R version: R version 3.6.1 (2019-07-05)
Bioconductor version: 3.10
Package version: 1.10.0
The follow packages will be used throughout this documents. R version
3.3.1
or higher is required to install all the packages using
BiocManager::install
.
library("mzR")
library("mzID")
library("MSnID")
library("MSnbase")
library("rpx")
library("MLInterfaces")
library("pRoloc")
library("pRolocdata")
library("MSGFplus")
library("rols")
library("hpar")
The most convenient way to install all the tutorials requirement (and more related content), is to install RforProteomics with all its dependencies.
library("BiocManager")
BiocManager::install("RforProteomics", dependencies = TRUE)
Other packages of interest, such as rTANDEM or MSGFgui will be described later in the document but are not required to execute the code in this workflow.
This workflow illustrates R / Bioconductor infrastructure for proteomics. Topics covered focus on support for open community-driven formats for raw data and identification results, packages for peptide-spectrum matching, data processing and analysis:
Links to other packages and references are also documented. In particular, the vignettes included in the RforProteomics package also contains relevant material.
In Bioconductor version 3.10, there are respectively 134
proteomics,
90
mass spectrometry software packages
and 23
mass spectrometry experiment packages. These
respective packages can be extracted with the proteomicsPackages()
,
massSpectrometryPackages()
and massSpectrometryDataPackages()
and
explored interactively.
library("RforProteomics")
pp <- proteomicsPackages()
display(pp)
Most community-driven formats are supported in R
, as detailed in the
table below.
Type | Format | Package |
---|---|---|
raw | mzML, mzXML, netCDF, mzData | mzR (read) |
identification | mzIdentML | mzR (read) and mzID (read) |
quantitation | mzQuantML | |
peak lists | mgf | MSnbase (read/write) |
other | mzTab | MSnbase (read) |
MS-based proteomics data is disseminated through the ProteomeXchange infrastructure, which centrally coordinates submission, storage and dissemination through multiple data repositories, such as the PRIDE data base at the EBI for MS/MS experiments, PASSEL at the ISB for SRM data and the MassIVE resource. The rpx is an interface to ProteomeXchange and provides a basic access to PX data.
library("rpx")
pxannounced()
## 15 new ProteomeXchange annoucements
## Data.Set Publication.Data Message
## 1 PXD015755 2019-10-30 15:00:10 New
## 2 PXD012778 2019-10-30 09:56:36 New
## 3 PXD013609 2019-10-30 09:39:18 New
## 4 PXD014708 2019-10-30 09:35:57 New
## 5 PXD015352 2019-10-30 09:33:40 New
## 6 PXD014660 2019-10-30 09:32:34 New
## 7 PXD015508 2019-10-30 09:27:38 New
## 8 PXD015358 2019-10-30 09:26:46 New
## 9 PXD015383 2019-10-30 09:23:47 New
## 10 PXD015182 2019-10-30 09:14:10 New
## 11 PXD013113 2019-10-30 09:13:45 New
## 12 PXD016073 2019-10-30 08:23:49 New
## 13 PXD016072 2019-10-30 03:35:35 New
## 14 PXD016065 2019-10-29 19:19:20 New
## 15 PXD004566 2019-10-29 16:51:20 New
Using the unique PXD000001
identifier, we can retrieve the relevant
metadata that will be stored in a PXDataset
object. The names of the
files available in this data can be retrieved with the pxfiles
accessor function.
px <- PXDataset("PXD000001")
px
## Object of class "PXDataset"
## Id: PXD000001 with 12 files
## [1] 'F063721.dat' ... [12] 'generated'
## Use 'pxfiles(.)' to see all files.
pxfiles(px)
## [1] "F063721.dat"
## [2] "F063721.dat-mztab.txt"
## [3] "PRIDE_Exp_Complete_Ac_22134.xml.gz"
## [4] "PRIDE_Exp_mzData_Ac_22134.xml.gz"
## [5] "PXD000001_mztab.txt"
## [6] "README.txt"
## [7] "TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzML"
## [8] "TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzXML"
## [9] "TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01.mzXML"
## [10] "TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01.raw"
## [11] "erwinia_carotovora.fasta"
## [12] "generated"
Other metadata for the px
data set:
pxtax(px)
## [1] "Erwinia carotovora"
pxurl(px)
## [1] "ftp://ftp.pride.ebi.ac.uk/pride/data/archive/2012/03/PXD000001"
pxref(px)
## [1] "Gatto L, Christoforou A. Using R and Bioconductor for proteomics data analysis. Biochim Biophys Acta. 2013 May 18. doi:pii: S1570-9639(13)00186-6. 10.1016/j.bbapap.2013.04.032"
Data files can then be downloaded with the pxget
function. Below, we
retrieve the raw data file. The file is downloaded in the working
directory and the name of the file is return by the function and
stored in the mzf
variable for later use.
fn <- "TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzML"
mzf <- pxget(px, fn)
## Downloading 1 file
mzf
## [1] "/tmp/RtmpPV7H2d/Rbuild16565201a65a/proteomics/vignettes/TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzML"
The mzR
package provides an interface to the
proteowizard C/C++ code base
to access various raw data files, such as mzML
, mzXML
, netCDF
,
and mzData
. The data is accessed on-disk, i.e it is not loaded
entirely in memory by default but only when explicitly requested. The
three main functions are openMSfile
to create a file handle to a raw
data file, header
to extract metadata about the spectra contained in
the file and peaks
to extract one or multiple spectra of
interest. Other functions such as instrumentInfo
, or runInfo
can
be used to gather general information about a run.
Below, we access the raw data file downloaded in the previous section and open a file handle that will allow us to extract data and metadata of interest.
library("mzR")
ms <- openMSfile(mzf)
ms
## Mass Spectrometry file handle.
## Filename: TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzML
## Number of scans: 7534
The header
function returns the metadata of all available peaks:
hd <- header(ms)
dim(hd)
## [1] 7534 31
names(hd)
## [1] "seqNum" "acquisitionNum"
## [3] "msLevel" "polarity"
## [5] "peaksCount" "totIonCurrent"
## [7] "retentionTime" "basePeakMZ"
## [9] "basePeakIntensity" "collisionEnergy"
## [11] "ionisationEnergy" "lowMZ"
## [13] "highMZ" "precursorScanNum"
## [15] "precursorMZ" "precursorCharge"
## [17] "precursorIntensity" "mergedScan"
## [19] "mergedResultScanNum" "mergedResultStartScanNum"
## [21] "mergedResultEndScanNum" "injectionTime"
## [23] "filterString" "spectrumId"
## [25] "centroided" "ionMobilityDriftTime"
## [27] "isolationWindowTargetMZ" "isolationWindowLowerOffset"
## [29] "isolationWindowUpperOffset" "scanWindowLowerLimit"
## [31] "scanWindowUpperLimit"
We can extract metadata and scan data for scan 1000 as follows:
hd[1000, ]
## seqNum acquisitionNum msLevel polarity peaksCount totIonCurrent
## 1000 1000 1000 2 1 274 1048554
## retentionTime basePeakMZ basePeakIntensity collisionEnergy
## 1000 1106.916 136.061 164464 45
## ionisationEnergy lowMZ highMZ precursorScanNum precursorMZ
## 1000 0 104.5467 1370.758 992 683.0817
## precursorCharge precursorIntensity mergedScan mergedResultScanNum
## 1000 2 689443.7 NA NA
## mergedResultStartScanNum mergedResultEndScanNum injectionTime
## 1000 NA NA 55.21463
## filterString
## 1000 FTMS + p NSI d Full ms2 683.08@hcd45.00 [100.00-1380.00]
## spectrumId centroided
## 1000 controllerType=0 controllerNumber=1 scan=1000 TRUE
## ionMobilityDriftTime isolationWindowTargetMZ isolationWindowLowerOffset
## 1000 NA 683.08 1
## isolationWindowUpperOffset scanWindowLowerLimit scanWindowUpperLimit
## 1000 1 100 1380
head(peaks(ms, 1000))
## [,1] [,2]
## [1,] 104.5467 308.9326
## [2,] 104.5684 308.6961
## [3,] 108.8340 346.7183
## [4,] 109.3928 365.1236
## [5,] 110.0345 616.7905
## [6,] 110.0703 429.1975
plot(peaks(ms, 1000), type = "h")
Below we reproduce the example from the MSmap
function from the
MSnbase
package to plot a specific slice of the raw data using the
mzR
functions we have just described.
## a set of spectra of interest: MS1 spectra eluted
## between 30 and 35 minutes retention time
ms1 <- which(hd$msLevel == 1)
rtsel <- hd$retentionTime[ms1] / 60 > 30 &
hd$retentionTime[ms1] / 60 < 35
## the map
M <- MSmap(ms, ms1[rtsel], 521, 523, .005, hd)
plot(M, aspect = 1, allTicks = FALSE)
plot3D(M)
## With some MS2 spectra
i <- ms1[which(rtsel)][1]
j <- ms1[which(rtsel)][2]
M2 <- MSmap(ms, i:j, 100, 1000, 1, hd)
plot3D(M2)
The RforProteomics
package distributes a small identification result
file (see
?TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01.mzid
) that we
load and parse using infrastructure from the mzID
package.
library("mzID")
f <- dir(system.file("extdata", package = "RforProteomics"),
pattern = "mzid", full.names=TRUE)
basename(f)
## [1] "TMT_Erwinia.mzid.gz"
id <- mzID(f)
## reading TMT_Erwinia.mzid.gz... DONE!
id
## An mzID object
##
## Software used: MS-GF+ (version: Beta (v10072))
##
## Rawfile: /home/lgatto/dev/00_github/RforProteomics/sandbox/TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01.mzXML
##
## Database: /home/lgatto/dev/00_github/RforProteomics/sandbox/erwinia_carotovora.fasta
##
## Number of scans: 5287
## Number of PSM's: 5563
Various data can be extracted from the mzID
object, using one the
accessor functions such as database
, scans
, peptides
, … The
object can also be converted into a data.frame
using the flatten
function.
The mzR
package also provides support fasta parsing mzIdentML
files
with the openIDfile
function. As for raw data, the underlying C/C++
code comes from the
proteowizard.
library("mzR")
f <- dir(system.file("extdata", package = "RforProteomics"),
pattern = "mzid", full.names=TRUE)
id1 <- openIDfile(f)
fid1 <- mzR::psms(id1)
head(fid1)
## spectrumID chargeState rank passThreshold experimentalMassToCharge
## 1 scan=5782 3 1 TRUE 1080.2325
## 2 scan=6037 3 1 TRUE 1002.2089
## 3 scan=5235 3 1 TRUE 1189.2836
## 4 scan=5397 3 1 TRUE 960.5365
## 5 scan=6075 3 1 TRUE 1264.3409
## 6 scan=5761 2 1 TRUE 1268.6429
## calculatedMassToCharge sequence modNum isDecoy
## 1 1080.2321 PVQIQAGEDSNVIGALGGAVLGGFLGNTIGGGSGR 0 FALSE
## 2 1002.2115 TQVLDGLINANDIEVPVALIDGEIDVLR 0 FALSE
## 3 1189.2800 TKGLNVMQNLLTAHPDVQAVFAQNDEMALGALR 0 FALSE
## 4 960.5365 SQILQQAGTSVLSQANQVPQTVLSLLR 0 FALSE
## 5 1264.3419 PIIGDNPFVVVLPDVVLDESTADQTQENLALLISR 0 FALSE
## 6 1268.6501 WTSQSSLDLGEPLSLITESVFAR 0 FALSE
## post pre start end DatabaseAccess DBseqLength DatabaseSeq
## 1 S R 50 84 ECA1932 155
## 2 R K 288 315 ECA1147 434
## 3 A R 192 224 ECA0013 295
## 4 - R 264 290 ECA1731 290
## 5 F R 119 153 ECA1443 298
## 6 Y K 264 286 ECA1444 468
## DatabaseDescription scan.number.s.
## 1 ECA1932 outer membrane lipoprotein 5782
## 2 ECA1147 trigger factor 6037
## 3 ECA0013 ribose-binding periplasmic protein 5235
## 4 ECA1731 flagellin 5397
## 5 ECA1443 UTP--glucose-1-phosphate uridylyltransferase 6075
## 6 ECA1444 6-phosphogluconate dehydrogenase, decarboxylating 5761
## acquisitionNum
## 1 5782
## 2 6037
## 3 5235
## 4 5397
## 5 6075
## 6 5761
While searches are generally performed using third-party software
independently of R or can be started from R using a system
call, the
rTANDEM package allows one to execute such searches
using the X!Tandem engine. The shinyTANDEM provides an
experimental interactive interface to explore the search results.
library("rTANDEM")
?rtandem
library("shinyTANDEM")
?shinyTANDEM
Similarly, the MSGFplus package enables to perform a search using the MSGF+ engine, as illustrated below.
We search the /tmp/RtmpPV7H2d/Rbuild16565201a65a/proteomics/vignettes/TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzML file against the fasta file from PXD000001
using MSGFplus
.
We first download the fasta files:
fas <- pxget(px, "erwinia_carotovora.fasta")
## Downloading 1 file
basename(fas)
## [1] "erwinia_carotovora.fasta"
library("MSGFplus")
msgfpar <- msgfPar(database = fas,
instrument = 'HighRes',
tda = TRUE,
enzyme = 'Trypsin',
protocol = 'iTRAQ')
idres <- runMSGF(msgfpar, mzf, memory=1000)
## '/usr/bin/java' -Xmx1000M -jar '/home/biocbuild/bbs-3.10-bioc/R/library/MSGFplus/MSGFPlus/MSGFPlus.jar' -s '/tmp/RtmpPV7H2d/Rbuild16565201a65a/proteomics/vignettes/TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzML' -o '/tmp/RtmpPV7H2d/Rbuild16565201a65a/proteomics/vignettes/TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzid' -d '/tmp/RtmpPV7H2d/Rbuild16565201a65a/proteomics/vignettes/erwinia_carotovora.fasta' -tda 1 -inst 1 -e 1 -protocol 2
##
## reading TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzid... DONE!
idres
## An mzID object
##
## Software used: MS-GF+ (version: Beta (v10072))
##
## Rawfile: /tmp/RtmpPV7H2d/Rbuild16565201a65a/proteomics/vignettes/TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzML
##
## Database: /tmp/RtmpPV7H2d/Rbuild16565201a65a/proteomics/vignettes/erwinia_carotovora.fasta
##
## Number of scans: 5343
## Number of PSM's: 5656
## identification file (needed below)
basename(mzID::files(idres)$id)
## [1] "TMT_Erwinia_1uLSike_Top10HCD_isol2_45stepped_60min_01-20141210.mzid"
(Note that in the runMSGF
call above, I explicitly reduce the memory
allocated to the java virtual machine to 3.5GB. In general, there is
no need to specify this argument, unless you experience an error
regarding the maximum heap size).
A graphical interface to perform the search the data and explore the results is also available:
library("MSGFgui")
MSGFgui()
The MSnID package can be used for post-search filtering
of MS/MS identifications. One starts with the construction of an
MSnID
object that is populated with identification results that can
be imported from a data.frame
or from mzIdenML
files. Here, we
will use the example identification data provided with the package.
mzids <- system.file("extdata", "c_elegans.mzid.gz", package="MSnID")
basename(mzids)
## [1] "c_elegans.mzid.gz"
We start by loading the package, initialising the MSnID
object, and
add the identification result from our mzid
file (there could of
course be more that one).
library("MSnID")
msnid <- MSnID(".")
## Note, the anticipated/suggested columns in the
## peptide-to-spectrum matching results are:
## -----------------------------------------------
## accession
## calculatedMassToCharge
## chargeState
## experimentalMassToCharge
## isDecoy
## peptide
## spectrumFile
## spectrumID
msnid <- read_mzIDs(msnid, mzids)
## Reading from mzIdentMLs ...
## reading c_elegans.mzid.gz... DONE!
show(msnid)
## MSnID object
## Working directory: "."
## #Spectrum Files: 1
## #PSMs: 12263 at 36 % FDR
## #peptides: 9489 at 44 % FDR
## #accessions: 7414 at 76 % FDR
Printing the MSnID
object returns some basic information such as
The package then enables to define, optimise and apply filtering based for example on missed cleavages, identification scores, precursor mass errors, etc. and assess PSM, peptide and protein FDR levels. To properly function, it expects to have access to the following data
## [1] "accession" "calculatedMassToCharge"
## [3] "chargeState" "experimentalMassToCharge"
## [5] "isDecoy" "peptide"
## [7] "spectrumFile" "spectrumID"
which are indeed present in our data:
names(msnid)
## [1] "spectrumID" "scan number(s)"
## [3] "acquisitionNum" "passThreshold"
## [5] "rank" "calculatedMassToCharge"
## [7] "experimentalMassToCharge" "chargeState"
## [9] "MS-GF:DeNovoScore" "MS-GF:EValue"
## [11] "MS-GF:PepQValue" "MS-GF:QValue"
## [13] "MS-GF:RawScore" "MS-GF:SpecEValue"
## [15] "AssumedDissociationMethod" "IsotopeError"
## [17] "isDecoy" "post"
## [19] "pre" "end"
## [21] "start" "accession"
## [23] "length" "description"
## [25] "pepSeq" "modified"
## [27] "modification" "idFile"
## [29] "spectrumFile" "databaseFile"
## [31] "peptide"
Here, we summarise a few steps and redirect the reader to the package’s vignette for more details:
Cleaning irregular cleavages at the termini of the peptides and
missing cleavage site within the peptide sequences. The following two
function call create the new numMisCleavages
and numIrrCleabages
columns in the MSnID
object
msnid <- assess_termini(msnid, validCleavagePattern="[KR]\\.[^P]")
msnid <- assess_missed_cleavages(msnid, missedCleavagePattern="[KR](?=[^P$])")
Now, we can use the apply_filter
function to effectively apply
filters. The strings passed to the function represent expressions that
will be evaludated, this keeping only PSMs that have 0 irregular
cleavages and 2 or less missed cleavages.
msnid <- apply_filter(msnid, "numIrregCleavages == 0")
msnid <- apply_filter(msnid, "numMissCleavages <= 2")
show(msnid)
## MSnID object
## Working directory: "."
## #Spectrum Files: 1
## #PSMs: 7838 at 17 % FDR
## #peptides: 5598 at 23 % FDR
## #accessions: 3759 at 53 % FDR
Using "calculatedMassToCharge"
and "experimentalMassToCharge"
, the
mass_measurement_error
function calculates the parent ion mass
measurement error in parts per million.
summary(mass_measurement_error(msnid))
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## -2184.0640 -0.6992 0.0000 17.6146 0.7512 2012.5178
We then filter any matches that do not fit the +/- 20 ppm tolerance
msnid <- apply_filter(msnid, "abs(mass_measurement_error(msnid)) < 20")
summary(mass_measurement_error(msnid))
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## -19.7797 -0.5866 0.0000 -0.2970 0.5713 19.6758
Filtering of the identification data will rely on
msnid$msmsScore <- -log10(msnid$`MS-GF:SpecEValue`)
msnid$absParentMassErrorPPM <- abs(mass_measurement_error(msnid))
MS2 fiters are handled by a special MSnIDFilter
class objects, where
individual filters are set by name (that is present in names(msnid)
)
and comparison operator (>, <, = , …) defining if we should retain
hits with higher or lower given the threshold and finally the
threshold value itself.
filtObj <- MSnIDFilter(msnid)
filtObj$absParentMassErrorPPM <- list(comparison="<", threshold=10.0)
filtObj$msmsScore <- list(comparison=">", threshold=10.0)
show(filtObj)
## MSnIDFilter object
## (absParentMassErrorPPM < 10) & (msmsScore > 10)
We can then evaluate the filter on the identification data object, which return the false discovery rate and number of retained identifications for the filtering criteria at hand.
evaluate_filter(msnid, filtObj)
## fdr n
## PSM 0 3807
## peptide 0 2455
## accession 0 1009
Rather than setting filtering values by hand, as shown above, these can be set automativally to meet a specific false discovery rate.
filtObj.grid <- optimize_filter(filtObj, msnid, fdr.max=0.01,
method="Grid", level="peptide",
n.iter=500)
show(filtObj.grid)
## MSnIDFilter object
## (absParentMassErrorPPM < 3) & (msmsScore > 7.4)
evaluate_filter(msnid, filtObj.grid)
## fdr n
## PSM 0.004097561 5146
## peptide 0.006447651 3278
## accession 0.021996616 1208
Filters can eventually be applied (rather than just evaluated) using
the apply_filter
function.
msnid <- apply_filter(msnid, filtObj.grid)
show(msnid)
## MSnID object
## Working directory: "."
## #Spectrum Files: 1
## #PSMs: 5146 at 0.41 % FDR
## #peptides: 3278 at 0.64 % FDR
## #accessions: 1208 at 2.2 % FDR
And finally, identifications that matched decoy and contaminant protein sequences are removed
msnid <- apply_filter(msnid, "isDecoy == FALSE")
msnid <- apply_filter(msnid, "!grepl('Contaminant',accession)")
show(msnid)
## MSnID object
## Working directory: "."
## #Spectrum Files: 1
## #PSMs: 5117 at 0 % FDR
## #peptides: 3251 at 0 % FDR
## #accessions: 1179 at 0 % FDR
The resulting filtered identification data can be exported to a
data.frame
or to a dedicated MSnSet
data structure for
quantitative MS data, described below, and further processed and
analyses using appropriate statistical tests.
The above sections introduced low-level interfaces to raw and
identification results. The MSnbase package provides
abstractions for raw data through the MSnExp
class and containers
for quantification data via the MSnSet
class. Both store
spectra
(or the [
, [[
operators) or exprs
;data.frame
with pData
;data.frame
with fData
.Another useful slot is processingData
, accessed with
processingData(.)
, that records all the processing that objects have
undergone since their creation (see examples below).
The readMSData
will parse the raw data, extract the MS2 spectra (by
default) and construct an MS experiment object of class MSnExp
.
(Note that while readMSData
supports MS1 data, this is currently not
convenient as all the data is read into memory.)
library("MSnbase")
rawFile <- dir(system.file(package = "MSnbase", dir = "extdata"),
full.name = TRUE, pattern = "mzXML$")
basename(rawFile)
## [1] "dummyiTRAQ.mzXML"
msexp <- readMSData(rawFile, verbose = FALSE, centroided = FALSE)
msexp
## MSn experiment data ("MSnExp")
## Object size in memory: 0.18 Mb
## - - - Spectra data - - -
## MS level(s): 2
## Number of spectra: 5
## MSn retention times: 25:1 - 25:2 minutes
## - - - Processing information - - -
## Data loaded: Wed Oct 30 12:13:54 2019
## MSnbase version: 2.12.0
## - - - Meta data - - -
## phenoData
## rowNames: dummyiTRAQ.mzXML
## varLabels: sampleNames
## varMetadata: labelDescription
## Loaded from:
## dummyiTRAQ.mzXML
## protocolData: none
## featureData
## featureNames: F1.S1 F1.S2 ... F1.S5 (5 total)
## fvarLabels: spectrum
## fvarMetadata: labelDescription
## experimentData: use 'experimentData(object)'
MS2 spectra can be extracted as a list of Spectrum2
objects with the
spectra
accessor or as a subset of the original MSnExp
data with
the [
operator. Individual spectra can be accessed with [[
.
length(msexp)
## [1] 5
msexp[1:2]
## MSn experiment data ("MSnExp")
## Object size in memory: 0.07 Mb
## - - - Spectra data - - -
## MS level(s): 2
## Number of spectra: 2
## MSn retention times: 25:1 - 25:2 minutes
## - - - Processing information - - -
## Data loaded: Wed Oct 30 12:13:54 2019
## Data [numerically] subsetted 2 spectra: Wed Oct 30 12:13:54 2019
## MSnbase version: 2.12.0
## - - - Meta data - - -
## phenoData
## rowNames: dummyiTRAQ.mzXML
## varLabels: sampleNames
## varMetadata: labelDescription
## Loaded from:
## dummyiTRAQ.mzXML
## protocolData: none
## featureData
## featureNames: F1.S1 F1.S2
## fvarLabels: spectrum
## fvarMetadata: labelDescription
## experimentData: use 'experimentData(object)'
msexp[[2]]
## Object of class "Spectrum2"
## Precursor: 546.9586
## Retention time: 25:2
## Charge: 3
## MSn level: 2
## Peaks count: 1012
## Total ion count: 56758067
The identification results stemming from the same raw data file can then be used to add PSM matches.
fData(msexp)
## spectrum
## F1.S1 1
## F1.S2 2
## F1.S3 3
## F1.S4 4
## F1.S5 5
## find path to a mzIdentML file
identFile <- dir(system.file(package = "MSnbase", dir = "extdata"),
full.name = TRUE, pattern = "dummyiTRAQ.mzid")
basename(identFile)
## [1] "dummyiTRAQ.mzid"
msexp <- addIdentificationData(msexp, identFile)
fData(msexp)
## spectrum acquisition.number sequence chargeState rank
## F1.S1 1 1 VESITARHGEVLQLRPK 3 1
## F1.S2 2 2 IDGQWVTHQWLKK 3 1
## F1.S3 3 3 <NA> NA NA
## F1.S4 4 4 <NA> NA NA
## F1.S5 5 5 LVILLFR 2 1
## passThreshold experimentalMassToCharge calculatedMassToCharge modNum
## F1.S1 TRUE 645.3741 645.0375 0
## F1.S2 TRUE 546.9586 546.9633 0
## F1.S3 NA NA NA NA
## F1.S4 NA NA NA NA
## F1.S5 TRUE 437.8040 437.2997 0
## isDecoy post pre start end DatabaseAccess DBseqLength DatabaseSeq
## F1.S1 FALSE A R 170 186 ECA0984 231
## F1.S2 FALSE A K 50 62 ECA1028 275
## F1.S3 NA <NA> <NA> NA NA <NA> NA <NA>
## F1.S4 NA <NA> <NA> NA NA <NA> NA <NA>
## F1.S5 FALSE L K 22 28 ECA0510 166
## DatabaseDescription
## F1.S1 ECA0984 DNA mismatch repair protein
## F1.S2 ECA1028 2,3,4,5-tetrahydropyridine-2,6-dicarboxylate N-succinyltransferase
## F1.S3 <NA>
## F1.S4 <NA>
## F1.S5 ECA0510 putative capsular polysacharide biosynthesis transferase
## scan.number.s. idFile MS.GF.RawScore MS.GF.DeNovoScore
## F1.S1 1 dummyiTRAQ.mzid -39 77
## F1.S2 2 dummyiTRAQ.mzid -30 39
## F1.S3 NA <NA> NA NA
## F1.S4 NA <NA> NA NA
## F1.S5 5 dummyiTRAQ.mzid -42 5
## MS.GF.SpecEValue MS.GF.EValue modName modMass modLocation
## F1.S1 5.527468e-05 79.36958 <NA> NA NA
## F1.S2 9.399048e-06 13.46615 <NA> NA NA
## F1.S3 NA NA <NA> NA NA
## F1.S4 NA NA <NA> NA NA
## F1.S5 2.577830e-04 366.38422 <NA> NA NA
## subOriginalResidue subReplacementResidue subLocation nprot npep.prot
## F1.S1 <NA> <NA> NA 1 1
## F1.S2 <NA> <NA> NA 1 1
## F1.S3 <NA> <NA> NA NA NA
## F1.S4 <NA> <NA> NA NA NA
## F1.S5 <NA> <NA> NA 1 1
## npsm.prot npsm.pep
## F1.S1 1 1
## F1.S2 1 1
## F1.S3 NA NA
## F1.S4 NA NA
## F1.S5 1 1
The readMSData
and addIdentificationData
make use of mzR
and
mzID
packages to access the raw and identification data.
Spectra and (parts of) experiments can be extracted and plotted.
msexp[[1]]
## Object of class "Spectrum2"
## Precursor: 645.3741
## Retention time: 25:1
## Charge: 3
## MSn level: 2
## Peaks count: 2921
## Total ion count: 668170086
plot(msexp[[1]], full=TRUE)
msexp[1:3]
## MSn experiment data ("MSnExp")
## Object size in memory: 0.11 Mb
## - - - Spectra data - - -
## MS level(s): 2
## Number of spectra: 3
## MSn retention times: 25:1 - 25:2 minutes
## - - - Processing information - - -
## Data loaded: Wed Oct 30 12:13:54 2019
## Data [numerically] subsetted 3 spectra: Wed Oct 30 12:13:55 2019
## MSnbase version: 2.12.0
## - - - Meta data - - -
## phenoData
## rowNames: dummyiTRAQ.mzXML
## varLabels: sampleNames
## varMetadata: labelDescription
## Loaded from:
## dummyiTRAQ.mzXML
## protocolData: none
## featureData
## featureNames: F1.S1 F1.S2 F1.S3
## fvarLabels: spectrum acquisition.number ... npsm.pep (34 total)
## fvarMetadata: labelDescription
## experimentData: use 'experimentData(object)'
plot(msexp[1:3], full=TRUE)
There are a wide range of proteomics quantitation techniques that can broadly be classified as labelled vs. label-free, depending whether the features are labelled prior the MS acquisition and the MS level at which quantitation is inferred, namely MS1 or MS2.
Label-free | Labelled | |
---|---|---|
MS1 | XIC | SILAC, 15N |
MS2 | Counting | iTRAQ, TMT |
In terms of raw data quantitation, most efforts have been devoted to MS2-level quantitation. Label-free XIC quantitation has however been addressed in the frame of metabolomics data processing by the xcms infrastructure.
An MSnExp
is converted to an MSnSet
by the quantitation
method. Below, we use the iTRAQ 4-plex isobaric tagging strategy
(defined by the iTRAQ4
parameter; other tags are available) and the
trapezoidation
method to calculate the area under the isobaric
reporter peaks.
plot(msexp[[1]], full=TRUE, reporters = iTRAQ4)
msset <- quantify(msexp, method = "trap", reporters = iTRAQ4, verbose=FALSE)
exprs(msset)
## iTRAQ4.114 iTRAQ4.115 iTRAQ4.116 iTRAQ4.117
## F1.S1 4483.320 4873.996 6743.441 4601.378
## F1.S2 1918.082 1418.040 1117.601 1581.954
## F1.S3 15210.979 15296.256 15592.760 16550.502
## F1.S4 4133.103 5069.983 4724.845 4694.801
## F1.S5 11947.881 13061.875 12809.491 12911.479
processingData(msset)
## - - - Processing information - - -
## Data loaded: Wed Oct 30 12:13:54 2019
## iTRAQ4 quantification by trapezoidation: Wed Oct 30 12:13:59 2019
## MSnbase version: 2.12.0
Other MS2 quantitation methods available in quantify
include the
(normalised) spectral index SI
and (normalised) spectral abundance
factor SAF
or simply a simple count method.
exprs(si <- quantify(msexp, method = "SIn"))
## dummyiTRAQ.mzXML
## ECA0510 0.0006553518
## ECA0984 0.0035384487
## ECA1028 0.0002684726
exprs(saf <- quantify(msexp, method = "NSAF"))
## dummyiTRAQ.mzXML
## ECA0510 0.4306167
## ECA0984 0.3094475
## ECA1028 0.2599359
Note that spectra that have not been assigned any peptide (NA
) or
that match non-unique peptides (npsm > 1
) are discarded in the
counting process.
The PSI mzTab
file format is aimed at providing a simpler (than XML
formats) and more accessible file format to the wider community. It is
composed of a key-value metadata section and peptide/protein/small
molecule tabular sections.
Note that below, we specify version 0.9 (that generates the warning)
to fit with the file. For recent files, the version
argument would
be ignored to use the recent importer.
mztf <- pxget(px, "F063721.dat-mztab.txt")
## Downloading 1 file
(mzt <- readMzTabData(mztf, what = "PEP", version = "0.9"))
## Warning: Version 0.9 is deprecated. Please see '?readMzTabData' and '?MzTab'
## for details.
## MSnSet (storageMode: lockedEnvironment)
## assayData: 1528 features, 6 samples
## element names: exprs
## protocolData: none
## phenoData
## sampleNames: sub[1] sub[2] ... sub[6] (6 total)
## varLabels: abundance
## varMetadata: labelDescription
## featureData
## featureNames: 1 2 ... 1528 (1528 total)
## fvarLabels: sequence accession ... uri (14 total)
## fvarMetadata: labelDescription
## experimentData: use 'experimentData(object)'
## Annotation:
## - - - Processing information - - -
## mzTab read: Wed Oct 30 12:14:08 2019
## MSnbase version: 2.12.0
It is also possible to import arbitrary spreadsheets as MSnSet
objects into R with the readMSnSet2
function. The main 2 arguments
of the function are (1) a text-based spreadsheet and (2) column names
of indices that identify the quantitation data. The latter can be
queried with the getEcols
function.
csv <- dir(system.file ("extdata" , package = "pRolocdata"),
full.names = TRUE, pattern = "pr800866n_si_004-rep1.csv")
getEcols(csv, split = ",")
## [1] "\"Protein ID\"" "\"FBgn\""
## [3] "\"Flybase Symbol\"" "\"No. peptide IDs\""
## [5] "\"Mascot score\"" "\"No. peptides quantified\""
## [7] "\"area 114\"" "\"area 115\""
## [9] "\"area 116\"" "\"area 117\""
## [11] "\"PLS-DA classification\"" "\"Peptide sequence\""
## [13] "\"Precursor ion mass\"" "\"Precursor ion charge\""
## [15] "\"pd.2013\"" "\"pd.markers\""
ecols <- 7:10
res <- readMSnSet2(csv, ecols)
head(exprs(res))
## area.114 area.115 area.116 area.117
## 1 0.379000 0.281000 0.225000 0.114000
## 2 0.420000 0.209667 0.206111 0.163889
## 3 0.187333 0.167333 0.169667 0.476000
## 4 0.247500 0.253000 0.320000 0.179000
## 5 0.216000 0.183000 0.342000 0.259000
## 6 0.072000 0.212333 0.573000 0.142667
head(fData(res))
## Protein.ID FBgn Flybase.Symbol No..peptide.IDs Mascot.score
## 1 CG10060 FBgn0001104 G-ialpha65A 3 179.86
## 2 CG10067 FBgn0000044 Act57B 5 222.40
## 3 CG10077 FBgn0035720 CG10077 5 219.65
## 4 CG10079 FBgn0003731 Egfr 2 86.39
## 5 CG10106 FBgn0029506 Tsp42Ee 1 52.10
## 6 CG10130 FBgn0010638 Sec61beta 2 79.90
## No..peptides.quantified PLS.DA.classification Peptide.sequence
## 1 1 PM
## 2 9 PM
## 3 3
## 4 2 PM
## 5 1 GGVFDTIQK
## 6 3 ER/Golgi
## Precursor.ion.mass Precursor.ion.charge pd.2013 pd.markers
## 1 PM unknown
## 2 PM unknown
## 3 unknown unknown
## 4 PM unknown
## 5 626.887 2 Phenotype 1 unknown
## 6 ER/Golgi ER
For raw data processing look at MSnbase
’s clean
, smooth
,
pickPeaks
, removePeaks
and trimMz
for MSnExp
and spectra
processing methods.
The MALDIquantand xcms packages also features a wide range of raw data processing methods on their own ad hoc data instance types.
Each different types of quantitative data will require their own
pre-processing and normalisation steps. Both isobar
and MSnbase
allow to correct for isobaric tag impurities normalise the
quantitative data.
data(itraqdata)
qnt <- quantify(itraqdata, method = "trap",
reporters = iTRAQ4, verbose = FALSE)
impurities <- matrix(c(0.929,0.059,0.002,0.000,
0.020,0.923,0.056,0.001,
0.000,0.030,0.924,0.045,
0.000,0.001,0.040,0.923),
nrow=4, byrow = TRUE)
## or, using makeImpuritiesMatrix()
## impurities <- makeImpuritiesMatrix(4)
qnt.crct <- purityCorrect(qnt, impurities)
processingData(qnt.crct)
## - - - Processing information - - -
## Data loaded: Wed May 11 18:54:39 2011
## Updated from version 0.3.0 to 0.3.1 [Fri Jul 8 20:23:25 2016]
## iTRAQ4 quantification by trapezoidation: Wed Oct 30 12:14:09 2019
## Purity corrected: Wed Oct 30 12:14:09 2019
## MSnbase version: 1.1.22
Various normalisation methods can be applied the MSnSet
instances
using the normalise
method: variance stabilisation (vsn
), quantile
(quantiles
), median or mean centring (center.media
or
center.mean
), …
qnt.crct.nrm <- normalise(qnt.crct, "quantiles")
The combineFeatures
method combines spectra/peptides quantitation
values into protein data. The grouping is defined by the groupBy
parameter, which is generally taken from the feature metadata (protein
accessions, for example).
## arbitraty grouping
g <- factor(c(rep(1, 25), rep(2, 15), rep(3, 15)))
g
## [1] 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 2
## [37] 2 2 2 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3
## Levels: 1 2 3
prt <- combineFeatures(qnt.crct.nrm, groupBy = g, fun = "sum")
## Warning: Parameter 'fun' is deprecated. Please use 'method' instead
## Your data contains missing values. Please read the relevant section
## in the combineFeatures manual page for details on the effects of
## missing values on data aggregation.
processingData(prt)
## - - - Processing information - - -
## Data loaded: Wed May 11 18:54:39 2011
## Updated from version 0.3.0 to 0.3.1 [Fri Jul 8 20:23:25 2016]
## iTRAQ4 quantification by trapezoidation: Wed Oct 30 12:14:09 2019
## Purity corrected: Wed Oct 30 12:14:09 2019
## Normalised (quantiles): Wed Oct 30 12:14:09 2019
## Combined 55 features into 3 using mean: Wed Oct 30 12:14:09 2019
## MSnbase version: 2.12.0
Finally, proteomics data analysis is generally hampered by missing values. Missing data imputation is a sensitive operation whose success will be guided by many factors, such as degree and (non-)random nature of the missingness.
Below, missing values are randomly assigned to our test data and visualised on a heatmap.
set.seed(1)
qnt0 <- qnt
exprs(qnt0)[sample(prod(dim(qnt0)), 10)] <- NA
table(is.na(qnt0))
##
## FALSE TRUE
## 209 11
image(qnt0)
Missing value in MSnSet
instances can be filtered out and imputed
using the filterNA
and impute
functions.
## remove features with missing values
qnt00 <- filterNA(qnt0)
dim(qnt00)
## [1] 44 4
any(is.na(qnt00))
## [1] FALSE
## impute missing values using knn imputation
qnt.imp <- impute(qnt0, method = "knn")
dim(qnt.imp)
## [1] 55 4
any(is.na(qnt.imp))
## [1] FALSE
There are various methods to perform data imputation, as described in
?impute
.
R in general and Bioconductor in particular are well suited for the statistical analysis of data. Several packages provide dedicated resources for proteomics data:
MSstats: A set of tools for statistical relative
protein significance analysis in DDA, SRM and DIA experiments. Data
stored in data.frame
or MSnSet
objects can be used as input.
msmsTests: Statistical tests for label-free LC-MS/MS
data by spectral counts, to discover differentially expressed
proteins between two biological conditions. Three tests are
available: Poisson GLM regression, quasi-likelihood GLM regression,
and the negative binomial of the edgeR
package. All can be readily applied on MSnSet
instances produced,
for example by MSnID
.
isobar also provides dedicated infrastructure for the statistical analysis of isobaric data.
The MLInterfaces package provides a unified interface
to a wide range of machine learning algorithms. Initially developed
for microarray and ExpressionSet
instances, the
pRoloc package enables application of these algorithms
to MSnSet
data.
The example below uses knn
with the 5 closest neighbours as an
illustration to classify proteins of unknown sub-cellular localisation
to one of 9 possible organelles.
library("MLInterfaces")
library("pRoloc")
library("pRolocdata")
data(dunkley2006)
traininds <- which(fData(dunkley2006)$markers != "unknown")
ans <- MLearn(markers ~ ., data = t(dunkley2006), knnI(k = 5), traininds)
ans
## MLInterfaces classification output container
## The call was:
## MLearn(formula = markers ~ ., data = t(dunkley2006), .method = knnI(k = 5),
## trainInd = traininds)
## Predicted outcome distribution for test set:
##
## ER lumen ER membrane Golgi Mitochondrion PM
## 5 140 67 51 89
## Plastid Ribosome TGN vacuole
## 29 31 6 10
## Summary of scores on test set (use testScores() method for details):
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## 0.4000 1.0000 1.0000 0.9332 1.0000 1.0000
kcl <- MLearn( ~ ., data = dunkley2006, kmeansI, centers = 12)
kcl
## clusteringOutput: partition table
##
## 1 2 3 4 5 6 7 8 9 10 11 12
## 30 48 101 44 50 35 24 80 34 87 52 104
## The call that created this object was:
## MLearn(formula = ~., data = dunkley2006, .method = kmeansI, centers = 12)
plot(kcl, exprs(dunkley2006))
A wide range of classification and clustering algorithms are also
available, as described in the ?MLearn
documentation page. The
pRoloc
package also uses MSnSet
instances as input and ,while
being conceived with the analysis of spatial/organelle proteomics data
in mind, is applicable many use cases.
All the Bioconductor annotation infrastructure, such as biomaRt, GO.db, organism specific annotations, .. are directly relevant to the analysis of proteomics data. A total of 239 ontologies, including some proteomics-centred annotations such as the PSI Mass Spectrometry Ontology, Molecular Interaction (PSI MI 2.5) or Protein Modifications are available through the rols
library("rols")
res <- OlsSearch(q = "ESI", ontology = "MS", exact = TRUE)
res
## Object of class 'OlsSearch':
## ontolgy: MS
## query: ESI
## requested: 20 (out of 1)
## response(s): 0
There is a single exact match (default is to retrieve 20 results),
that can be retrieved and coreced to a Terms
or data.frame
object
with
res <- olsSearch(res)
as(res, "Terms")
## Object of class 'Terms' with 1 entries
## From the MS ontology
## MS:1000073
as(res, "data.frame")
## id
## 1 ms:class:http://purl.obolibrary.org/obo/MS_1000073
## iri short_form obo_id
## 1 http://purl.obolibrary.org/obo/MS_1000073 MS_1000073 MS:1000073
## label
## 1 electrospray ionization
## description
## 1 A process in which ionized species in the gas phase are produced from an analyte-containing solution via highly charged fine droplets, by means of spraying the solution from a narrow-bore needle tip at atmospheric pressure in the presence of a high electric field. When a pressurized gas is used to aid in the formation of a stable spray, the term pneumatically assisted electrospray ionization is used. The term ion spray is not recommended.
## ontology_name ontology_prefix type is_defining_ontology
## 1 ms MS class TRUE
Data from the Human Protein Atlas is available via the hpar package.
Additional relevant packages are described in the RforProteomics vignettes.
## R version 3.6.1 (2019-07-05)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 18.04.3 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.10-bioc/R/lib/libRblas.so
## LAPACK: /home/biocbuild/bbs-3.10-bioc/R/lib/libRlapack.so
##
## attached base packages:
## [1] stats4 parallel stats graphics grDevices utils datasets
## [8] methods base
##
## other attached packages:
## [1] nloptr_1.2.1 RforProteomics_1.23.1 BiocManager_1.30.9
## [4] knitr_1.25 proteomics_1.10.0 hpar_1.28.0
## [7] rols_2.14.0 MSGFplus_1.20.0 pRolocdata_1.23.0
## [10] pRoloc_1.26.0 BiocParallel_1.20.0 MLInterfaces_1.66.0
## [13] cluster_2.1.0 annotate_1.64.0 XML_3.98-1.20
## [16] AnnotationDbi_1.48.0 IRanges_2.20.0 rpx_1.22.0
## [19] MSnbase_2.12.0 ProtGenerics_1.18.0 S4Vectors_0.24.0
## [22] Biobase_2.46.0 BiocGenerics_0.32.0 MSnID_1.20.0
## [25] mzID_1.24.0 mzR_2.20.0 Rcpp_1.0.2
## [28] BiocStyle_2.14.0
##
## loaded via a namespace (and not attached):
## [1] R.utils_2.9.0 RUnit_0.4.32 tidyselect_0.2.5
## [4] RSQLite_2.1.2 htmlwidgets_1.5.1 grid_3.6.1
## [7] lpSolve_5.6.13.3 rda_1.0.2-2.1 munsell_0.5.0
## [10] codetools_0.2-16 preprocessCore_1.48.0 withr_2.1.2
## [13] colorspace_1.4-1 highr_0.8 robustbase_0.93-5
## [16] labeling_0.3 hwriter_1.3.2 bit64_0.9-7
## [19] ggvis_0.4.5 coda_0.19-3 vctrs_0.2.0
## [22] generics_0.0.2 ipred_0.9-9 xfun_0.10
## [25] BiocFileCache_1.10.0 randomForest_4.6-14 diptest_0.75-7
## [28] R6_2.4.0 doParallel_1.0.15 flexmix_2.3-15
## [31] bitops_1.0-6 assertthat_0.2.1 promises_1.1.0
## [34] scales_1.0.0 nnet_7.3-12 gtable_0.3.0
## [37] biocViews_1.54.0 affy_1.64.0 timeDate_3043.102
## [40] rlang_0.4.1 zeallot_0.1.0 genefilter_1.68.0
## [43] splines_3.6.1 lazyeval_0.2.2 ModelMetrics_1.2.2
## [46] impute_1.60.0 hexbin_1.27.3 yaml_2.2.0
## [49] reshape2_1.4.3 threejs_0.3.1 crosstalk_1.0.0
## [52] backports_1.1.5 httpuv_1.5.2 RBGL_1.62.0
## [55] caret_6.0-84 tools_3.6.1 lava_1.6.6
## [58] bookdown_0.14 ggplot2_3.2.1 affyio_1.56.0
## [61] RColorBrewer_1.1-2 proxy_0.4-23 plyr_1.8.4
## [64] base64enc_0.1-3 progress_1.2.2 zlibbioc_1.32.0
## [67] purrr_0.3.3 RCurl_1.95-4.12 prettyunits_1.0.2
## [70] rpart_4.1-15 openssl_1.4.1 viridis_0.5.1
## [73] sampling_2.8 sfsmisc_1.1-4 LaplacesDemon_16.1.1
## [76] magrittr_1.5 data.table_1.12.6 pcaMethods_1.78.0
## [79] mvtnorm_1.0-11 R.cache_0.13.0 hms_0.5.1
## [82] mime_0.7 evaluate_0.14 xtable_1.8-4
## [85] mclust_5.4.5 gridExtra_2.3 compiler_3.6.1
## [88] biomaRt_2.42.0 tibble_2.1.3 ncdf4_1.17
## [91] crayon_1.3.4 R.oo_1.22.0 htmltools_0.4.0
## [94] segmented_1.0-0 later_1.0.0 lubridate_1.7.4
## [97] DBI_1.0.0 dbplyr_1.4.2 MASS_7.3-51.4
## [100] fpc_2.2-3 rappdirs_0.3.1 Matrix_1.2-17
## [103] vsn_3.54.0 R.methodsS3_1.7.1 gdata_2.18.0
## [106] mlbench_2.1-1 gower_0.2.1 igraph_1.2.4.1
## [109] pkgconfig_2.0.3 recipes_0.1.7 MALDIquant_1.19.3
## [112] xml2_1.2.2 foreach_1.4.7 prodlim_2018.04.18
## [115] stringr_1.4.0 digest_0.6.22 pls_2.7-2
## [118] graph_1.64.0 rmarkdown_1.16 dendextend_1.12.0
## [121] curl_4.2 kernlab_0.9-27 shiny_1.4.0
## [124] gtools_3.8.1 modeltools_0.2-22 nlme_3.1-141
## [127] jsonlite_1.6 viridisLite_0.3.0 askpass_1.1
## [130] limma_3.42.0 pillar_1.4.2 lattice_0.20-38
## [133] fastmap_1.0.1 httr_1.4.1 DEoptimR_1.0-8
## [136] survival_2.44-1.1 glue_1.3.1 FNN_1.1.3
## [139] gbm_2.1.5 prabclus_2.3-1 iterators_1.0.12
## [142] bit_1.1-14 class_7.3-15 stringi_1.4.3
## [145] mixtools_1.1.0 blob_1.2.0 memoise_1.1.0
## [148] dplyr_0.8.3 e1071_1.7-2