specL 1.32.1
Targeted proteomics is a fast evolving field in proteomics science and was even elected as the method of the year in 2012 . Especially targeted methods like SWATH (Gillet et al. 2012) open promising perspectives for for identifying and quantifying of peptides and proteins. All targeted methods have in common the need of precise MS coordinates composed of precursor mass, fragment masses, and retention time. The combination of this information is kept in so-called assays or spectra libraries. Here we present an R package able to produce such libraries out of peptide identification results (Mascot (dat), TPP (pep.xml and mzXMLs), ProteinPilot (group), Omssa (omx)). specL (Panse et al. 2015) is an easy-to-use, versatile, and flexible function, which can be integrated into already existing commercial or non-commercial analysis pipelines for targeted proteomics data analysis. Some examples of today’s pipelines are ProteinPilot combined with Peakview (AB Sciex), Spectronaut (Biognosys) or OpenSwath (Rost et al. 2014).
In the following vignette it is described how the specL package
can be used for the included data sets peptideStd
and
peptideStd.redundant
.
Since peptide identification (using, e.g., Mascot, Sequest, xTandem!,
Omssa, ProteinPilot)
usually creates result files which are
heavily redundant and therefore unsuited for spectral library building,
the search results must first be filtered. To create non-redundant
input files, we use the BiblioSpec (Frewen and MacCoss 2007) algorithm
implemented in Skyline (MacLean et al. 2010). A given search result (e.g.
Mascot result file) is loaded into the software Skyline and is redundancy
filtered. The ‘Skyline workflow step’ provides two sqlite readable
files
as output named *.blib
and *.redundant.blib
.
These files are used as ideal input for this packages.
Note here, that Skyline is very flexible when it comes to peptide
identification results. It means with Skyline you can build the spectrum
library files for almost all search engines (even from other spectrum
library files such as spectraST (Lam et al. 2008)).
The first step which has to be performed on the R shell is loading specL library.
library(specL)
packageVersion('specL')
## [1] '1.32.1'
for demonstration, specL contains the two data sets, namely peptideStd
and
peptideStd.redundant
. This data set
comes from two standard-run experiments routinely
used to check if the liquid chromatographic system is still working
appropriately. The sample consists of a digest of the Fetuin protein
(Bos taurus, uniprot id: P12763). 40 femtomole are loaded on the column.
Mascot was used to search and identify the respective peptides.
summary(peptideStd)
## Summary of a "psmSet" object.
## Number of precursor:
## 137
## Number of precursors in Filename(s)
## 0140910_01_fetuin_400amol_1.raw 21
## 0140910_07_fetuin_400amol_2.raw 116
## Number of annotated precursor:
## 0
For both peptideStd
, peptideStd.redandant
data sets the
Skyline software was used to generate the bibliospec files which
contain the peptide sequences with the respective peptide spectrum
match (PSM). The specL::read.bibliospec
function was used
to read the blib files into R.
The from read.bibliospec
generated object has its own plot functions.
The LC-MS map graphs peptide mass versus retention time.
# plot(peptideStd)
plot(0,0, main='MISSING')
The individual peptide spectrum match (psm) is displayed by using the
protViz peakplot
function.
demoIdx <- 40
# str(peptideStd[[demoIdx]])
#res <- plot(peptideStd[[demoIdx]], ion.axes=TRUE)
plot(0,0, main='MISSING')
Alternatively, Mascot search result files (dat) can be used by applying
protViz perl script
protViz\-\_mascotDat2RData.pl
.
The Perl script can be found in the exec directory of the protViz package. The mascot mod_file can be found in the configurations of the mascot server. An example on our Linux shell looks as follows:
$ /usr/local/lib/R/site-library/protViz/exec/protViz_mascotDat2RData.pl \
-d=/usr/local/mascot/data/20130116/F178287.dat \
-m=mod_file
mascotDat2RData.pl
requires the Mascot server mod\_file
keeping
all the configured modification.
Once the {erl script is finished, the resulting RData file can be read into the R session using load
.
Next, the variable modifications, and the S3 psmSet object has to be generated. This can be done by using specL:::.mascot2psmSet
specL:::.mascot2psmSet
## function (dat, mod, mascotScoreCutOff = 40)
## {
## res <- lapply(dat, function(x) {
## x$MonoisotopicAAmass <- protViz::aa2mass(x$peptideSequence)[[1]]
## modString <- as.numeric(strsplit(x$modification, "")[[1]])
## modIdx <- which(modString > 0) - 1
## modString.length <- length(modString)
## x$varModification <- mod[modString[c(-1, -modString.length)] +
## 1]
## if (length(modIdx) > 0) {
## warning("modified varModification caused.")
## x$varModification[modIdx] <- x$varModification[modIdx] -
## x$MonoisotopicAAmass[modIdx]
## }
## rt <- x$rtinseconds
## x <- c(x, rt = rt, fileName = "mascot")
## class(x) <- "psm"
## return(x)
## })
## res <- res[which(unlist(lapply(dat, function(x) {
## x$mascotScore > mascotScoreCutOff && length(x$mZ) > 10
## })))]
## class(res) <- "psmSet"
## return(res)
## }
## <bytecode: 0x5597de2ef570>
## <environment: namespace:specL>
If you are processing Mascot result files, you can continue reading in the section genSwathIonLib
.
However, please note due do the high potential redundancy of peptide spectrum matches in a database search approach, it might not result in useful ion library for targeted data extraction unless redundancy filtering is handled. However, in a future release, a redundancy filter algorithm might be proposed to resolve this problem.
The information to which protein a peptide-spectrum-match belongs (PSM)
is not stored by BiblioSpec. Therefore specL provides the annotate.protein\_id
function which uses R’s internal grep
to ‘reassign’ the protein information. Therefore a fasta
object has
to be loaded into the R system using read.fasta
of the
seqinr package. For this, not necessarily, the same fasta
file needs to be provided as in the original database
search.
The following lines demonstrate a simple sanity check with a single FASTA style formatted protein entry. Also it demonstrates the use case how to identify entries in the R-object which are from one or a few proteins of interest.
irtFASTAseq <- paste(">zz|ZZ_FGCZCont0260|",
"iRT_Protein_with_AAAAK_spacers concatenated Biognosys\n",
"LGGNEQVTRAAAAKGAGSSEPVTGLDAKAAAAKVEATFGVDESNAKAAAAKYILAGVENS",
"KAAAAKTPVISGGPYEYRAAAAKTPVITGAPYEYRAAAAKDGLDAASYYAPVRAAAAKAD",
"VTPADFSEWSKAAAAKGTFIIDPGGVIRAAAAKGTFIIDPAAVIRAAAAKLFLQFGAQGS",
"PFLK\n")
Tfile <- file(); cat(irtFASTAseq, file = Tfile);
fasta.irtFASTAseq <- read.fasta(Tfile, as.string=TRUE, seqtype="AA")
close(Tfile)
As expected, the peptideStd
data, e.g., our demo object, does not contain any protein information yet.
peptideStd[[demoIdx]]$proteinInformation
## [1] ""
The protein information can be added as follow:
peptideStd <- annotate.protein_id(peptideStd,
fasta=fasta.irtFASTAseq)
## start protein annotation ...
## time taken: 0.000662712256113688 minutes
The following lines now show the object indices of those entries which do have protein information now.
(idx <- which(unlist(lapply(peptideStd,
function(x){nchar(x$proteinInformation)>0}))))
## [1] 1 2 3 4 5 6
As expected, there are now a number of peptide sequences annotated with the protein ID.
peptideStd[[demoIdx]]$proteinInformation
## [1] "zz|ZZ_FGCZCont0260|"
Of note, that the default digest pattern is defined as
digestPattern = "(([RK])|(^)|(^M))"
for tryptic peptides. For other enzymes, the pattern has to
be adapted. For example, for semi-tryptic identifications, use
digestPattern = ""
.
genSwathIonLib
is the main contribution of the
specL package. It generates the spectral library used in a targeted data extraction workflow from a mass spectrometric
measurement. Generating the ion library using iRT peptides is highly recommended as described. However if you have no iRT peptide, continue reading in section noiRT.
Generation of the spec Library with default (see Table) settings.
res.genSwathIonLib <- genSwathIonLib(data = peptideStd,
data.fit = peptideStd.redundant)
## normalizing RT ...
## found 7 iRT peptide(s) in s:\p1239\Proteomics\QEXACTIVE_3\ctrachse_20140910_Nuclei_diff_extraction_methods\20140910_01_fetuin_400amol_1.raw
## found 7 iRT peptide(s) in s:\p1239\Proteomics\QEXACTIVE_3\ctrachse_20140910_Nuclei_diff_extraction_methods\20140910_07_fetuin_400amol_2.raw
## building model ...
## generating ion library ...
## start generating specLSet object ...
## length of findNN idx 137
## length of genSwathIonLibSpecL 137
## time taken: 0.269155025482178 secs
## length of genSwathIonLibSpecL after fragmentIonRange filtering 137
genSwathIonLib default settings
parameter | description | value |
---|---|---|
max.mZ.Da.error | max ms2 tolerance | 0.1 |
topN | the n most intense fragment ion | 10 |
fragmentIonMzRange | mZ range filter of fragment ion | c(300, 1800) |
fragmentIonRange | min/max number of fragment ions | c(5,100) |
fragmentIonFUN} | desired fragment ion types | b1+,y1+,b2+,y2+,b3+,y3+ |
summary(res.genSwathIonLib)
## Summary of a "specLSet" object.
##
## Parameter:
##
## Number of precursor (q1 and peptideModSeq) = 137
## Number of unique precursor
## (q1.in-silico and peptideModSeq) = 126
## Number of iRT peptide(s) = 8
## Which std peptides (iRTs) where found in which raw files:
## 0140910_01_fetuin_400amol_1.raw GAGSSEPVTGLDAK
## 0140910_01_fetuin_400amol_1.raw TPVITGAPYEYR
## 0140910_01_fetuin_400amol_1.raw VEATFGVDESNAK
## 0140910_07_fetuin_400amol_2.raw ADVTPADFSEWSK
## 0140910_07_fetuin_400amol_2.raw DGLDAASYYAPVR
## 0140910_07_fetuin_400amol_2.raw GTFIIDPGGVIR
## 0140910_07_fetuin_400amol_2.raw LFLQFGAQGSPFLK
## 0140910_07_fetuin_400amol_2.raw TPVISGGPYEYR
##
## Number of transitions frequency:
## 4 1
## 5 5
## 6 10
## 7 7
## 8 18
## 9 32
## 10 64
##
## Number of annotated precursor = 6
## Number of file(s)
## 2
##
## Number of precursors in Filename(s)
## 0140910_01_fetuin_400amol_1.raw 21
## 0140910_07_fetuin_400amol_2.raw 116
##
## Misc:
##
## Memory usage = 676976 bytes
The determined mass spec coordinates of the selected tandem mass spectrum
demoIdx
look like this:
res.genSwathIonLib@ionlibrary[[demoIdx]]
## An "specL" object.
##
##
## content:
## group_id = GAGSSEPVTGLDAK.2
## peptide_sequence = GAGSSEPVTGLDAK
## proteinInformation = zz|ZZ_FGCZCont0260|
## q1 = 644.8219
## q1.in_silico = 1288.638
## q3 = 800.4497 604.3285 1016.522 503.2805 929.4925 400.7282
## 333.176 1160.581 703.3948 343.1235
## q3.in_silico = 800.4512 604.3301 1016.526 503.2824 929.4938
## 400.7295 333.1769 1160.579 703.3985 343.1615
## prec_z = 2
## frg_type = y y y y y y y y y b
## frg_nr = 8 6 10 5 9 8 3 12 7 8
## frg_z = 1 1 1 1 1 2 1 1 1 2
## relativeFragmentIntensity = 100 21 19 12 10 9 9 8 8 6
## irt = -0.95
## peptideModSeq = GAGSSEPVTGLDAK
## mZ.error = 0.001514 0.00156 0.003685 0.001914 0.001318
## 0.001313 0.000856 0.001846 0.003686 0.0380015
## uclei_diff_extraction_methods\20140910_01_fetuin_400amol_1.raw
## score = 41.54902
##
## size:
## Memory usage: 4776 bytes
It can be displayed using the function.
plot(res.genSwathIonLib@ionlibrary[[demoIdx]])
The following code considers only the top five y ions.
# define customized fragment ions
# for demonstration lets consider only the top five singly charged y ions.
r.genSwathIonLib.top5 <- genSwathIonLib(peptideStd,
peptideStd.redundant, topN=5,
fragmentIonFUN=function (b, y) {
return( cbind(y1_=y) )
}
)
## normalizing RT ...
## found 7 iRT peptide(s) in s:\p1239\Proteomics\QEXACTIVE_3\ctrachse_20140910_Nuclei_diff_extraction_methods\20140910_01_fetuin_400amol_1.raw
## found 7 iRT peptide(s) in s:\p1239\Proteomics\QEXACTIVE_3\ctrachse_20140910_Nuclei_diff_extraction_methods\20140910_07_fetuin_400amol_2.raw
## building model ...
## generating ion library ...
## start generating specLSet object ...
## length of findNN idx 137
## length of genSwathIonLibSpecL 137
## time taken: 0.195030212402344 secs
## length of genSwathIonLibSpecL after fragmentIonRange filtering 137
plot(r.genSwathIonLib.top5@ionlibrary[[demoIdx]])
Retention time is an essential parameter in targeted data extraction. However, retention times are difficult to transfer between reverse phase columns or HPLC systems. To make transfer applicable and account for the inter-run shift in retention time Biognosys (Escher et al. 2012) invented the iRT normalization based on iRT / HRM peptides. For this, a set of well-behaving peptides (good flying properties, good fragmentation characteristics, completely artificial) which cover the whole rt-gradient and are spiked into each sample. For this set of peptides, an idependent retention time (dimension less) is suggested by Biognosys. With this at hand, the set of peptides can later be used to apply a linear regression model to adapt all measured retention times into an independent retention time scale.
If the identification results contain iRT peptides, the package
supports the conversion to the iRT scale. For this (if the identification
the outcome is based on multiple input files), the redundant BiblioSpec file
is required where all iRT peptides from all measurements are stored.
For the most representative spectrum in the non-redundant R-object the
original filename is identified, and the respective linear model for this
one particular MS experiment is applied
to normalize the retention time to the iRT scale.
The iRT peptides, as well as their independent retention times, are
stored in the iRTpeptides
object.
specL uses by default the iRT peptide table to normalize into the independent retention time but could also be extended or changed to custom iRT peptides if available.
iRTpeptides
## peptide rt
## 1 LGGNEQVTR -24.92000
## 2 GAGSSEPVTGLDAK 0.00000
## 3 AAVYHHFISDGVR 10.48963
## 4 VEATFGVDESNAK 12.39000
## 5 YILAGVENSK 19.79000
## 6 HIQNIDIQHLAGK 23.93091
## 7 TPVISGGPYEYR 28.71000
## 8 TPVITGAPYEYR 33.38000
## 9 DGLDAASYYAPVR 42.26000
## 10 TEVSSNHVLIYLDK 43.54062
## 11 ADVTPADFSEWSK 54.62000
## 12 LVAYYTLIGASGQR 64.15480
## 13 GTFIIDPGGVIR 70.52000
## 14 TEHPFTVEEFVLPK 74.50968
## 15 TTNIQGINLLFSSR 84.36927
## 16 GTFIIDPAAVIR 87.23000
## 17 LFLQFGAQGSPFLK 100.00000
## 18 NQGNTWLTAFVLK 104.06935
## 19 DSPVLIDFFEDTER 112.63426
## 20 ITPNLAEFAFSLYR 122.24622
## 21 LGGNETQVR -24.92000
## 22 AGGSSEPVTGLADK 0.00000
## 23 VEATFGVDESANK 12.39000
## 24 YILAGVESNK 19.79000
## 25 TPVISGGPYYER 28.71000
## 26 TPVITGAPYYER 33.38000
## 27 GDLDAASYYAPVR 42.26000
## 28 DAVTPADFSEWSK 54.62000
## 29 TGFIIDPGGVIR 70.52000
## 30 GTFIIDPAAIVR 87.23000
## 31 FLLQFGAQGSPLFK 100.00000
The method genSwathIonLib uses:
fit <- lm(formula = rt ~ aggregateInputRT * fileName, data = m)
to build the linear models for each MS measurement individually.
For defining m
both data sets were aggregated over the attributes
peptide
and fileName
using the mean
operator.
data <- aggregate(df$rt, by = list(df$peptide, df$fileName),
FUN = mean)
data.fit <- aggregate(df.fit$rt,
by = list(df.fit$peptide, df.fit$fileName),
FUN = mean)
Afterwards the following join operator was applied.
m <- merge(iRT, data.fit, by.x='peptide', by.y='peptide')
The following graph displays the normalized retention time versus the measured retention time after applying the calculated model to the two data sets.
# calls the plot method for a specLSet object
op <- par(mfrow=c(2,3))
plot(res.genSwathIonLib)
## [1] 16.83185 13.13262 18.54058 18.36923 15.30478 15.30478
## [1] 7.032372 6.490769 14.787681 14.544429 15.207398
## [6] 15.207398
par(op)
Shown are the original retention time (in minutes) and iRT (dimensionless) for two standard run experiments (color black and red). Indicated with black {} are the iRT peptides, which are the base for the regression.
If no iRT peptides are contained in the data, not iRT normalization is applied. The scatter plot below shows on the y-axis that there was not iRT transformation.
idx.iRT <- which(unlist(lapply(peptideStd,
function(x){
if(x$peptideSequence %in% iRTpeptides$peptide){0}
else{1}
})) == 0)
# remove all iRTs and compute ion library
res.genSwathIonLib.no_iRT <- genSwathIonLib(peptideStd[-idx.iRT])
## normalizing RT ...
## no iRT peptides found for building the model.
## => no iRT regression applied, using orgiginal rt instead!
## generating ion library ...
## start generating specLSet object ...
## length of findNN idx 129
## length of genSwathIonLibSpecL 129
## time taken: 0.257305145263672 secs
## length of genSwathIonLibSpecL after fragmentIonRange filtering 129
summary(res.genSwathIonLib.no_iRT)
## Summary of a "specLSet" object.
##
## Parameter:
##
## Number of precursor (q1 and peptideModSeq) = 129
## Number of unique precursor
## (q1.in-silico and peptideModSeq) = 118
## Number of iRT peptide(s) = 0
## Number of transitions frequency:
## 4 1
## 5 5
## 6 10
## 7 7
## 8 17
## 9 31
## 10 58
##
## Number of annotated precursor = 0
## Number of file(s)
## 2
##
## Number of precursors in Filename(s)
## 0140910_01_fetuin_400amol_1.raw 18
## 0140910_07_fetuin_400amol_2.raw 111
##
## Misc:
##
## Memory usage = 630368 bytes
op <- par(mfrow = c(2, 3))
plot(res.genSwathIonLib.no_iRT)
## [1] 16.83185 18.54058 18.36923 15.30478 15.30478 19.36682
## [1] 7.032372 6.490769 14.787681 14.544429 15.207398
## [6] 15.207398
par(op)
The output can be written as an ASCII text file.
write.spectronaut(res.genSwathIonLib,
file="specL-Spectronaut.txt")
## writting specL object (including header) to file 'specL-Spectronaut.txt' ...
The specL output text file can directly be used as input (assay) for the Spectronaut software from Biognosys or with minimal reshaping for Peakview. Alternatively, it can be used as a basis for script-based construction of SRM/MRM assays.
The benchmarks were processed on a 12 core XEON Server (X5650 @ 2.67GHz) running Linux Debian wheezy having R version 3.1.1 (2014-07-10) , specL 1.1.2, and BiocParallel 1.0.0 installed. The default setting of BiocParallel uses eight cores. As FASTA, we used a TAIR10 retrieved from and Human Swissprot.
\begin{table}[h]
\centering
\resizebox{.99\textwidth}{!}{
\begin{tabular}{rrr|rr|rr}
\hline
fasta=TAIR10 & & & blib [unpublished] & & runtime & \\
\#proteins & \#tryptic peptides & file size & \#specs & file size & annotate & generate\\\hline \hline
71032 & 3423196 & 39M & 39648/118268 & 51M & 79min & 19sec \\
71032 & 3423196 & 39M & 65018/136963 & 120M & 130min & 30sec \\
\hline
fasta=HUMAN & & & blib \cite[Rosenberger]{Rosenberger} & & & \\
88969& 3997085 & 43M & 256908/3060421 & 4.4G & $\approx$7h &$\approx$5min \\
%HUMAN\footnote{Rosenberger et al. in Scientific Data (doi:10.1038/sdata.2014.31)} && & & & 256908/3060421& & 4.4G & & $\approx$5min\\
\hline
\end{tabular}
}
\end{table}
The following parameter settings were given to the genSwathIonLib
function:
res <- genSwathIonLib(data, data.fit,
topN=10,
fragmentIonMzRange=c(200,2000),
fragmentIonRange=c(2,100))
The authors thank all colleagues of the Functional Genomics Center Zuerich (FGCZ), and especial thank goes to our test users Sira Echevarr'{i}a~Zome~{n}o (ETHZ), Tobias Kockmann (ETHZ), Lukas von Ziegler (Brain Research Institute, UZH/ETH Zurich), and Stephan~Michalik (Ernst-Moritz-Arndt-Universität Greifswald, Germany).
importer for peakview csv format; enable
new option for ; Exclude fragment ions from precursor
new option for ; Predict transitions for heavy labeled peptides using information from light peptides
new export function into TraML format for compatibility with OpenSWATH
replace by using to handle fasta files
add varMods to specL class
replace Mascot score by a generic score
in-silico rt ion map plot () split window into SWATH windows (one plot per, e.g., 25Da window)
assay refinement - replace contaminated fragment ion in library
An overview of the package versions used to produce this document are shown below.
## R version 4.2.2 (2022-10-31)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 20.04.5 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.16-bioc/R/lib/libRblas.so
## LAPACK: /home/biocbuild/bbs-3.16-bioc/R/lib/libRlapack.so
##
## locale:
## [1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
## [3] LC_TIME=en_GB LC_COLLATE=C
## [5] LC_MONETARY=en_US.UTF-8 LC_MESSAGES=en_US.UTF-8
## [7] LC_PAPER=en_US.UTF-8 LC_NAME=C
## [9] LC_ADDRESS=C LC_TELEPHONE=C
## [11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
##
## attached base packages:
## [1] stats graphics grDevices utils datasets
## [6] methods base
##
## other attached packages:
## [1] knitr_1.41 specL_1.32.1 seqinr_4.2-23
## [4] RSQLite_2.2.19 protViz_0.7.3 DBI_1.1.3
## [7] BiocStyle_2.26.0
##
## loaded via a namespace (and not attached):
## [1] Rcpp_1.0.9 bslib_0.4.1
## [3] compiler_4.2.2 BiocManager_1.30.19
## [5] jquerylib_0.1.4 highr_0.9
## [7] tools_4.2.2 digest_0.6.31
## [9] bit_4.0.5 jsonlite_1.8.4
## [11] evaluate_0.18 memoise_2.0.1
## [13] lifecycle_1.0.3 rlang_1.0.6
## [15] cli_3.4.1 magick_2.7.3
## [17] yaml_2.3.6 parallel_4.2.2
## [19] xfun_0.35 fastmap_1.1.0
## [21] stringr_1.5.0 vctrs_0.5.1
## [23] sass_0.4.4 bit64_4.0.5
## [25] ade4_1.7-20 glue_1.6.2
## [27] R6_2.5.1 rmarkdown_2.18
## [29] bookdown_0.30 blob_1.2.3
## [31] magrittr_2.0.3 codetools_0.2-18
## [33] htmltools_0.5.4 MASS_7.3-58.1
## [35] stringi_1.7.8 cachem_1.0.6
Escher, C., L. Reiter, B. MacLean, R. Ossola, F. Herzog, J. Chilton, M. J. MacCoss, and O. Rinner. 2012. “Using iRT, a normalized retention time for more targeted measurement of peptides.” Proteomics 12 (8): 1111–21.
Frewen, B., and M. J. MacCoss. 2007. “Using BiblioSpec for creating and searching tandem MS peptide libraries.” Curr Protoc Bioinformatics Chapter 13 (December): Unit 13.7.
Gillet, L. C., P. Navarro, S. Tate, H. Rost, N. Selevsek, L. Reiter, R. Bonner, and R. Aebersold. 2012. “Targeted data extraction of the MS/MS spectra generated by data-independent acquisition: a new concept for consistent and accurate proteome analysis.” Mol. Cell Proteomics 11 (6): O111.016717.
Lam, H., E. W. Deutsch, J. S. Eddes, J. K. Eng, S. E. Stein, and R. Aebersold. 2008. “Building consensus spectral libraries for peptide identification in proteomics.” Nat. Methods 5 (10): 873–75.
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