOT',
ylimUp = FALSE,
ylimDown = FALSE,
x.axis.size = 10,
y.axis.size = 10,
text.size = 4,
text.angle = 90,
legend.size = 7,
dot.size.profile = 2,
ncol.guide = 5,
width = 10,
height = 12,
lip.title = "All Peptides",
protein.title = "All Proteins",
which.Peptide = "all",
which.Protein = NULL,
originalPlot = TRUE,
summaryPlot = TRUE,
address = "") {
PROTEIN <- Protein <- FULL_PEPTIDE <- NULL
## Filter for all PTMs in one protein
if (!is.null(which.Protein)){
data$LiP$FeatureLevelData <- data$LiP$FeatureLevelData[
PROTEIN %in% which.Protein]
data$LiP$ProteinLevelData <- data$LiP$ProteinLevelData[
Protein %in% which.Protein]
if (!is.null(data$TrP)){
data$TrP$FeatureLevelData <- as.data.table(data$TrP$FeatureLevelData)[
PROTEIN %in% which.Protein]
data$TrP$ProteinLevelData <- as.data.table(data$TrP$ProteinLevelData)[
Protein %in% which.Protein]
if (sum(nrow(data$TrP$ProteinLevelData),
nrow(data$TrP$FeatureLevelData)) == 0){
data$TrP <- NULL
}
}
which.Protein <- NULL
}
## Format into PTM format
Lip.data <- data[["LiP"]]
Lip.data.Processed <- Lip.data$FeatureLevelData
Lip.data.Processed$PROTEIN <- Lip.data.Processed$FULL_PEPTIDE
Lip.data.Processed <- as.data.table(Lip.data.Processed)
Lip.data.Processed[, FULL_PEPTIDE := NULL]
Lip.data.Run <- Lip.data$ProteinLevelData
Lip.data.Run <- as.data.table(Lip.data.Run)
Lip.data.Run$Protein <- Lip.data.Run$FULL_PEPTIDE
Lip.data.Run[, FULL_PEPTIDE := NULL]
TrP.data <- data[["TrP"]]
format.data <- list(PTM = list(FeatureLevelData = Lip.data.Processed,
ProteinLevelData = Lip.data.Run,
SummaryMethod = Lip.data[["SummaryMethod"]],
ModelQC = Lip.data[["ModelQC"]],
PredictBySurvival = Lip.data[["PredictBySurvival"]]),
PROTEIN = TrP.data)
## Plot
dataProcessPlotsPTM(format.data, type, ylimUp, ylimDown, x.axis.size,
y.axis.size, text.size, text.angle, legend.size,
dot.size.profile, ncol.guide, width, height, lip.title,
protein.title, which.Peptide, which.Protein, originalPlot,
summaryPlot, address)
}
Vitek-Lab/MSstatsLiP documentation built on April 5, 2024, 3:25 a.m.
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Defines functions dataProcessPlotsLiP
Documented in dataProcessPlotsLiP
#' Visualization for explanatory data analysis
#'
#' To illustrate the quantitative data and quality control of MS runs,
#' dataProcessPlotsLiP takes the quantitative data from MSstatsLiP converter
#' functions as input
#' and generate two types of figures in pdf files as output :
#' (1) profile plot (specify "ProfilePlot" in option type), to identify the
#' potential sources of variation for each protein;
#' (2) quality control plot (specify "QCPlot" in option type), to evaluate the
#' systematic bias between MS runs.
#'
#' @export
#' @importFrom data.table `:=`
#' @importFrom MSstatsPTM dataProcessPlotsPTM
#' @param data name of the list with LiP and (optionally) Protein data, which
#' can be the output of the MSstatsLiP.
#' \code{\link[MSstatsLiP]{dataSummarizationLiP}} function.
#' @param type choice of visualization. "ProfilePlot" represents profile plot of
#' log intensities across MS runs.
#' "QCPlot" represents box plots of log intensities across channels and MS runs.
#' @param ylimUp upper limit for y-axis in the log scale.
#' FALSE(Default) for Profile Plot and QC Plot uses the upper limit as rounded
#' off maximum of log2(intensities) after normalization + 3..
#' @param ylimDown lower limit for y-axis in the log scale. FALSE(Default) for
#' Profile Plot and QC Plot uses 0..
#' @param x.axis.size size of x-axis labeling for "Run" and "channel in Profile
#' Plot and QC Plot.
#' @param y.axis.size size of y-axis labels. Default is 10.
#' @param text.size size of labels represented each condition at the top of
#' Profile plot and QC plot. Default is 4.
#' @param text.angle angle of labels represented each condition at the top of
#' Profile plot and QC plot. Default is 0.
#' @param legend.size size of legend above Profile plot. Default is 7.
#' @param dot.size.profile size of dots in Profile plot. Default is 2.
#' @param ncol.guide number of columns for legends at the top of plot. Default
#' is 5.
#' @param width width of the saved pdf file. Default is 10.
#' @param height height of the saved pdf file. Default is 10.
#' @param lip.title title of all LiP QC plot
#' @param protein.title title of all Protein QC plot
#' @param which.Peptide LiP peptide list to draw plots. List can be names of
#' LiP peptides or order numbers of LiPs.
#' Default is "all", which generates all plots for each protein. For QC plot,
#' "allonly" will generate one QC plot with all proteins.
#' @param which.Protein String of protein's to plot if the user would like to
#' plot all Peptides associated with a given Protein. Default is NULL. Please do
#' not include "all" or "allonly" here.
#' @param originalPlot TRUE(default) draws original profile plots, without
#' normalization.
#' @param summaryPlot TRUE(default) draws profile plots with protein
#' summarization for each channel and MS run.
#' @param address the name of folder that will store the results. Default folder
#' is the current working directory.
#' The other assigned folder has to be existed under the current working
#' directory.
#' An output pdf file is automatically created with the default name of
#' "ProfilePlot.pdf" or "QCplot.pdf".
#' The command address can help to specify where to store the file as well as
#' how to modify the beginning of the file name.
#' If address=FALSE, plot will be not saved as pdf file but showed in window.
#' @return plot or pdf
#' @examples
#' # Use the output of the MSstatsLiP_Summarized function
#' # Profile Plot
#' dataProcessPlotsLiP(MSstatsLiP_Summarized, type = "ProfilePlot")
#'
#' # QCPlot Plot
#' dataProcessPlotsLiP(MSstatsLiP_Summarized, type = "QCPlot")
#'
dataProcessPlotsLiP <- function(data,
type = 'PROFILEPLOT',
ylimUp = FALSE,
ylimDown = FALSE,
x.axis.size = 10,
y.axis.size = 10,
text.size = 4,
text.angle = 90,
legend.size = 7,
dot.size.profile = 2,
ncol.guide = 5,
width = 10,
height = 12,
lip.title = "All Peptides",
protein.title = "All Proteins",
which.Peptide = "all",
which.Protein = NULL,
originalPlot = TRUE,
summaryPlot = TRUE,
address = "") {
PROTEIN <- Protein <- FULL_PEPTIDE <- NULL
## Filter for all PTMs in one protein
if (!is.null(which.Protein)){
data$LiP$FeatureLevelData <- data$LiP$FeatureLevelData[
PROTEIN %in% which.Protein]
data$LiP$ProteinLevelData <- data$LiP$ProteinLevelData[
Protein %in% which.Protein]
if (!is.null(data$TrP)){
data$TrP$FeatureLevelData <- as.data.table(data$TrP$FeatureLevelData)[
PROTEIN %in% which.Protein]
data$TrP$ProteinLevelData <- as.data.table(data$TrP$ProteinLevelData)[
Protein %in% which.Protein]
if (sum(nrow(data$TrP$ProteinLevelData),
nrow(data$TrP$FeatureLevelData)) == 0){
data$TrP <- NULL
}
}
which.Protein <- NULL
}
## Format into PTM format
Lip.data <- data[["LiP"]]
Lip.data.Processed <- Lip.data$FeatureLevelData
Lip.data.Processed$PROTEIN <- Lip.data.Processed$FULL_PEPTIDE
Lip.data.Processed <- as.data.table(Lip.data.Processed)
Lip.data.Processed[, FULL_PEPTIDE := NULL]
Lip.data.Run <- Lip.data$ProteinLevelData
Lip.data.Run <- as.data.table(Lip.data.Run)
Lip.data.Run$Protein <- Lip.data.Run$FULL_PEPTIDE
Lip.data.Run[, FULL_PEPTIDE := NULL]
TrP.data <- data[["TrP"]]
format.data <- list(PTM = list(FeatureLevelData = Lip.data.Processed,
ProteinLevelData = Lip.data.Run,
SummaryMethod = Lip.data[["SummaryMethod"]],
ModelQC = Lip.data[["ModelQC"]],
PredictBySurvival = Lip.data[["PredictBySurvival"]]),
PROTEIN = TrP.data)
## Plot
dataProcessPlotsPTM(format.data, type, ylimUp, ylimDown, x.axis.size,
y.axis.size, text.size, text.angle, legend.size,
dot.size.profile, ncol.guide, width, height, lip.title,
protein.title, which.Peptide, which.Protein, originalPlot,
summaryPlot, address)
}
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