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R/Fastq.R
In alakazam: Immunoglobulin Clonal Lineage and Diversity Analysis
Defines functions
getPositionQuality
maskPositionsByQuality
sequenceAlignmentQuality
calcSequenceAlignmentQuality
readFastqDb
Documented in
getPositionQuality
maskPositionsByQuality
readFastqDb
#' Load sequencing quality scores from a FASTQ file
#'
#' \code{readFastqDb} adds the sequencing quality scores to a data.frame
#' from a FASTQ file. Matching is done by `sequence_id`.
#'
#' @param data \code{data.frame} containing sequence data.
#' @param fastq_file path to the fastq file
#' @param quality_offset offset value to be used by ape::read.fastq. It is
#' the value to be added to the quality scores
#' (the default -33 applies to the Sanger format and
#' should work for most recent FASTQ files).
#' @param header FASTQ file header format; one of \code{"presto"} or
#' \code{"asis"}. Use \code{"presto"} to specify
#' that the fastq file headers are using the pRESTO
#' format and can be parsed to extract
#' the \code{sequence_id}. Use \code{"asis"} to skip
#' any processing and use the sequence names as they are.
#' @param sequence_id column in \code{data} that contains sequence
#' identifiers to be matched to sequence identifiers in
#' \code{fastq_file}.
#' @param sequence column in \code{data} that contains sequence data.
#' @param sequence_alignment column in \code{data} that contains IMGT aligned sequence data.
#' @param v_cigar column in \code{data} that contains CIGAR
#' strings for the V gene alignments.
#' @param d_cigar column in \code{data} that contains CIGAR
#' strings for the D gene alignments.
#' @param j_cigar column in \code{data} that contains CIGAR
#' strings for the J gene alignments.
#' @param np1_length column in \code{data} that contains the number
#' of nucleotides between the V gene and first D gene
#' alignments or between the V gene and J gene alignments.
#' @param np2_length column in \code{data} that contains the number
#' of nucleotides between either the first D gene and J
#' gene alignments or the first D gene and second D gene
#' alignments.
#' @param v_sequence_end column in \code{data} that contains the
#' end position of the V gene in \code{sequence}.
#' @param d_sequence_end column in \code{data} that contains the
#' end position of the D gene in \code{sequence}.
#' @param style how the sequencing quality should be returned;
#' one of \code{"num"}, \code{"phred"}, or \code{"both"}.
#' Specify \code{"num"} to store the quality scores as strings of
#' comma separated numeric values. Use \code{"phred"} to have
#' the function return the scores as Phred (ASCII) scores.
#' Use \code{"both"} to retrieve both.
#' @param quality_sequence specify \code{TRUE} to keep the quality scores for
#' \code{sequence}. If false, only the quality score
#' for \code{sequence_alignment} will be added to \code{data}.
#'
#' @return Modified \code{data} with additional fields:
#' \enumerate{
#' \item \code{quality_alignment}: A character vector with ASCII Phred
#' scores for \code{sequence_alignment}.
#' \item \code{quality_alignment_num}: A character vector, with comma separated
#' numerical quality values for each
#' position in \code{sequence_alignment}.
#' \item \code{quality}: A character vector with ASCII Phred
#' scores for \code{sequence}.
#' \item \code{quality_num}: A character vector, with comma separated
#' numerical quality values for each
#' position in \code{sequence}.
#' }
#' @seealso \link{maskPositionsByQuality} and \link{getPositionQuality}
#'
#' @examples
#' db <- airr::read_rearrangement(system.file("extdata", "example_quality.tsv", package="alakazam"))
#' fastq_file <- system.file("extdata", "example_quality.fastq", package="alakazam")
#' db <- readFastqDb(db, fastq_file, quality_offset=-33)
#'
#' @export
readFastqDb <- function(data, fastq_file, quality_offset=-33,
header=c("presto", "asis"),
sequence_id="sequence_id",
sequence="sequence",
sequence_alignment="sequence_alignment",
v_cigar="v_cigar",
d_cigar="d_cigar",
j_cigar="j_cigar",
np1_length="np1_length",
np2_length="np2_length",
v_sequence_end="v_sequence_end",
d_sequence_end="d_sequence_end",
style=c("num", "ascii", "both"),
quality_sequence=FALSE) {
check_cols <- c(sequence_id,
sequence,
sequence_alignment,
v_cigar, d_cigar, j_cigar,
np1_length, np2_length,
v_sequence_end, d_sequence_end)
alakazam::checkColumns(data, check_cols)
style <- match.arg(style)
# Process the fastq file
header <- match.arg(header)
fastq <- ape::read.fastq(fastq_file, offset=quality_offset) #default: -33 (pRESTO)
fastq_db <- data.frame(
"quality_num"=as.vector(sapply(attr(fastq, "QUAL"), paste0, collapse=",")),
stringsAsFactors = F)
fastq_db$quality <- sapply(fastq_db[["quality_num"]],
function(qual, quality_offset) {
paste0(sapply(strsplit(qual, ",")[[1]], function(x,quality_offset) {
y <- as.numeric(x) - quality_offset
rawToChar(as.raw(y))
},quality_offset), sep="",collapse="")
}, quality_offset)
fastq_db[[sequence_id]] <- attr(fastq, "names")
if (header=="presto") {
fastq_db[[sequence_id]] <- gsub("\\|.+","",attr(fastq, "names"))
}
# Merge
by <- sequence_id
names(by) <- sequence_id
data <- data %>%
left_join(fastq_db, by=by)
data <- sequenceAlignmentQuality(data,
sequence=sequence,
sequence_id=sequence_id,
sequence_alignment=sequence_alignment,
quality="quality",
quality_num="quality_num",
v_cigar=v_cigar,
d_cigar=d_cigar,
j_cigar=j_cigar,
np1_length=np1_length,
np2_length=np2_length,
v_sequence_end=v_sequence_end,
d_sequence_end=d_sequence_end,
raw=FALSE)
if (!quality_sequence) {
data[['quality']] <- NULL
data[['quality_num']] <- NULL
}
if (style != "both") {
if (style == "phred") {
data[['quality_alignment_num']] <- NULL
} else {
data[['quality_alignment']] <- NULL
}
}
data
}
# Thanks!:
# https://drive5.com/usearch/manual/cigar.html &
# https://jef.works/blog/2017/03/28/CIGAR-strings-for-dummies/
# M Match (alignment column containing two letters). This could contain two
# letters (mismatch) or two identical letters. USEARCH generates CIGAR strings
# containing Ms rather than X's and ='s (see below).
# N Alignment gap Next x positions on ref don’t match (Deletion in query?)
# D Deletion (gap in the target sequence).
# I Insertion (gap in the query sequence).
# S Segment of the query sequence that does not appear in the alignment.
# This is used with soft clipping, where the full-length query sequence
# is given (field 10 in the SAM record). In this case, S operations specify
# segments at the start and/or end of the query that do not appear in a
# local alignment.
# H Segment of the query sequence that does not appear in the alignment.
# This is used with hard clipping, where only the aligned segment of the
# query sequences is given (field 10 in the SAM record). In this case, H
# operations specify segments at the start and/or end of the query that
# do not appear in the SAM record.
# = Alignment column containing two identical letters. USEARCH can read
# CIGAR strings using this operation, but does not generate them.
# X Alignment column containing a mismatch, i.e. two different letters.
# USEARCH can read CIGAR strings using this operation, but does not generate them.
# Tested with IgBlast output, not with IMGT
calcSequenceAlignmentQuality <- function(sequence_db,
sequence="sequence",
sequence_id="sequence_id",
sequence_alignment="sequence_alignment",
quality="quality",
quality_num="quality_num",
v_cigar="v_cigar",
d_cigar="d_cigar",
j_cigar="j_cigar",
np1_length="np1_length",
np2_length="np2_length",
v_sequence_end="v_sequence_end",
d_sequence_end="d_sequence_end",
raw=FALSE) {
# query sequence
sequence <- sequence_db[[sequence]]
quality_phred <- strsplit(sequence_db[[quality]],"")[[1]]
quality_num_values <- strsplit(sequence_db[[quality_num]],",")[[1]]
v_cigar <- sequence_db[[v_cigar]]
vd_pseudo_cigar <- NA
if (!is.na(sequence_db[[np1_length]])) {
if (sequence_db[[np1_length]]>0) {
vd_pseudo_cigar <- paste0(sequence_db[[v_sequence_end]],"S",sequence_db[[np1_length]],"X")
}
}
d_cigar <- sequence_db[[d_cigar]]
dj_pseudo_cigar <- NA
if (!is.na(sequence_db[[np2_length]])) {
if (sequence_db[[np2_length]]>0){
dj_pseudo_cigar <- paste0(sequence_db[[d_sequence_end]],"S",sequence_db[[np2_length]],"X")
}
}
j_cigar <- sequence_db[[j_cigar]]
cigars <- c(v_cigar, vd_pseudo_cigar, d_cigar, dj_pseudo_cigar, j_cigar)
cigars <- cigars[!is.na(cigars)]
ranges <- bind_rows(lapply(cigars, function(cigar) {
ops <- GenomicAlignments::explodeCigarOps(cigar)[[1]]
lengths <- GenomicAlignments::explodeCigarOpLengths(cigar)[[1]]
keep <- ops %in% c("N", "I") == F
ops <- ops[keep]
lengths <- lengths[keep]
ranges <- data.frame(
"start"=rep(NA, length(ops)),
"end"=NA,
"width"=lengths,
"operator"=ops,
stringsAsFactors = F)
ranges[['start']][1] <- 1
for (i in 1:nrow(ranges)) {
if (ranges[['operator']][i] %in% c("S","=","X","D")) {
ranges[['end']][i] <- ranges[['start']][i]+ranges[['width']][i]-1
}
if (i+1<=nrow(ranges)) {
ranges[['start']][i+1] <- ranges[['end']][i]+1
}
}
ranges <- ranges %>%
filter(!!rlang::sym("operator") %in% c("S","D") == FALSE)
ranges
}))
iranges <- IRanges(start=ranges[['start']], end=ranges[['end']], width=ranges[['width']])
reconstruced_sequence_alignment <- extractAt(BString(sequence), iranges)
reconstruced_sequence_alignment <- paste0(sapply(reconstruced_sequence_alignment, toString), collapse="")
positions <- unlist(sapply(1:nrow(ranges), function(i) { ranges$start[i]:ranges$end[i]}))
quality_df <- data.frame(
"reconstructed_sequence_alignment"=paste0(sapply(reconstruced_sequence_alignment, toString),collapse=""),
"sequence_position"=positions,
"sequence_alignment_position"=NA,
stringsAsFactors = F
) %>%
mutate (
!!rlang::sym(quality) := quality_phred[positions],
!!rlang::sym(quality_num) := as.numeric(quality_num_values)[positions],
!!rlang::sym(sequence_id) := sequence_db[[sequence_id]])
# Sanity check. Just to be sure reconstruction is working correctly,
# and be sure I will later transfer the quality scores correctly
sequence_alignment <- sequence_db[[sequence_alignment]]
expected <- gsub("[\\.-]","",sequence_alignment)
if (reconstruced_sequence_alignment != expected) {
stop("Reconstructed sequence_alignment from cigar doesn't match db sequence_alignment.")
}
# map position numbering: sequence input positions <--> aligned positions
nt_aln <- strsplit(sequence_alignment,"")[[1]]
for ( aln_position in 1:length(nt_aln)) {
if (nt_aln[aln_position] %in% c(".","-") == FALSE ) {
pos <- sum(nt_aln[1:aln_position] %in% c(".","-") == F)
quality_df[['sequence_alignment_position']][pos] <- aln_position
quality_df[['sequence_alignment_nt']][pos] <- nt_aln[aln_position]
}
}
if (raw) {
quality_df %>%
select(-!!rlang::sym("reconstructed_sequence_alignment"))
} else {
qual_num <- rep(NA, length(nt_aln))
qual_num[quality_df[['sequence_alignment_position']]] <- quality_df[[quality_num]]
qual_num <- paste0(qual_num, sep="", collapse=",")
qual_phred <- rep(" ", length(nt_aln))
qual_phred[quality_df[['sequence_alignment_position']]] <- quality_df[[quality]]
qual_phred <- paste0(qual_phred, sep="", collapse="")
ret <- data.frame(
"quality_alignment_num"=qual_num,
"quality_alignment"=qual_phred,
stringsAsFactors = F
) %>%
mutate(!!rlang::sym(sequence_id) := sequence_db[[sequence_id]])
ret
}
}
# Retrieve sequencing quality scores from tabular data
#
# \code{sequenceAlignmentQuality} is used internally by \code{readFastqDb} to
# process the sequencing quality scores loaded from a \code{fastq} file.
#
# Once a repertoire \code{data.frame} has been processed with \link{readFastqDb} and
# contains the fields \code{quality} and \code{quality_num},
# \code{sequenceAlignmentQuality} can be used to retrieve the quality scores
# from the already present field \code{quality_num}, without requiring
# again the \code{fastq} file, and report them as a \code{data.frame} with sequencing
# qualities per position, not as a string. This is done setting \code{raw=TRUE}.
# This \code{data.frame} with qualities per position can be used to generate figures,
# for example.
#
# @param data \code{data.frame} containing sequence data.
# @param sequence_id column in \code{data} that contains sequence
# identifiers to be matched to sequence identifiers in
# \code{fastq_file}.
# @param sequence column in \code{data} that contains sequence data.
# @param sequence_alignment column in \code{data} that contains
# IMGT aligned sequence data.
# @param quality column in \code{data} that contains
# sequencing quality as Phred scores.
# @param quality_num column in \code{data} that contains
# sequencing quality as a comma separated string.
# @param v_cigar column in \code{data} that contains CIGAR
# strings for the V gene alignments.
# @param d_cigar column in \code{data} that contains CIGAR
# strings for the D gene alignments.
# @param j_cigar column in \code{data} that contains CIGAR
# strings for the J gene alignments.
# @param np1_length column in \code{data} that contains the number
# of nucleotides between the V gene and first D gene
# alignments or between the V gene and J gene alignments.
# @param np2_length column in \code{data} that contains the number
# of nucleotides between either the first D gene and J
# gene alignments or the first D gene and second D gene
# alignments.
# @param v_sequence_end column in \code{data} that contains the
# end position of the V gene in \code{sequence}.
# @param d_sequence_end column in \code{data} that contains the
# end position of the D gene in \code{sequence}.
# @param raw specify how the sequencing quality should be returned.
# If \code{TRUE}, return a \code{data.frame} with
# quality information per position, where each row is
# a position. This \code{data.frame} has columns
# "sequence_position", "sequence_alignment_position",
# "quality", "quality_num", "sequence_id"
# and "sequence_alignment_nt" If \code{FALSE}, for each sequence,
# concatenate the position qualities in a string, and the
# quality information to \code{data}
sequenceAlignmentQuality <- function(data,
sequence_id="sequence_id",
sequence="sequence",
sequence_alignment="sequence_alignment",
quality="quality",
quality_num="quality_num",
v_cigar="v_cigar",
d_cigar="d_cigar",
j_cigar="j_cigar",
np1_length="np1_length",
np2_length="np2_length",
v_sequence_end="v_sequence_end",
d_sequence_end="d_sequence_end",
raw=FALSE) {
pb <- progressBar(nrow(data))
qual <- bind_rows(lapply(1:nrow(data),function(i) {
pb$tick()
calcSequenceAlignmentQuality(data[i,],
sequence=sequence,
sequence_id=sequence_id,
sequence_alignment=sequence_alignment,
quality=quality,
quality_num=quality_num,
v_cigar=v_cigar,
d_cigar=d_cigar,
j_cigar=j_cigar,
np1_length=np1_length,
np2_length=np2_length,
v_sequence_end=v_sequence_end,
d_sequence_end=d_sequence_end,
raw=raw)
}))
if (raw) {
qual
} else {
data %>%
dplyr::left_join(qual, by=sequence_id)
}
}
#' Mask sequence positions with low quality
#'
#' \code{maskPositionsByQuality} will replace positions that
#' have a sequencing quality score lower that \code{min_quality} with an
#' \code{"N"} character.
#'
#'
#' @param data \code{data.frame} containing sequence data.
#' @param min_quality minimum quality score. Positions with sequencing quality
#' less than \code{min_qual} will be masked.
#' @param sequence column in \code{data} with sequence data to be masked.
#' @param quality_num column in \code{data} with quality scores (a
#' string of numeric values, comma separated) that can
#' be used to mask \code{sequence}.
#'
#' @return Modified \code{data} data.frame with an additional field containing
#' quality masked sequences. The name of this field is created
#' concatenating the \code{sequence} name and \code{"_masked"}.
#'
#' @seealso \link{readFastqDb} and \link{getPositionQuality}
#'
#' @examples
#' db <- airr::read_rearrangement(system.file("extdata", "example_quality.tsv", package="alakazam"))
#' fastq_file <- system.file("extdata", "example_quality.fastq", package="alakazam")
#' db <- readFastqDb(db, fastq_file, quality_offset=-33)
#' maskPositionsByQuality(db, min_quality=90, quality_num="quality_alignment_num")
#'
#' @export
maskPositionsByQuality <- function(data, min_quality=70,
sequence="sequence_alignment",
quality_num="quality_alignment_num") {
required_cols <- c(sequence,quality_num)
checkColumns(data, required_cols)
sequence_masked <- paste0(sequence,"_masked")
num_masked_seqs <- 0
data <- bind_rows(lapply(1:nrow(data), function(i) {
db_row <- data[i,]
seq_qual <- strsplit(db_row[[quality_num]],",")[[1]]
low_seq_qual <- which(sapply(seq_qual, function(x) {
if (x != "NA") {
as.numeric(x) < min_quality
} else {
NA
}
}, USE.NAMES = FALSE))
if (length(low_seq_qual)>0) {
num_masked_seqs <<- num_masked_seqs + 1
seq <- strsplit(db_row[[sequence]],"")[[1]]
seq[low_seq_qual] <- "N"
seq <- paste0(seq, collapse="")
db_row[[sequence_masked]] <- seq
}
db_row
}))
message("Number of masked sequences: ", num_masked_seqs)
data
}
#' Get a data.frame with sequencing qualities per position
#'
#' \code{getPositionQuality} takes a data.frame with sequence quality scores
#' in the form of a strings of comma separated numeric values, split the quality
#' scores values by \code{","}, and returns a data.frame with the values
#' for each position.
#'
#'
#' @param data \code{data.frame} containing sequence data.
#' @param sequence_id column in \code{data} with sequence identifiers.
#' @param sequence column in \code{data} with sequence data.
#' @param quality_num column in \code{data} with quality scores (as
#' strings of numeric values, comma separated) for \code{sequence}.
#'
#' @return \code{data} with one additional field with masked sequences. The
#' name of this field is created concatenating \code{sequence}
#' and '_masked'.
#'
#' @seealso \link{readFastqDb} and \link{maskPositionsByQuality}
#'
#' @examples
#' db <- airr::read_rearrangement(system.file("extdata", "example_quality.tsv", package="alakazam"))
#' fastq_file <- system.file("extdata", "example_quality.fastq", package="alakazam")
#' db <- readFastqDb(db, fastq_file, quality_offset=-33)
#' head(getPositionQuality(db))
#
#' @export
getPositionQuality <- function(data,
sequence_id="sequence_id",
sequence="sequence_alignment",
quality_num="quality_alignment_num") {
checkColumns(data, c(sequence, quality_num))
bind_rows(lapply(1:nrow(data), function(i) {
seq_id <- data[[sequence_id]][i]
seq_len <- nchar(data[[sequence]][i])
qual_values <- as.numeric(strsplit(data[[quality_num]][i],",")[[1]])
nt <- strsplit(data[[sequence]],"")[[1]]
if (seq_len != length(qual_values)) {
stop("Different length, for sequence: ", seq_id,". seq: ", sequence, ". qual: ", quality_num)
}
data.frame(
"position"=1:seq_len, stringsAsFactors = F) %>%
mutate(!!rlang::sym(quality_num) := qual_values,
!!rlang::sym(sequence_id) := seq_id,
nt = nt)
}))
}
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Defines functions getPositionQuality maskPositionsByQuality sequenceAlignmentQuality calcSequenceAlignmentQuality readFastqDb
Documented in getPositionQuality maskPositionsByQuality readFastqDb
#' Load sequencing quality scores from a FASTQ file
#'
#' \code{readFastqDb} adds the sequencing quality scores to a data.frame
#' from a FASTQ file. Matching is done by `sequence_id`.
#'
#' @param data \code{data.frame} containing sequence data.
#' @param fastq_file path to the fastq file
#' @param quality_offset offset value to be used by ape::read.fastq. It is
#' the value to be added to the quality scores
#' (the default -33 applies to the Sanger format and
#' should work for most recent FASTQ files).
#' @param header FASTQ file header format; one of \code{"presto"} or
#' \code{"asis"}. Use \code{"presto"} to specify
#' that the fastq file headers are using the pRESTO
#' format and can be parsed to extract
#' the \code{sequence_id}. Use \code{"asis"} to skip
#' any processing and use the sequence names as they are.
#' @param sequence_id column in \code{data} that contains sequence
#' identifiers to be matched to sequence identifiers in
#' \code{fastq_file}.
#' @param sequence column in \code{data} that contains sequence data.
#' @param sequence_alignment column in \code{data} that contains IMGT aligned sequence data.
#' @param v_cigar column in \code{data} that contains CIGAR
#' strings for the V gene alignments.
#' @param d_cigar column in \code{data} that contains CIGAR
#' strings for the D gene alignments.
#' @param j_cigar column in \code{data} that contains CIGAR
#' strings for the J gene alignments.
#' @param np1_length column in \code{data} that contains the number
#' of nucleotides between the V gene and first D gene
#' alignments or between the V gene and J gene alignments.
#' @param np2_length column in \code{data} that contains the number
#' of nucleotides between either the first D gene and J
#' gene alignments or the first D gene and second D gene
#' alignments.
#' @param v_sequence_end column in \code{data} that contains the
#' end position of the V gene in \code{sequence}.
#' @param d_sequence_end column in \code{data} that contains the
#' end position of the D gene in \code{sequence}.
#' @param style how the sequencing quality should be returned;
#' one of \code{"num"}, \code{"phred"}, or \code{"both"}.
#' Specify \code{"num"} to store the quality scores as strings of
#' comma separated numeric values. Use \code{"phred"} to have
#' the function return the scores as Phred (ASCII) scores.
#' Use \code{"both"} to retrieve both.
#' @param quality_sequence specify \code{TRUE} to keep the quality scores for
#' \code{sequence}. If false, only the quality score
#' for \code{sequence_alignment} will be added to \code{data}.
#'
#' @return Modified \code{data} with additional fields:
#' \enumerate{
#' \item \code{quality_alignment}: A character vector with ASCII Phred
#' scores for \code{sequence_alignment}.
#' \item \code{quality_alignment_num}: A character vector, with comma separated
#' numerical quality values for each
#' position in \code{sequence_alignment}.
#' \item \code{quality}: A character vector with ASCII Phred
#' scores for \code{sequence}.
#' \item \code{quality_num}: A character vector, with comma separated
#' numerical quality values for each
#' position in \code{sequence}.
#' }
#' @seealso \link{maskPositionsByQuality} and \link{getPositionQuality}
#'
#' @examples
#' db <- airr::read_rearrangement(system.file("extdata", "example_quality.tsv", package="alakazam"))
#' fastq_file <- system.file("extdata", "example_quality.fastq", package="alakazam")
#' db <- readFastqDb(db, fastq_file, quality_offset=-33)
#'
#' @export
readFastqDb <- function(data, fastq_file, quality_offset=-33,
header=c("presto", "asis"),
sequence_id="sequence_id",
sequence="sequence",
sequence_alignment="sequence_alignment",
v_cigar="v_cigar",
d_cigar="d_cigar",
j_cigar="j_cigar",
np1_length="np1_length",
np2_length="np2_length",
v_sequence_end="v_sequence_end",
d_sequence_end="d_sequence_end",
style=c("num", "ascii", "both"),
quality_sequence=FALSE) {
check_cols <- c(sequence_id,
sequence,
sequence_alignment,
v_cigar, d_cigar, j_cigar,
np1_length, np2_length,
v_sequence_end, d_sequence_end)
alakazam::checkColumns(data, check_cols)
style <- match.arg(style)
# Process the fastq file
header <- match.arg(header)
fastq <- ape::read.fastq(fastq_file, offset=quality_offset) #default: -33 (pRESTO)
fastq_db <- data.frame(
"quality_num"=as.vector(sapply(attr(fastq, "QUAL"), paste0, collapse=",")),
stringsAsFactors = F)
fastq_db$quality <- sapply(fastq_db[["quality_num"]],
function(qual, quality_offset) {
paste0(sapply(strsplit(qual, ",")[[1]], function(x,quality_offset) {
y <- as.numeric(x) - quality_offset
rawToChar(as.raw(y))
},quality_offset), sep="",collapse="")
}, quality_offset)
fastq_db[[sequence_id]] <- attr(fastq, "names")
if (header=="presto") {
fastq_db[[sequence_id]] <- gsub("\\|.+","",attr(fastq, "names"))
}
# Merge
by <- sequence_id
names(by) <- sequence_id
data <- data %>%
left_join(fastq_db, by=by)
data <- sequenceAlignmentQuality(data,
sequence=sequence,
sequence_id=sequence_id,
sequence_alignment=sequence_alignment,
quality="quality",
quality_num="quality_num",
v_cigar=v_cigar,
d_cigar=d_cigar,
j_cigar=j_cigar,
np1_length=np1_length,
np2_length=np2_length,
v_sequence_end=v_sequence_end,
d_sequence_end=d_sequence_end,
raw=FALSE)
if (!quality_sequence) {
data[['quality']] <- NULL
data[['quality_num']] <- NULL
}
if (style != "both") {
if (style == "phred") {
data[['quality_alignment_num']] <- NULL
} else {
data[['quality_alignment']] <- NULL
}
}
data
}
# Thanks!:
# https://drive5.com/usearch/manual/cigar.html &
# https://jef.works/blog/2017/03/28/CIGAR-strings-for-dummies/
# M Match (alignment column containing two letters). This could contain two
# letters (mismatch) or two identical letters. USEARCH generates CIGAR strings
# containing Ms rather than X's and ='s (see below).
# N Alignment gap Next x positions on ref don’t match (Deletion in query?)
# D Deletion (gap in the target sequence).
# I Insertion (gap in the query sequence).
# S Segment of the query sequence that does not appear in the alignment.
# This is used with soft clipping, where the full-length query sequence
# is given (field 10 in the SAM record). In this case, S operations specify
# segments at the start and/or end of the query that do not appear in a
# local alignment.
# H Segment of the query sequence that does not appear in the alignment.
# This is used with hard clipping, where only the aligned segment of the
# query sequences is given (field 10 in the SAM record). In this case, H
# operations specify segments at the start and/or end of the query that
# do not appear in the SAM record.
# = Alignment column containing two identical letters. USEARCH can read
# CIGAR strings using this operation, but does not generate them.
# X Alignment column containing a mismatch, i.e. two different letters.
# USEARCH can read CIGAR strings using this operation, but does not generate them.
# Tested with IgBlast output, not with IMGT
calcSequenceAlignmentQuality <- function(sequence_db,
sequence="sequence",
sequence_id="sequence_id",
sequence_alignment="sequence_alignment",
quality="quality",
quality_num="quality_num",
v_cigar="v_cigar",
d_cigar="d_cigar",
j_cigar="j_cigar",
np1_length="np1_length",
np2_length="np2_length",
v_sequence_end="v_sequence_end",
d_sequence_end="d_sequence_end",
raw=FALSE) {
# query sequence
sequence <- sequence_db[[sequence]]
quality_phred <- strsplit(sequence_db[[quality]],"")[[1]]
quality_num_values <- strsplit(sequence_db[[quality_num]],",")[[1]]
v_cigar <- sequence_db[[v_cigar]]
vd_pseudo_cigar <- NA
if (!is.na(sequence_db[[np1_length]])) {
if (sequence_db[[np1_length]]>0) {
vd_pseudo_cigar <- paste0(sequence_db[[v_sequence_end]],"S",sequence_db[[np1_length]],"X")
}
}
d_cigar <- sequence_db[[d_cigar]]
dj_pseudo_cigar <- NA
if (!is.na(sequence_db[[np2_length]])) {
if (sequence_db[[np2_length]]>0){
dj_pseudo_cigar <- paste0(sequence_db[[d_sequence_end]],"S",sequence_db[[np2_length]],"X")
}
}
j_cigar <- sequence_db[[j_cigar]]
cigars <- c(v_cigar, vd_pseudo_cigar, d_cigar, dj_pseudo_cigar, j_cigar)
cigars <- cigars[!is.na(cigars)]
ranges <- bind_rows(lapply(cigars, function(cigar) {
ops <- GenomicAlignments::explodeCigarOps(cigar)[[1]]
lengths <- GenomicAlignments::explodeCigarOpLengths(cigar)[[1]]
keep <- ops %in% c("N", "I") == F
ops <- ops[keep]
lengths <- lengths[keep]
ranges <- data.frame(
"start"=rep(NA, length(ops)),
"end"=NA,
"width"=lengths,
"operator"=ops,
stringsAsFactors = F)
ranges[['start']][1] <- 1
for (i in 1:nrow(ranges)) {
if (ranges[['operator']][i] %in% c("S","=","X","D")) {
ranges[['end']][i] <- ranges[['start']][i]+ranges[['width']][i]-1
}
if (i+1<=nrow(ranges)) {
ranges[['start']][i+1] <- ranges[['end']][i]+1
}
}
ranges <- ranges %>%
filter(!!rlang::sym("operator") %in% c("S","D") == FALSE)
ranges
}))
iranges <- IRanges(start=ranges[['start']], end=ranges[['end']], width=ranges[['width']])
reconstruced_sequence_alignment <- extractAt(BString(sequence), iranges)
reconstruced_sequence_alignment <- paste0(sapply(reconstruced_sequence_alignment, toString), collapse="")
positions <- unlist(sapply(1:nrow(ranges), function(i) { ranges$start[i]:ranges$end[i]}))
quality_df <- data.frame(
"reconstructed_sequence_alignment"=paste0(sapply(reconstruced_sequence_alignment, toString),collapse=""),
"sequence_position"=positions,
"sequence_alignment_position"=NA,
stringsAsFactors = F
) %>%
mutate (
!!rlang::sym(quality) := quality_phred[positions],
!!rlang::sym(quality_num) := as.numeric(quality_num_values)[positions],
!!rlang::sym(sequence_id) := sequence_db[[sequence_id]])
# Sanity check. Just to be sure reconstruction is working correctly,
# and be sure I will later transfer the quality scores correctly
sequence_alignment <- sequence_db[[sequence_alignment]]
expected <- gsub("[\\.-]","",sequence_alignment)
if (reconstruced_sequence_alignment != expected) {
stop("Reconstructed sequence_alignment from cigar doesn't match db sequence_alignment.")
}
# map position numbering: sequence input positions <--> aligned positions
nt_aln <- strsplit(sequence_alignment,"")[[1]]
for ( aln_position in 1:length(nt_aln)) {
if (nt_aln[aln_position] %in% c(".","-") == FALSE ) {
pos <- sum(nt_aln[1:aln_position] %in% c(".","-") == F)
quality_df[['sequence_alignment_position']][pos] <- aln_position
quality_df[['sequence_alignment_nt']][pos] <- nt_aln[aln_position]
}
}
if (raw) {
quality_df %>%
select(-!!rlang::sym("reconstructed_sequence_alignment"))
} else {
qual_num <- rep(NA, length(nt_aln))
qual_num[quality_df[['sequence_alignment_position']]] <- quality_df[[quality_num]]
qual_num <- paste0(qual_num, sep="", collapse=",")
qual_phred <- rep(" ", length(nt_aln))
qual_phred[quality_df[['sequence_alignment_position']]] <- quality_df[[quality]]
qual_phred <- paste0(qual_phred, sep="", collapse="")
ret <- data.frame(
"quality_alignment_num"=qual_num,
"quality_alignment"=qual_phred,
stringsAsFactors = F
) %>%
mutate(!!rlang::sym(sequence_id) := sequence_db[[sequence_id]])
ret
}
}
# Retrieve sequencing quality scores from tabular data
#
# \code{sequenceAlignmentQuality} is used internally by \code{readFastqDb} to
# process the sequencing quality scores loaded from a \code{fastq} file.
#
# Once a repertoire \code{data.frame} has been processed with \link{readFastqDb} and
# contains the fields \code{quality} and \code{quality_num},
# \code{sequenceAlignmentQuality} can be used to retrieve the quality scores
# from the already present field \code{quality_num}, without requiring
# again the \code{fastq} file, and report them as a \code{data.frame} with sequencing
# qualities per position, not as a string. This is done setting \code{raw=TRUE}.
# This \code{data.frame} with qualities per position can be used to generate figures,
# for example.
#
# @param data \code{data.frame} containing sequence data.
# @param sequence_id column in \code{data} that contains sequence
# identifiers to be matched to sequence identifiers in
# \code{fastq_file}.
# @param sequence column in \code{data} that contains sequence data.
# @param sequence_alignment column in \code{data} that contains
# IMGT aligned sequence data.
# @param quality column in \code{data} that contains
# sequencing quality as Phred scores.
# @param quality_num column in \code{data} that contains
# sequencing quality as a comma separated string.
# @param v_cigar column in \code{data} that contains CIGAR
# strings for the V gene alignments.
# @param d_cigar column in \code{data} that contains CIGAR
# strings for the D gene alignments.
# @param j_cigar column in \code{data} that contains CIGAR
# strings for the J gene alignments.
# @param np1_length column in \code{data} that contains the number
# of nucleotides between the V gene and first D gene
# alignments or between the V gene and J gene alignments.
# @param np2_length column in \code{data} that contains the number
# of nucleotides between either the first D gene and J
# gene alignments or the first D gene and second D gene
# alignments.
# @param v_sequence_end column in \code{data} that contains the
# end position of the V gene in \code{sequence}.
# @param d_sequence_end column in \code{data} that contains the
# end position of the D gene in \code{sequence}.
# @param raw specify how the sequencing quality should be returned.
# If \code{TRUE}, return a \code{data.frame} with
# quality information per position, where each row is
# a position. This \code{data.frame} has columns
# "sequence_position", "sequence_alignment_position",
# "quality", "quality_num", "sequence_id"
# and "sequence_alignment_nt" If \code{FALSE}, for each sequence,
# concatenate the position qualities in a string, and the
# quality information to \code{data}
sequenceAlignmentQuality <- function(data,
sequence_id="sequence_id",
sequence="sequence",
sequence_alignment="sequence_alignment",
quality="quality",
quality_num="quality_num",
v_cigar="v_cigar",
d_cigar="d_cigar",
j_cigar="j_cigar",
np1_length="np1_length",
np2_length="np2_length",
v_sequence_end="v_sequence_end",
d_sequence_end="d_sequence_end",
raw=FALSE) {
pb <- progressBar(nrow(data))
qual <- bind_rows(lapply(1:nrow(data),function(i) {
pb$tick()
calcSequenceAlignmentQuality(data[i,],
sequence=sequence,
sequence_id=sequence_id,
sequence_alignment=sequence_alignment,
quality=quality,
quality_num=quality_num,
v_cigar=v_cigar,
d_cigar=d_cigar,
j_cigar=j_cigar,
np1_length=np1_length,
np2_length=np2_length,
v_sequence_end=v_sequence_end,
d_sequence_end=d_sequence_end,
raw=raw)
}))
if (raw) {
qual
} else {
data %>%
dplyr::left_join(qual, by=sequence_id)
}
}
#' Mask sequence positions with low quality
#'
#' \code{maskPositionsByQuality} will replace positions that
#' have a sequencing quality score lower that \code{min_quality} with an
#' \code{"N"} character.
#'
#'
#' @param data \code{data.frame} containing sequence data.
#' @param min_quality minimum quality score. Positions with sequencing quality
#' less than \code{min_qual} will be masked.
#' @param sequence column in \code{data} with sequence data to be masked.
#' @param quality_num column in \code{data} with quality scores (a
#' string of numeric values, comma separated) that can
#' be used to mask \code{sequence}.
#'
#' @return Modified \code{data} data.frame with an additional field containing
#' quality masked sequences. The name of this field is created
#' concatenating the \code{sequence} name and \code{"_masked"}.
#'
#' @seealso \link{readFastqDb} and \link{getPositionQuality}
#'
#' @examples
#' db <- airr::read_rearrangement(system.file("extdata", "example_quality.tsv", package="alakazam"))
#' fastq_file <- system.file("extdata", "example_quality.fastq", package="alakazam")
#' db <- readFastqDb(db, fastq_file, quality_offset=-33)
#' maskPositionsByQuality(db, min_quality=90, quality_num="quality_alignment_num")
#'
#' @export
maskPositionsByQuality <- function(data, min_quality=70,
sequence="sequence_alignment",
quality_num="quality_alignment_num") {
required_cols <- c(sequence,quality_num)
checkColumns(data, required_cols)
sequence_masked <- paste0(sequence,"_masked")
num_masked_seqs <- 0
data <- bind_rows(lapply(1:nrow(data), function(i) {
db_row <- data[i,]
seq_qual <- strsplit(db_row[[quality_num]],",")[[1]]
low_seq_qual <- which(sapply(seq_qual, function(x) {
if (x != "NA") {
as.numeric(x) < min_quality
} else {
NA
}
}, USE.NAMES = FALSE))
if (length(low_seq_qual)>0) {
num_masked_seqs <<- num_masked_seqs + 1
seq <- strsplit(db_row[[sequence]],"")[[1]]
seq[low_seq_qual] <- "N"
seq <- paste0(seq, collapse="")
db_row[[sequence_masked]] <- seq
}
db_row
}))
message("Number of masked sequences: ", num_masked_seqs)
data
}
#' Get a data.frame with sequencing qualities per position
#'
#' \code{getPositionQuality} takes a data.frame with sequence quality scores
#' in the form of a strings of comma separated numeric values, split the quality
#' scores values by \code{","}, and returns a data.frame with the values
#' for each position.
#'
#'
#' @param data \code{data.frame} containing sequence data.
#' @param sequence_id column in \code{data} with sequence identifiers.
#' @param sequence column in \code{data} with sequence data.
#' @param quality_num column in \code{data} with quality scores (as
#' strings of numeric values, comma separated) for \code{sequence}.
#'
#' @return \code{data} with one additional field with masked sequences. The
#' name of this field is created concatenating \code{sequence}
#' and '_masked'.
#'
#' @seealso \link{readFastqDb} and \link{maskPositionsByQuality}
#'
#' @examples
#' db <- airr::read_rearrangement(system.file("extdata", "example_quality.tsv", package="alakazam"))
#' fastq_file <- system.file("extdata", "example_quality.fastq", package="alakazam")
#' db <- readFastqDb(db, fastq_file, quality_offset=-33)
#' head(getPositionQuality(db))
#
#' @export
getPositionQuality <- function(data,
sequence_id="sequence_id",
sequence="sequence_alignment",
quality_num="quality_alignment_num") {
checkColumns(data, c(sequence, quality_num))
bind_rows(lapply(1:nrow(data), function(i) {
seq_id <- data[[sequence_id]][i]
seq_len <- nchar(data[[sequence]][i])
qual_values <- as.numeric(strsplit(data[[quality_num]][i],",")[[1]])
nt <- strsplit(data[[sequence]],"")[[1]]
if (seq_len != length(qual_values)) {
stop("Different length, for sequence: ", seq_id,". seq: ", sequence, ". qual: ", quality_num)
}
data.frame(
"position"=1:seq_len, stringsAsFactors = F) %>%
mutate(!!rlang::sym(quality_num) := qual_values,
!!rlang::sym(sequence_id) := seq_id,
nt = nt)
}))
}
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