Nothing
R/Modifier-AlkAnilineSeq-class.R
In RNAmodR.AlkAnilineSeq: Detection of m7G, m3C and D modification by AlkAnilineSeq
Defines functions
ModSetAlkAnilineSeq
.find_aas_modifications
.find_aas_modifications_in_data
.get_aas_scores
.aggregate_aas
.apply_Np1_offset
.selected_base_score
.norm_aas_args
ModAlkAnilineSeq
Documented in
ModAlkAnilineSeq
ModSetAlkAnilineSeq
#' @include RNAmodR.AlkAnilineSeq.R
NULL
#' @name ModAlkAnilineSeq
#' @aliases AlkAnilineSeq ModAlkAnilineSeq ModSetAlkAnilineSeq
#'
#' @author Felix G.M. Ernst [aut]
#'
#' @title ModAlkAnilineSeq class to analyze AlkAnilineSeq data
#'
#' @description
#' 7-methyl guanosine (m7G), 3-methyl cytidine (m3C) and Dihydrouridine (D)
#' are commonly found in rRNA and tRNA and can be detected classically by
#' primer extension analysis. However, since the modifications do not interfere
#' with Watson-Crick base pairing, a specific chemical treatment is employed
#' to cause strand breaks specifically at the modified positions.
#'
#' This classical protocol was converted to a high throughput sequencing
#' method call AlkAnilineSeq and allows modified position be detected by an
#' accumulation of 5'-ends at the N+1 position. Since the identify of the
#' unmodified nucleotide is different for the three modified nucleotides, they
#' modification can be detected at the same time from the same samples.
#'
#' \code{dataType} is \code{c("NormEnd3SequenceData","PileupSequenceData")}:
#'
#' The \code{ModAlkAnilineSeq} class uses the
#' \code{\link[RNAmodR:NormEndSequenceData-class]{NormEnd5SequenceData}}
#' class to store and aggregate data along the transcripts. This includes
#' normalized values against the whole transcript (normalzed cleavage) and
#' normalized values against the overlapping reads (stop ratio), which are used
#' to score for modified positions.
#'
#' In addition the
#' \code{\link[RNAmodR:PileupSequenceData-class]{PileupSequenceData}} class is
#' used as well, to check, whether the base is can be called according to the
#' expected sequence identity.
#'
#' Only samples named \code{treated} are used for this analysis. Normalization
#' to untreated samples is currently not used.
#'
#' @param x the input which can be of the different types depending on whether
#' a \code{ModRiboMethSeq} or a \code{ModSetRiboMethSeq} object is to be
#' constructed. For more information have a look at the documentation of
#' the \code{\link[RNAmodR:Modifier-class]{Modifier}} and
#' \code{\link[RNAmodR:ModifierSet-class]{ModifierSet}} classes.
#' @param annotation annotation data, which must match the information contained
#' in the BAM files. This is parameter is only required if \code{x} if not a
#' \code{Modifier} object.
#' @param sequences sequences matching the target sequences the reads were
#' mapped onto. This must match the information contained in the BAM files. This
#' is parameter is only required if \code{x} if not a \code{Modifier} object.
#' @param seqinfo An optional \code{\link[GenomeInfoDb:Seqinfo-class]{Seqinfo}}
#' argument or character vector, which can be coerced to one, to subset the
#' sequences to be analyzed on a per chromosome basis.
#' @param ... Optional arguments overwriting default values, which are
#' \itemize{
#' \item{minLength:} {The minimal read length to be used for the analysis
#' (default: \code{minLength = 9L}).}
#' \item{minSignal:} {The minimal signal at the position as integer value
#' (default: \code{minSignal = 10L}). If the reaction is very specific a lower
#' value may need to be used}
#' \item{minScoreNC:} {minimum for score (normalized cleavage) to identify m7G,
#' m3C and D positions de novo (default: \code{minScoreNC = 50L})}
#' \item{minScoreSR:} {minimum for score (stop ration) to identify m7G, m3C and D
#' positions de novo (default: \code{minScoreSR = 0.5})}
#' \item{minScoreBaseScore:} {minimum score for base calling (0.0-1.0)
#' (default: \code{minScoreSR = 0.9})}
#' \item{scoreOperator:} {how the minimal score should be used as logical
#' operator. "&" requires all minimal values to be exceeded, whereas "|" detects
#' positions, if at least one minimal values is exceeded (default:
#' \code{scoreOperator = "&"}).}
#' \item{other arguments} {which are passed on to
#' \code{\link[RNAmodR:EndSequenceData-class]{End5SequenceData}}}
#' }
#'
#' @return a \code{ModAlkAnilineSeq} or \code{ModSetAlkAnilineSeq} object
#'
#' @references
#' - Marchand V, Ayadi L, __Ernst FGM__, Hertler J, Bourguignon-Igel V,
#' Galvanin A, Kotter A, Helm M, __Lafontaine DLJ__, Motorin Y (2018):
#' "AlkAniline-Seq: Profiling of m7 G and m3 C RNA Modifications at Single
#' Nucleotide Resolution." Angewandte Chemie (International ed. in English) 57
#' (51), P. 16785–16790. DOI:
#' \href{https://doi.org/10.1002/anie.201810946}{10.1002/anie.201810946}.
#'
#' @examples
#' library(RNAmodR.Data)
#' library(rtracklayer)
#' annotation <- GFF3File(RNAmodR.Data.example.AAS.gff3())
#' sequences <- RNAmodR.Data.example.AAS.fasta()
#' files <- list("wt" = c(treated = RNAmodR.Data.example.wt.1()),
#' "Bud23del" = c(treated = RNAmodR.Data.example.bud23.1()),
#' "Trm8del" = c(treated = RNAmodR.Data.example.trm8.1()))
#' # Creating a Modifier object of type ModRiboMethSeq
#' maas <- ModAlkAnilineSeq(files[[1]], annotation = annotation,
#' sequences = sequences)
#' # Creating a ModifierSet object of type ModSetRiboMethSeq
#' msaas <- ModSetAlkAnilineSeq(files, annotation = annotation,
#' sequences = sequences)
NULL
#' @rdname ModAlkAnilineSeq
#' @export
setClass("ModAlkAnilineSeq",
contains = c("RNAModifier"),
prototype = list(mod = c("m7G","m3C","D"),
score = "scoreNC",
dataType = c("NormEnd5SequenceData",
"PileupSequenceData")))
# constructors -----------------------------------------------------------------
#' @rdname ModAlkAnilineSeq
#' @export
ModAlkAnilineSeq <- function(x, annotation = NA, sequences = NA, seqinfo = NA,
...){
RNAmodR::Modifier("ModAlkAnilineSeq", x = x, annotation = annotation,
sequences = sequences, seqinfo = seqinfo, ...)
}
# settings ---------------------------------------------------------------------
#' @name ModAlkAnilineSeq-functions
#' @aliases aggregate modify settings plotData plotDataByCoord
#'
#' @title Functions for ModAlkAnilineSeq
#'
#' @description
#' All of the functions of \code{\link[RNAmodR:Modifier-class]{Modifier}} and
#' the \code{\link[RNAmodR:ModifierSet-class]{ModifierSet}} classes are
#' inherited by the \code{ModAlkAnilineSeq} and \code{ModSetAlkAnilineSeq}
#' classes.
#'
#' @param x a \code{\link[RNAmodR:Modifier-class]{Modifier}} or a
#' \code{\link[RNAmodR:ModifierSet-class]{ModifierSet}} object. For more
#' details see also the man pages for the functions mentioned below.
#' @param value See \code{\link[RNAmodR:Modifier-class]{settings}}
#' @param coord,name,from,to,type,window.size,... See
#' \code{\link[RNAmodR:plotData]{plotData}}.
#'
#' @details
#' \code{ModAlkAnilineSeq} specific arguments for \link{plotData}:
#' \itemize{
#' \item{\code{colour} - }{a named character vector of \code{length = 4}
#' for the colours of the individual histograms. The names are expected to be
#' \code{c("scoreNC","scoreSR")}}
#' }
#'
#' @return
#' \itemize{
#' \item{\code{settings}} {See
#' \code{\link[RNAmodR:Modifier-functions]{settings}}.}
#' \item{\code{aggregate}} {See \code{\link[RNAmodR:aggregate]{aggregate}}.}
#' \item{\code{modify}} {See \code{\link[RNAmodR:modify]{modify}}.}
#' \item{\code{getDataTrack}} {a list of
#' \code{\link[Gviz:DataTrack-class]{DataTrack}} object.}
#' \item{\code{plotData}} {See
#' \code{\link[RNAmodR:plotData]{plotDataByCoord}}.}
#' \item{\code{plotDataByCoord}} {See
#' \code{\link[RNAmodR:plotData]{plotDataByCoord}}.}
#' }
#'
#' @importMethodsFrom RNAmodR modify aggregate settings plotData
#' plotDataByCoord
#'
#' @examples
#' data(msaas,package="RNAmodR.AlkAnilineSeq")
#' maas <- msaas[[1]]
#' settings(maas)
#' aggregate(maas)
#' modify(maas)
#' getDataTrack(maas, "1", mainScore(maas))
NULL
.not_integer_bigger_than_zero <- RNAmodR:::.not_integer_bigger_than_zero
.not_numeric_bigger_zero <- RNAmodR:::.not_numeric_bigger_zero
.not_numeric_between_0_1 <- RNAmodR:::.not_numeric_between_0_1
.not_logical_operator <- RNAmodR:::.not_logical_operator
.ModAlkAnilineSeq_settings <- data.frame(
variable = c("minLength",
"minSignal",
"minScoreNC",
"minScoreSR",
"minScoreBaseScore",
"scoreOperator"),
testFUN = c(".not_integer_bigger_than_zero",
".not_integer_bigger_than_zero",
".not_numeric_bigger_zero",
".not_numeric_between_0_1",
".not_numeric_between_0_1",
".not_logical_operator"),
errorValue = c(TRUE,
TRUE,
TRUE,
TRUE,
TRUE,
TRUE),
errorMessage = c("'minQuality' must be integer with a value higher than 0.",
"'minSignal' must be integer with a value higher than 0.",
"'minScoreNC' must be numeric with a value higher than 0.",
"'minScoreSR' must be numeric with a value between 0 and 1.",
"'minScoreBaseScore' must be numeric with a value between 0 and 1.",
"'scoreOperator' must be either '|' or '&'."),
stringsAsFactors = FALSE)
.norm_aas_args <- function(input){
minLength <- 9L # for all scores
minSignal <- 10L # for all scores
minScoreNC <- 50L # for score normalized cleavage
minScoreSR <- 0.50 # for score stop ratio
minScoreBaseScore <- 0.9 # for base scoring
scoreOperator <- "&"
args <- RNAmodR:::.norm_settings(input, .ModAlkAnilineSeq_settings, minLength,
minSignal, minScoreNC, minScoreSR,
minScoreBaseScore, scoreOperator)
args <- c(RNAmodR:::.norm_Modifier_settings(input),
args)
args
}
#' @rdname ModAlkAnilineSeq-functions
#' @export
setReplaceMethod(f = "settings",
signature = signature(x = "ModAlkAnilineSeq"),
definition = function(x, value){
x <- callNextMethod()
value <- .norm_aas_args(value)
x@settings[names(value)] <- unname(value)
x
})
# functions --------------------------------------------------------------------
.selected_base_score <- function(data,seq){
seq <- IRanges::CharacterList(strsplit(as.character(seq),""))
data <- data@unlistData
# the order of baseSelect and baseColumns must be compatible
# "conversion" T to U is performed with this
baseSelect <- S4Vectors::DataFrame("G" = unlist(seq) == "G",
"A" = unlist(seq) == "A",
"U" = unlist(seq) == "U",
"C" = unlist(seq) == "C")
baseColumns <- which(colnames(data) %in% c("means.treated.G",
"means.treated.A",
"means.treated.T",
"means.treated.C"))
baseData <- as(data[,baseColumns],"NumericList")
baseSelect <- as(baseSelect,"LogicalList")
tmpBaseValues <- unname(baseData)[unname(baseSelect)]
baseValues <- rep(0,nrow(data))
baseValues[which(baseSelect[[1]])] <- tmpBaseValues[[1]]
baseValues[which(baseSelect[[2]])] <- tmpBaseValues[[2]]
baseValues[which(baseSelect[[3]])] <- tmpBaseValues[[3]]
baseValues[which(baseSelect[[4]])] <- tmpBaseValues[[4]]
baseValues[is.na(baseValues)] <- 0
baseValues[is.infinite(baseValues)] <- 0
baseValues
}
.apply_Np1_offset <- function(x){
offsetAdd <- S4Vectors::DataFrame(as.list(rep(0,ncol(x@unlistData))))
colnames(offsetAdd) <- colnames(unlist(x))
x_rownames <- rownames(x)
x <- x[IRanges::IntegerList(Map(seq.int,2L,lengths(x)))]
x_offsetAdd <- IRanges::SplitDataFrameList(rep(list(offsetAdd),length(x)))
x <- rbind(x,x_offsetAdd)
rownames(x) <- x_rownames
x
}
.aggregate_aas <- function(x){
mod <- aggregate(sequenceData(x), condition = "Treated")
if(is.null(names(mod))){
names(mod) <- vapply(mod,class,character(1))
}
# get the NormEnd5SequenceData
# shift each result one position upstream, since the signal has an N+1 offset
endData <- .apply_Np1_offset(mod[["NormEnd5SequenceData"]])
# get the PileupSequenceData
# calculate base score
pileupData <- mod[["PileupSequenceData"]]
score <- .selected_base_score(pileupData,sequences(x))
# subset to columns needed
partitioning <- IRanges::PartitioningByEnd(endData)
endData <- unlist(endData)[,c("means.treated.ends",
"means.treated.tx",
"means.treated.ol")]
colnames(endData) <- c("ends","scoreNC","scoreSR")
# add base score
endData$baseScore <- score
# split and return
ans <- relist(endData, partitioning)
rownames(ans) <- IRanges::CharacterList(RNAmodR:::.seqs_rl_strand(ranges(x)))
ans
}
#' @rdname ModAlkAnilineSeq-functions
#' @export
setMethod(
f = "aggregateData",
signature = signature(x = "ModAlkAnilineSeq"),
definition =
function(x){
.aggregate_aas(x)
}
)
.get_aas_scores <- function(data){
list(score = data$scoreNC,
scoreSR = data$scoreSR)
}
.find_aas_modifications_in_data <- function(mod, letters, grl, signal,
minScoreNC, minScoreSR,
minScoreBaseScore,
scoreOperator){
modifications <- mapply(
function(m,l,r,s){
pos <- rownames(m)
m <- m[!is.na(m$scoreNC) &
!is.na(m$scoreSR) &
!is.na(m$ends),,drop=FALSE]
if(nrow(m) == 0L) return(NULL)
m <- m[s,,drop=FALSE]
if(nrow(m) == 0L) return(NULL)
m <- m[mapply(Reduce,
rep(scoreOperator,nrow(m)),
m$scoreNC >= minScoreNC,
m$scoreSR >= minScoreSR,
m$baseScore >= minScoreBaseScore),,drop=FALSE]
if(nrow(m) == 0L) return(NULL)
l <- l[which(pos %in% rownames(m))]
if(!any(l %in% c("G","C","U"))){
return(NULL)
}
ansm7G <- RNAmodR:::constructModRanges(
r,
m[l == "G",],
modType = "m7G",
scoreFun = RNAmodR.AlkAnilineSeq:::.get_aas_scores,
source = "RNAmodR.AlkAnilineSeq",
type = "RNAMOD")
ansD <- RNAmodR:::constructModRanges(
r,
m[l == "U",],
modType = "D",
scoreFun = RNAmodR.AlkAnilineSeq:::.get_aas_scores,
source = "RNAmodR.AlkAnilineSeq",
type = "RNAMOD")
ansm3C <- RNAmodR:::constructModRanges(
r,
m[l == "C",],
modType = "m3C",
scoreFun = RNAmodR.AlkAnilineSeq:::.get_aas_scores,
source = "RNAmodR.AlkAnilineSeq",
type = "RNAMOD")
ans <- unlist(GenomicRanges::GRangesList(list(ansm7G,ansD,ansm3C)))
ans <- ans[order(BiocGenerics::start(ans))]
ans
},
mod,
letters,
grl,
signal)
f <- !vapply(modifications, is.null, logical(1))
modifications <- mapply(
function(m,name){
m$Parent <- rep(name,length(m))
m
},
modifications[f],
names(grl)[f],
SIMPLIFY = FALSE)
modifications <- GenomicRanges::GRangesList(modifications)
modifications
}
.find_aas_modifications <- function(x){
if(!hasAggregateData(x)){
stop("Something went wrong.")
}
grl <- ranges(x)
letters <- IRanges::CharacterList(strsplit(as.character(sequences(x)),""))
# get the aggregate data
mod <- getAggregateData(x)
# set up some arguments
minSignal <- settings(x,"minSignal")
minScoreNC <- settings(x,"minScoreNC")
minScoreSR <- settings(x,"minScoreSR")
minScoreBaseScore <- settings(x,"minScoreBaseScore")
scoreOperator <- settings(x,"scoreOperator")
# construct logical vector for passing the minSignal threshold
signal <- mod[,"ends"] >= minSignal
# find modifications
modifications <- .find_aas_modifications_in_data(mod, letters, grl, signal,
minScoreNC, minScoreSR,
minScoreBaseScore,
scoreOperator)
unname(unlist(modifications))
}
#' @rdname ModAlkAnilineSeq-functions
#' @export
setMethod("findMod",
signature = c(x = "ModAlkAnilineSeq"),
function(x){
.find_aas_modifications(x)
}
)
# ModSetAlkAnilineSeq ----------------------------------------------------------
#' @rdname ModAlkAnilineSeq
#' @export
setClass("ModSetAlkAnilineSeq",
contains = "ModifierSet",
prototype = list(elementType = "ModAlkAnilineSeq"))
#' @rdname ModAlkAnilineSeq
#' @export
ModSetAlkAnilineSeq <- function(x, annotation = NA, sequences = NA,
seqinfo = NA, ...){
RNAmodR::ModifierSet("ModAlkAnilineSeq", x, annotation = annotation,
sequences = sequences, seqinfo = seqinfo, ...)
}
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Defines functions ModSetAlkAnilineSeq .find_aas_modifications .find_aas_modifications_in_data .get_aas_scores .aggregate_aas .apply_Np1_offset .selected_base_score .norm_aas_args ModAlkAnilineSeq
Documented in ModAlkAnilineSeq ModSetAlkAnilineSeq
#' @include RNAmodR.AlkAnilineSeq.R
NULL
#' @name ModAlkAnilineSeq
#' @aliases AlkAnilineSeq ModAlkAnilineSeq ModSetAlkAnilineSeq
#'
#' @author Felix G.M. Ernst [aut]
#'
#' @title ModAlkAnilineSeq class to analyze AlkAnilineSeq data
#'
#' @description
#' 7-methyl guanosine (m7G), 3-methyl cytidine (m3C) and Dihydrouridine (D)
#' are commonly found in rRNA and tRNA and can be detected classically by
#' primer extension analysis. However, since the modifications do not interfere
#' with Watson-Crick base pairing, a specific chemical treatment is employed
#' to cause strand breaks specifically at the modified positions.
#'
#' This classical protocol was converted to a high throughput sequencing
#' method call AlkAnilineSeq and allows modified position be detected by an
#' accumulation of 5'-ends at the N+1 position. Since the identify of the
#' unmodified nucleotide is different for the three modified nucleotides, they
#' modification can be detected at the same time from the same samples.
#'
#' \code{dataType} is \code{c("NormEnd3SequenceData","PileupSequenceData")}:
#'
#' The \code{ModAlkAnilineSeq} class uses the
#' \code{\link[RNAmodR:NormEndSequenceData-class]{NormEnd5SequenceData}}
#' class to store and aggregate data along the transcripts. This includes
#' normalized values against the whole transcript (normalzed cleavage) and
#' normalized values against the overlapping reads (stop ratio), which are used
#' to score for modified positions.
#'
#' In addition the
#' \code{\link[RNAmodR:PileupSequenceData-class]{PileupSequenceData}} class is
#' used as well, to check, whether the base is can be called according to the
#' expected sequence identity.
#'
#' Only samples named \code{treated} are used for this analysis. Normalization
#' to untreated samples is currently not used.
#'
#' @param x the input which can be of the different types depending on whether
#' a \code{ModRiboMethSeq} or a \code{ModSetRiboMethSeq} object is to be
#' constructed. For more information have a look at the documentation of
#' the \code{\link[RNAmodR:Modifier-class]{Modifier}} and
#' \code{\link[RNAmodR:ModifierSet-class]{ModifierSet}} classes.
#' @param annotation annotation data, which must match the information contained
#' in the BAM files. This is parameter is only required if \code{x} if not a
#' \code{Modifier} object.
#' @param sequences sequences matching the target sequences the reads were
#' mapped onto. This must match the information contained in the BAM files. This
#' is parameter is only required if \code{x} if not a \code{Modifier} object.
#' @param seqinfo An optional \code{\link[GenomeInfoDb:Seqinfo-class]{Seqinfo}}
#' argument or character vector, which can be coerced to one, to subset the
#' sequences to be analyzed on a per chromosome basis.
#' @param ... Optional arguments overwriting default values, which are
#' \itemize{
#' \item{minLength:} {The minimal read length to be used for the analysis
#' (default: \code{minLength = 9L}).}
#' \item{minSignal:} {The minimal signal at the position as integer value
#' (default: \code{minSignal = 10L}). If the reaction is very specific a lower
#' value may need to be used}
#' \item{minScoreNC:} {minimum for score (normalized cleavage) to identify m7G,
#' m3C and D positions de novo (default: \code{minScoreNC = 50L})}
#' \item{minScoreSR:} {minimum for score (stop ration) to identify m7G, m3C and D
#' positions de novo (default: \code{minScoreSR = 0.5})}
#' \item{minScoreBaseScore:} {minimum score for base calling (0.0-1.0)
#' (default: \code{minScoreSR = 0.9})}
#' \item{scoreOperator:} {how the minimal score should be used as logical
#' operator. "&" requires all minimal values to be exceeded, whereas "|" detects
#' positions, if at least one minimal values is exceeded (default:
#' \code{scoreOperator = "&"}).}
#' \item{other arguments} {which are passed on to
#' \code{\link[RNAmodR:EndSequenceData-class]{End5SequenceData}}}
#' }
#'
#' @return a \code{ModAlkAnilineSeq} or \code{ModSetAlkAnilineSeq} object
#'
#' @references
#' - Marchand V, Ayadi L, __Ernst FGM__, Hertler J, Bourguignon-Igel V,
#' Galvanin A, Kotter A, Helm M, __Lafontaine DLJ__, Motorin Y (2018):
#' "AlkAniline-Seq: Profiling of m7 G and m3 C RNA Modifications at Single
#' Nucleotide Resolution." Angewandte Chemie (International ed. in English) 57
#' (51), P. 16785–16790. DOI:
#' \href{https://doi.org/10.1002/anie.201810946}{10.1002/anie.201810946}.
#'
#' @examples
#' library(RNAmodR.Data)
#' library(rtracklayer)
#' annotation <- GFF3File(RNAmodR.Data.example.AAS.gff3())
#' sequences <- RNAmodR.Data.example.AAS.fasta()
#' files <- list("wt" = c(treated = RNAmodR.Data.example.wt.1()),
#' "Bud23del" = c(treated = RNAmodR.Data.example.bud23.1()),
#' "Trm8del" = c(treated = RNAmodR.Data.example.trm8.1()))
#' # Creating a Modifier object of type ModRiboMethSeq
#' maas <- ModAlkAnilineSeq(files[[1]], annotation = annotation,
#' sequences = sequences)
#' # Creating a ModifierSet object of type ModSetRiboMethSeq
#' msaas <- ModSetAlkAnilineSeq(files, annotation = annotation,
#' sequences = sequences)
NULL
#' @rdname ModAlkAnilineSeq
#' @export
setClass("ModAlkAnilineSeq",
contains = c("RNAModifier"),
prototype = list(mod = c("m7G","m3C","D"),
score = "scoreNC",
dataType = c("NormEnd5SequenceData",
"PileupSequenceData")))
# constructors -----------------------------------------------------------------
#' @rdname ModAlkAnilineSeq
#' @export
ModAlkAnilineSeq <- function(x, annotation = NA, sequences = NA, seqinfo = NA,
...){
RNAmodR::Modifier("ModAlkAnilineSeq", x = x, annotation = annotation,
sequences = sequences, seqinfo = seqinfo, ...)
}
# settings ---------------------------------------------------------------------
#' @name ModAlkAnilineSeq-functions
#' @aliases aggregate modify settings plotData plotDataByCoord
#'
#' @title Functions for ModAlkAnilineSeq
#'
#' @description
#' All of the functions of \code{\link[RNAmodR:Modifier-class]{Modifier}} and
#' the \code{\link[RNAmodR:ModifierSet-class]{ModifierSet}} classes are
#' inherited by the \code{ModAlkAnilineSeq} and \code{ModSetAlkAnilineSeq}
#' classes.
#'
#' @param x a \code{\link[RNAmodR:Modifier-class]{Modifier}} or a
#' \code{\link[RNAmodR:ModifierSet-class]{ModifierSet}} object. For more
#' details see also the man pages for the functions mentioned below.
#' @param value See \code{\link[RNAmodR:Modifier-class]{settings}}
#' @param coord,name,from,to,type,window.size,... See
#' \code{\link[RNAmodR:plotData]{plotData}}.
#'
#' @details
#' \code{ModAlkAnilineSeq} specific arguments for \link{plotData}:
#' \itemize{
#' \item{\code{colour} - }{a named character vector of \code{length = 4}
#' for the colours of the individual histograms. The names are expected to be
#' \code{c("scoreNC","scoreSR")}}
#' }
#'
#' @return
#' \itemize{
#' \item{\code{settings}} {See
#' \code{\link[RNAmodR:Modifier-functions]{settings}}.}
#' \item{\code{aggregate}} {See \code{\link[RNAmodR:aggregate]{aggregate}}.}
#' \item{\code{modify}} {See \code{\link[RNAmodR:modify]{modify}}.}
#' \item{\code{getDataTrack}} {a list of
#' \code{\link[Gviz:DataTrack-class]{DataTrack}} object.}
#' \item{\code{plotData}} {See
#' \code{\link[RNAmodR:plotData]{plotDataByCoord}}.}
#' \item{\code{plotDataByCoord}} {See
#' \code{\link[RNAmodR:plotData]{plotDataByCoord}}.}
#' }
#'
#' @importMethodsFrom RNAmodR modify aggregate settings plotData
#' plotDataByCoord
#'
#' @examples
#' data(msaas,package="RNAmodR.AlkAnilineSeq")
#' maas <- msaas[[1]]
#' settings(maas)
#' aggregate(maas)
#' modify(maas)
#' getDataTrack(maas, "1", mainScore(maas))
NULL
.not_integer_bigger_than_zero <- RNAmodR:::.not_integer_bigger_than_zero
.not_numeric_bigger_zero <- RNAmodR:::.not_numeric_bigger_zero
.not_numeric_between_0_1 <- RNAmodR:::.not_numeric_between_0_1
.not_logical_operator <- RNAmodR:::.not_logical_operator
.ModAlkAnilineSeq_settings <- data.frame(
variable = c("minLength",
"minSignal",
"minScoreNC",
"minScoreSR",
"minScoreBaseScore",
"scoreOperator"),
testFUN = c(".not_integer_bigger_than_zero",
".not_integer_bigger_than_zero",
".not_numeric_bigger_zero",
".not_numeric_between_0_1",
".not_numeric_between_0_1",
".not_logical_operator"),
errorValue = c(TRUE,
TRUE,
TRUE,
TRUE,
TRUE,
TRUE),
errorMessage = c("'minQuality' must be integer with a value higher than 0.",
"'minSignal' must be integer with a value higher than 0.",
"'minScoreNC' must be numeric with a value higher than 0.",
"'minScoreSR' must be numeric with a value between 0 and 1.",
"'minScoreBaseScore' must be numeric with a value between 0 and 1.",
"'scoreOperator' must be either '|' or '&'."),
stringsAsFactors = FALSE)
.norm_aas_args <- function(input){
minLength <- 9L # for all scores
minSignal <- 10L # for all scores
minScoreNC <- 50L # for score normalized cleavage
minScoreSR <- 0.50 # for score stop ratio
minScoreBaseScore <- 0.9 # for base scoring
scoreOperator <- "&"
args <- RNAmodR:::.norm_settings(input, .ModAlkAnilineSeq_settings, minLength,
minSignal, minScoreNC, minScoreSR,
minScoreBaseScore, scoreOperator)
args <- c(RNAmodR:::.norm_Modifier_settings(input),
args)
args
}
#' @rdname ModAlkAnilineSeq-functions
#' @export
setReplaceMethod(f = "settings",
signature = signature(x = "ModAlkAnilineSeq"),
definition = function(x, value){
x <- callNextMethod()
value <- .norm_aas_args(value)
x@settings[names(value)] <- unname(value)
x
})
# functions --------------------------------------------------------------------
.selected_base_score <- function(data,seq){
seq <- IRanges::CharacterList(strsplit(as.character(seq),""))
data <- data@unlistData
# the order of baseSelect and baseColumns must be compatible
# "conversion" T to U is performed with this
baseSelect <- S4Vectors::DataFrame("G" = unlist(seq) == "G",
"A" = unlist(seq) == "A",
"U" = unlist(seq) == "U",
"C" = unlist(seq) == "C")
baseColumns <- which(colnames(data) %in% c("means.treated.G",
"means.treated.A",
"means.treated.T",
"means.treated.C"))
baseData <- as(data[,baseColumns],"NumericList")
baseSelect <- as(baseSelect,"LogicalList")
tmpBaseValues <- unname(baseData)[unname(baseSelect)]
baseValues <- rep(0,nrow(data))
baseValues[which(baseSelect[[1]])] <- tmpBaseValues[[1]]
baseValues[which(baseSelect[[2]])] <- tmpBaseValues[[2]]
baseValues[which(baseSelect[[3]])] <- tmpBaseValues[[3]]
baseValues[which(baseSelect[[4]])] <- tmpBaseValues[[4]]
baseValues[is.na(baseValues)] <- 0
baseValues[is.infinite(baseValues)] <- 0
baseValues
}
.apply_Np1_offset <- function(x){
offsetAdd <- S4Vectors::DataFrame(as.list(rep(0,ncol(x@unlistData))))
colnames(offsetAdd) <- colnames(unlist(x))
x_rownames <- rownames(x)
x <- x[IRanges::IntegerList(Map(seq.int,2L,lengths(x)))]
x_offsetAdd <- IRanges::SplitDataFrameList(rep(list(offsetAdd),length(x)))
x <- rbind(x,x_offsetAdd)
rownames(x) <- x_rownames
x
}
.aggregate_aas <- function(x){
mod <- aggregate(sequenceData(x), condition = "Treated")
if(is.null(names(mod))){
names(mod) <- vapply(mod,class,character(1))
}
# get the NormEnd5SequenceData
# shift each result one position upstream, since the signal has an N+1 offset
endData <- .apply_Np1_offset(mod[["NormEnd5SequenceData"]])
# get the PileupSequenceData
# calculate base score
pileupData <- mod[["PileupSequenceData"]]
score <- .selected_base_score(pileupData,sequences(x))
# subset to columns needed
partitioning <- IRanges::PartitioningByEnd(endData)
endData <- unlist(endData)[,c("means.treated.ends",
"means.treated.tx",
"means.treated.ol")]
colnames(endData) <- c("ends","scoreNC","scoreSR")
# add base score
endData$baseScore <- score
# split and return
ans <- relist(endData, partitioning)
rownames(ans) <- IRanges::CharacterList(RNAmodR:::.seqs_rl_strand(ranges(x)))
ans
}
#' @rdname ModAlkAnilineSeq-functions
#' @export
setMethod(
f = "aggregateData",
signature = signature(x = "ModAlkAnilineSeq"),
definition =
function(x){
.aggregate_aas(x)
}
)
.get_aas_scores <- function(data){
list(score = data$scoreNC,
scoreSR = data$scoreSR)
}
.find_aas_modifications_in_data <- function(mod, letters, grl, signal,
minScoreNC, minScoreSR,
minScoreBaseScore,
scoreOperator){
modifications <- mapply(
function(m,l,r,s){
pos <- rownames(m)
m <- m[!is.na(m$scoreNC) &
!is.na(m$scoreSR) &
!is.na(m$ends),,drop=FALSE]
if(nrow(m) == 0L) return(NULL)
m <- m[s,,drop=FALSE]
if(nrow(m) == 0L) return(NULL)
m <- m[mapply(Reduce,
rep(scoreOperator,nrow(m)),
m$scoreNC >= minScoreNC,
m$scoreSR >= minScoreSR,
m$baseScore >= minScoreBaseScore),,drop=FALSE]
if(nrow(m) == 0L) return(NULL)
l <- l[which(pos %in% rownames(m))]
if(!any(l %in% c("G","C","U"))){
return(NULL)
}
ansm7G <- RNAmodR:::constructModRanges(
r,
m[l == "G",],
modType = "m7G",
scoreFun = RNAmodR.AlkAnilineSeq:::.get_aas_scores,
source = "RNAmodR.AlkAnilineSeq",
type = "RNAMOD")
ansD <- RNAmodR:::constructModRanges(
r,
m[l == "U",],
modType = "D",
scoreFun = RNAmodR.AlkAnilineSeq:::.get_aas_scores,
source = "RNAmodR.AlkAnilineSeq",
type = "RNAMOD")
ansm3C <- RNAmodR:::constructModRanges(
r,
m[l == "C",],
modType = "m3C",
scoreFun = RNAmodR.AlkAnilineSeq:::.get_aas_scores,
source = "RNAmodR.AlkAnilineSeq",
type = "RNAMOD")
ans <- unlist(GenomicRanges::GRangesList(list(ansm7G,ansD,ansm3C)))
ans <- ans[order(BiocGenerics::start(ans))]
ans
},
mod,
letters,
grl,
signal)
f <- !vapply(modifications, is.null, logical(1))
modifications <- mapply(
function(m,name){
m$Parent <- rep(name,length(m))
m
},
modifications[f],
names(grl)[f],
SIMPLIFY = FALSE)
modifications <- GenomicRanges::GRangesList(modifications)
modifications
}
.find_aas_modifications <- function(x){
if(!hasAggregateData(x)){
stop("Something went wrong.")
}
grl <- ranges(x)
letters <- IRanges::CharacterList(strsplit(as.character(sequences(x)),""))
# get the aggregate data
mod <- getAggregateData(x)
# set up some arguments
minSignal <- settings(x,"minSignal")
minScoreNC <- settings(x,"minScoreNC")
minScoreSR <- settings(x,"minScoreSR")
minScoreBaseScore <- settings(x,"minScoreBaseScore")
scoreOperator <- settings(x,"scoreOperator")
# construct logical vector for passing the minSignal threshold
signal <- mod[,"ends"] >= minSignal
# find modifications
modifications <- .find_aas_modifications_in_data(mod, letters, grl, signal,
minScoreNC, minScoreSR,
minScoreBaseScore,
scoreOperator)
unname(unlist(modifications))
}
#' @rdname ModAlkAnilineSeq-functions
#' @export
setMethod("findMod",
signature = c(x = "ModAlkAnilineSeq"),
function(x){
.find_aas_modifications(x)
}
)
# ModSetAlkAnilineSeq ----------------------------------------------------------
#' @rdname ModAlkAnilineSeq
#' @export
setClass("ModSetAlkAnilineSeq",
contains = "ModifierSet",
prototype = list(elementType = "ModAlkAnilineSeq"))
#' @rdname ModAlkAnilineSeq
#' @export
ModSetAlkAnilineSeq <- function(x, annotation = NA, sequences = NA,
seqinfo = NA, ...){
RNAmodR::ModifierSet("ModAlkAnilineSeq", x, annotation = annotation,
sequences = sequences, seqinfo = seqinfo, ...)
}
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