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Modstrings
In Modstrings: Working with modified nucleotide sequences
BiocStyle::markdown(css.files = c('custom.css'))
Introduction
Most nucleic acids, regardless of their being DNA or RNA, contain modified
nucleotides, which enhances the normal function of encoding genetic information.
They have usually a regulatory function and/or modify folding behavior and
molecular interactions.
RNA are nearly always post-transcriptionally modified. Most prominent examples
are of course ribsomal RNA (rRNA) and transfer RNA (tRNA), but in recent years
mRNA was also discovered to be post-transcriptionally modified. In addition,
many small and long non-coding RNAs are also modified.
In many resources, like the tRNAdb [@Juehling.2009] or the modomics database
[@Boccaletto.2018], modified nucleotides are repertoried. However in the
Bioconductor context these information were not accessible, since they rely
extensively on special characters in the RNA modification alphabet.
Therefore, the ModRNAString class was implemented extending the BString
class from the Biostrings [@Pages.2017] package. It can store RNA sequences
containing special characters of the RNA modification alphabet and thus can
store location and identity of modifications. Functions for conversion to a
tabular format are implemented as well.
The implemented classes inherit most of the functions from the parental
BString class and it derivatives, which allows them to behave like the
normal XString classes within the Bioconductor context. Most of the
functionality is directly inherited and derived from the Biostrings package.
Since a DNA modification alphabet also exists, a ModDNAString class was
implemented as well. For details on the available letters have a look at the
RNA modification and
[DNA modification](ModDNAString-alphabet.html alphabet vignettes.
Creating a ModRNAString object
In principle ModRNAString and ModDNAString objects can be created as any
other XString object. However encoding issue will most certainly come into
play, depending on the modification, the operation system and probably the R
version. This is not a problem of how the data is internally used, but how the
letter is transfered from the console to R and back.
suppressPackageStartupMessages({
library(Modstrings)
library(GenomicRanges)
})
library(Modstrings)
library(GenomicRanges)
# This works
mr <- ModRNAString("ACGU7")
# This might work on Linux, but does not on Windows
ModRNAString("ACGU≈")
# This cause a misinterpretation on Windows. Omega gets added as O.
# This modifys the information from yW-72 (7-aminocarboxypropylwyosine) to
# m1I (1-methylinosine)
ModRNAString("ACGUΩ")
To eliminate this issue the function modifyNucleotide() is implemented,
which can use short names or the nomenclature of a modification to add it at the
desired position.
head(shortName(ModRNAString()))
head(nomenclature(ModRNAString()))
r <- RNAString("ACGUG")
mr2 <- modifyNucleotides(r,5L,"m7G")
mr2
mr3 <- modifyNucleotides(r,5L,"7G",nc.type = "nc")
mr3
In addition, one can also use the alphabet() function and subset to the
desired modifications.
mr4 <- ModRNAString(paste0("ACGU",alphabet(ModRNAString())[33L]))
mr4
Streamlining object creation and modification
To offer a more streamlined functionality, which can take more information as
input, the function combineIntoModstrings() is implemented. It takes a
XString object and a GRanges object with a mod column and returns a
ModString object. The information in the mod column must match the short
name or nomenclature of the particular modification of interest as returned by
the shortName() or nomenclature() functions as seen above.
gr <- GRanges("1:5", mod = "m7G")
mr5 <- combineIntoModstrings(r, gr)
mr5
combineIntoModstrings() is also implemented for ModStringSet objects.
rs <- RNAStringSet(list(r,r,r,r,r))
names(rs) <- paste0("Sequence", seq_along(rs))
gr2 <- GRanges(seqnames = names(rs)[c(1L,1L,2L,3L,3L,4L,5L,5L)],
ranges = IRanges(start = c(4L,5L,5L,4L,5L,5L,4L,5L),
width = 1L),
mod = c("D","m7G","m7G","D","m7G","m7G","D","m7G"))
gr2
mrs <- combineIntoModstrings(rs, gr2)
mrs
The reverse operation is also available via the function separate(), which
allows the positions of modifications to be transfered into a tabular format.
gr3 <- separate(mrs)
rs2 <- RNAStringSet(mrs)
gr3
rs2
modifyNucleotides() and therefore also combineIntoModstrings() requires,
that the nucleotides to be modified match the originating base for the
modification. The next chunk fails, since the originating base for m7G is of
course G.
modifyNucleotides(r,4L,"m7G")
Calls for both functions check the sanity for this operation, so that the next
bit is always TRUE.
r <- RNAString("ACGUG")
mr2 <- modifyNucleotides(r,5L,"m7G")
r == RNAString(mr2)
Comparing ModString objects
ModString objects can be directly compared to RNAString or DNAString
objects depending on the type (ModRNA to RNA and ModDNA to DNA).
r == ModRNAString(r)
r == mr
rs == ModRNAStringSet(rs)
rs == c(mrs[1L:3L],rs[4L:5L])
Conversion of ModString objects
ModString objects can be converted into each other. However any conversion
will remove any information on modifications and revert each nucleotide back to
its originating nucleotide.
RNAString(mr)
Quality scaled ModString
Quality information can be encoded alongside ModString objects by combining it
with a XStringQuality object inside a QualityScaledModStringSet object. Two
class are implemented: QualityScaledModRNAStringSet and
QualityScaledModDNAStringSet. They are usable as expected from a
QualityScaledXStringSet object.
qmrs <- QualityScaledModRNAStringSet(mrs,
PhredQuality(c("!!!!h","!!!!h","!!!!h",
"!!!!h","!!!!h")))
qmrs
They can also be constructed/deconstructed using the functions
combineIntoModstrings() and separate() and use an additional metadata column
named quality. For quality information to persist during construction, set the
argument with.qualities = TRUE. If a QualityScaledModStringSet is used as an
input to separate, the quality information are returned in the quality column.
We choose to avoid clashes with the score column and not to recycle it.
qgr <- separate(qmrs)
qgr
combineIntoModstrings(mrs,qgr, with.qualities = TRUE)
Saving and reading ModString objects to/from file
The nucleotide sequences with modifications can be saved to a fasta or
fastq file using the functions writeModStringSet(). Reading of these files
is achieved using readModRNAStringSet() or readModDNAStringSet(). In case of
fastq files, the sequences can be automatically read as a
QualityScaledModRNAStringSet using readQualityScaledModRNAStringSet()
function.
writeModStringSet(mrs, file = "test.fasta")
# note the different function name. Otherwise empty qualities will be written
writeQualityScaledModStringSet(qmrs, file = "test.fastq")
mrs2 <- readModRNAStringSet("test.fasta", format = "fasta")
mrs2
qmrs2 <- readQualityScaledModRNAStringSet("test.fastq")
qmrs2
Since these functions are specifically designed to work with the modified
nucleotides within the sequence, they are slower than the analogous functions
from the Biostrings package. This is the result of a purely R based
implementation, whereas Biostrings functions are spead up through a C
backend. This is a potential improvement for future developments, but
currently special sequence files are limited, so it is not a priority.
unlink("test.fasta")
unlink("test.fastq")
Pattern matching
Pattern matching is implemented as well as expected for XString objects.
matchPattern("U7",mr)
vmatchPattern("D7",mrs)
mrl <- unlist(mrs)
matchLRPatterns("7ACGU","U7ACG",100L,mrl)
Future development
In principle post-translational modifications of proteins could also be
implemented. However, a one letter alphabet of post-translational modifications
must be developed first. If you are already aware of such an alphabet and want
to use it in a Bioconductor context, let us know.
Import example
This is a quick example showing how sequence information containing modified
nucleotides can be imported into an R session using the Modstrings package.
The file needs to be UTF-8 encoded.
# read the lines
test <- readLines(system.file("extdata","test.fasta",package = "Modstrings"),
encoding = "UTF-8")
head(test,2L)
# keep every second line as sequence, the other one as name
names <- test[seq.int(from = 1L, to = 104L, by = 2L)]
seq <- test[seq.int(from = 2L, to = 104L, by = 2L)]
# sanitize input. This needs to be adapt to the individual case
names <- gsub(" ","_",
gsub("> ","",
gsub(" \\| ","-",
names)))
seq <- gsub("-","",gsub("_","",seq))
names(seq) <- names
# sanitize special characters to Modstrings equivalent
seq <- sanitizeFromModomics(seq)
seq <- ModRNAStringSet(seq)
seq
# convert the contained modifications into a tabular format
separate(seq)
Sessioninfo
sessionInfo()
References
Try the Modstrings package in your browser
Any scripts or data that you put into this service are public.
Modstrings documentation built on Nov. 8, 2020, 7:51 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
BiocStyle::markdown(css.files = c('custom.css'))
Introduction
Most nucleic acids, regardless of their being DNA or RNA, contain modified nucleotides, which enhances the normal function of encoding genetic information. They have usually a regulatory function and/or modify folding behavior and molecular interactions.
RNA are nearly always post-transcriptionally modified. Most prominent examples are of course ribsomal RNA (rRNA) and transfer RNA (tRNA), but in recent years mRNA was also discovered to be post-transcriptionally modified. In addition, many small and long non-coding RNAs are also modified.
In many resources, like the tRNAdb [@Juehling.2009] or the modomics database [@Boccaletto.2018], modified nucleotides are repertoried. However in the Bioconductor context these information were not accessible, since they rely extensively on special characters in the RNA modification alphabet.
Therefore, the ModRNAString class was implemented extending the BString
class from the Biostrings [@Pages.2017] package. It can store RNA sequences
containing special characters of the RNA modification alphabet and thus can
store location and identity of modifications. Functions for conversion to a
tabular format are implemented as well.
The implemented classes inherit most of the functions from the parental
BString class and it derivatives, which allows them to behave like the
normal XString classes within the Bioconductor context. Most of the
functionality is directly inherited and derived from the Biostrings package.
Since a DNA modification alphabet also exists, a ModDNAString class was
implemented as well. For details on the available letters have a look at the
RNA modification and
[DNA modification](ModDNAString-alphabet.html alphabet vignettes.
Creating a ModRNAString object
In principle ModRNAString and ModDNAString objects can be created as any
other XString object. However encoding issue will most certainly come into
play, depending on the modification, the operation system and probably the R
version. This is not a problem of how the data is internally used, but how the
letter is transfered from the console to R and back.
suppressPackageStartupMessages({ library(Modstrings) library(GenomicRanges) })
library(Modstrings) library(GenomicRanges)
# This works mr <- ModRNAString("ACGU7") # This might work on Linux, but does not on Windows ModRNAString("ACGU≈") # This cause a misinterpretation on Windows. Omega gets added as O. # This modifys the information from yW-72 (7-aminocarboxypropylwyosine) to # m1I (1-methylinosine) ModRNAString("ACGUΩ")
To eliminate this issue the function modifyNucleotide() is implemented,
which can use short names or the nomenclature of a modification to add it at the
desired position.
head(shortName(ModRNAString())) head(nomenclature(ModRNAString()))
r <- RNAString("ACGUG") mr2 <- modifyNucleotides(r,5L,"m7G") mr2 mr3 <- modifyNucleotides(r,5L,"7G",nc.type = "nc") mr3
In addition, one can also use the alphabet() function and subset to the
desired modifications.
mr4 <- ModRNAString(paste0("ACGU",alphabet(ModRNAString())[33L])) mr4
Streamlining object creation and modification
To offer a more streamlined functionality, which can take more information as
input, the function combineIntoModstrings() is implemented. It takes a
XString object and a GRanges object with a mod column and returns a
ModString object. The information in the mod column must match the short
name or nomenclature of the particular modification of interest as returned by
the shortName() or nomenclature() functions as seen above.
gr <- GRanges("1:5", mod = "m7G") mr5 <- combineIntoModstrings(r, gr) mr5
combineIntoModstrings() is also implemented for ModStringSet objects.
rs <- RNAStringSet(list(r,r,r,r,r)) names(rs) <- paste0("Sequence", seq_along(rs)) gr2 <- GRanges(seqnames = names(rs)[c(1L,1L,2L,3L,3L,4L,5L,5L)], ranges = IRanges(start = c(4L,5L,5L,4L,5L,5L,4L,5L), width = 1L), mod = c("D","m7G","m7G","D","m7G","m7G","D","m7G")) gr2 mrs <- combineIntoModstrings(rs, gr2) mrs
The reverse operation is also available via the function separate(), which
allows the positions of modifications to be transfered into a tabular format.
gr3 <- separate(mrs) rs2 <- RNAStringSet(mrs) gr3 rs2
modifyNucleotides() and therefore also combineIntoModstrings() requires,
that the nucleotides to be modified match the originating base for the
modification. The next chunk fails, since the originating base for m7G is of
course G.
modifyNucleotides(r,4L,"m7G")
Calls for both functions check the sanity for this operation, so that the next
bit is always TRUE.
r <- RNAString("ACGUG") mr2 <- modifyNucleotides(r,5L,"m7G") r == RNAString(mr2)
Comparing ModString objects
ModString objects can be directly compared to RNAString or DNAString
objects depending on the type (ModRNA to RNA and ModDNA to DNA).
r == ModRNAString(r) r == mr rs == ModRNAStringSet(rs) rs == c(mrs[1L:3L],rs[4L:5L])
Conversion of ModString objects
ModString objects can be converted into each other. However any conversion
will remove any information on modifications and revert each nucleotide back to
its originating nucleotide.
RNAString(mr)
Quality scaled ModString
Quality information can be encoded alongside ModString objects by combining it
with a XStringQuality object inside a QualityScaledModStringSet object. Two
class are implemented: QualityScaledModRNAStringSet and
QualityScaledModDNAStringSet. They are usable as expected from a
QualityScaledXStringSet object.
qmrs <- QualityScaledModRNAStringSet(mrs, PhredQuality(c("!!!!h","!!!!h","!!!!h", "!!!!h","!!!!h"))) qmrs
They can also be constructed/deconstructed using the functions
combineIntoModstrings() and separate() and use an additional metadata column
named quality. For quality information to persist during construction, set the
argument with.qualities = TRUE. If a QualityScaledModStringSet is used as an
input to separate, the quality information are returned in the quality column.
We choose to avoid clashes with the score column and not to recycle it.
qgr <- separate(qmrs) qgr combineIntoModstrings(mrs,qgr, with.qualities = TRUE)
Saving and reading ModString objects to/from file
The nucleotide sequences with modifications can be saved to a fasta or
fastq file using the functions writeModStringSet(). Reading of these files
is achieved using readModRNAStringSet() or readModDNAStringSet(). In case of
fastq files, the sequences can be automatically read as a
QualityScaledModRNAStringSet using readQualityScaledModRNAStringSet()
function.
writeModStringSet(mrs, file = "test.fasta") # note the different function name. Otherwise empty qualities will be written writeQualityScaledModStringSet(qmrs, file = "test.fastq") mrs2 <- readModRNAStringSet("test.fasta", format = "fasta") mrs2 qmrs2 <- readQualityScaledModRNAStringSet("test.fastq") qmrs2
Since these functions are specifically designed to work with the modified
nucleotides within the sequence, they are slower than the analogous functions
from the Biostrings package. This is the result of a purely R based
implementation, whereas Biostrings functions are spead up through a C
backend. This is a potential improvement for future developments, but
currently special sequence files are limited, so it is not a priority.
unlink("test.fasta") unlink("test.fastq")
Pattern matching
Pattern matching is implemented as well as expected for XString objects.
matchPattern("U7",mr) vmatchPattern("D7",mrs) mrl <- unlist(mrs) matchLRPatterns("7ACGU","U7ACG",100L,mrl)
Future development
In principle post-translational modifications of proteins could also be implemented. However, a one letter alphabet of post-translational modifications must be developed first. If you are already aware of such an alphabet and want to use it in a Bioconductor context, let us know.
Import example
This is a quick example showing how sequence information containing modified
nucleotides can be imported into an R session using the Modstrings package.
The file needs to be UTF-8 encoded.
# read the lines test <- readLines(system.file("extdata","test.fasta",package = "Modstrings"), encoding = "UTF-8") head(test,2L) # keep every second line as sequence, the other one as name names <- test[seq.int(from = 1L, to = 104L, by = 2L)] seq <- test[seq.int(from = 2L, to = 104L, by = 2L)] # sanitize input. This needs to be adapt to the individual case names <- gsub(" ","_", gsub("> ","", gsub(" \\| ","-", names))) seq <- gsub("-","",gsub("_","",seq)) names(seq) <- names
# sanitize special characters to Modstrings equivalent seq <- sanitizeFromModomics(seq) seq <- ModRNAStringSet(seq) seq
# convert the contained modifications into a tabular format separate(seq)
Sessioninfo
sessionInfo()
References
Try the Modstrings package in your browser
Any scripts or data that you put into this service are public.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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