MetaboAnnotation 1.11.1
Package: MetaboAnnotation
Authors: Michael Witting [aut] (ORCID: https://orcid.org/0000-0002-1462-4426),
Johannes Rainer [aut, cre] (ORCID:
https://orcid.org/0000-0002-6977-7147),
Andrea Vicini [aut] (ORCID: https://orcid.org/0000-0001-9438-6909),
Carolin Huber [aut] (ORCID: https://orcid.org/0000-0002-9355-8948),
Philippine Louail [aut] (ORCID:
https://orcid.org/0009-0007-5429-6846),
Nir Shachaf [ctb]
Compiled: Thu Nov 21 18:28:00 2024
The MetaboAnnotation package defines high-level user functionality to support and facilitate annotation of MS-based metabolomics data (Rainer et al. 2022).
The package can be installed with the BiocManager package. To
install BiocManager
use install.packages("BiocManager")
and, after that,
BiocManager::install("MetaboAnnotation")
to install this package.
MetaboAnnotation provides a set of matching functions that allow comparison (and matching) between query and target entities. These entities can be chemical formulas, numeric values (e.g. m/z or retention times) or fragment spectra. The available matching functions are:
matchFormula()
: to match chemical formulas.matchSpectra()
: to match fragment spectra.matchValues()
(formerly matchMz()
): to match numerical values (m/z,
masses, retention times etc).For each of these matching functions parameter objects are available that
allow different types or matching algorithms. Refer to the help pages for a
detailed listing of these (e.g. ?matchFormula
, ?matchSpectra
or
?matchValues
). As a result, a Matched
(or MatchedSpectra
) object is
returned which streamlines and simplifies handling of the potential one-to-many
(or one-to-none) matching.
The following sections illustrate example use cases of the functionality provided by the MetaboAnnotation package.
library(MetaboAnnotation)
In this section a simple matching of feature m/z values against theoretical m/z values is performed. This is the lowest level of confidence in metabolite annotation. However, it gives ideas about potential metabolites that can be analyzed in further downstream experiments and analyses.
The following example loads the feature table from a lipidomics experiments and
matches the measured m/z values against reference masses from LipidMaps. Below
we use a data.frame
as reference database, but a CompDb
compound database
instance (as created by the CompoundDb package) would also be
supported.
ms1_features <- read.table(system.file("extdata", "MS1_example.txt",
package = "MetaboAnnotation"),
header = TRUE, sep = "\t")
head(ms1_features)
## feature_id mz rtime
## 1 Cluster_0001 102.1281 1.560147
## 2 Cluster_0002 102.1279 2.153590
## 3 Cluster_0003 102.1281 2.925570
## 4 Cluster_0004 102.1281 3.419617
## 5 Cluster_0005 102.1270 5.801039
## 6 Cluster_0006 102.1230 8.137535
target_df <- read.table(system.file("extdata", "LipidMaps_CompDB.txt",
package = "MetaboAnnotation"),
header = TRUE, sep = "\t")
head(target_df)
## headgroup name exactmass formula chain_type
## 1 NAE NAE 20:4;O 363.2773 C22H37NO3 even
## 2 NAT NAT 20:4;O 427.2392 C22H37NO5S even
## 3 NAE NAE 20:3;O2 381.2879 C22H39NO4 even
## 4 NAE NAE 20:4 347.2824 C22H37NO2 even
## 5 NAE NAE 18:2 323.2824 C20H37NO2 even
## 6 NAE NAE 18:3 321.2668 C20H35NO2 even
For reference (target) compounds we have only the mass available. We need to
convert this mass to m/z values in order to match the m/z values from the
features (i.e. the query m/z values) against them. For this we need to define
the most likely ions/adducts that would be generated from the compounds based
on the ionization used in the experiment. We assume the most abundant adducts
from the compounds being "[M+H]+"
and "[M+Na]+
. We next perform the matching
with the matchValues()
function providing the query and target data as well as
a parameter object (in our case a Mass2MzParam
) with the settings for the
matching. With the Mass2MzParam
, the mass or target compounds get first
converted to m/z values, based on the defined adducts, and these are then
matched against the query m/z values (i.e. the m/z values for the features). To
get a full list of supported adducts the MetaboCoreUtils::adductNames(polarity = "positive")
or MetaboCoreUtils::adductNames(polarity = "negative")
can be
used). Note also, to keep the runtime of this vignette short, we match only the
first 100 features.
parm <- Mass2MzParam(adducts = c("[M+H]+", "[M+Na]+"),
tolerance = 0.005, ppm = 0)
matched_features <- matchValues(ms1_features[1:100, ], target_df, parm)
matched_features
## Object of class Matched
## Total number of matches: 55
## Number of query objects: 100 (55 matched)
## Number of target objects: 57599 (1 matched)
From the tested 100 features 55 were matched against at least one target
compound (all matches are against a single compound). The result object (of type
Matched
) contains the full query data frame and target data frames as well as
the matching information. We can access the original query data with query()
and the original target data with target()
function:
head(query(matched_features))
## feature_id mz rtime
## 1 Cluster_0001 102.1281 1.560147
## 2 Cluster_0002 102.1279 2.153590
## 3 Cluster_0003 102.1281 2.925570
## 4 Cluster_0004 102.1281 3.419617
## 5 Cluster_0005 102.1270 5.801039
## 6 Cluster_0006 102.1230 8.137535
head(target(matched_features))
## headgroup name exactmass formula chain_type
## 1 NAE NAE 20:4;O 363.2773 C22H37NO3 even
## 2 NAT NAT 20:4;O 427.2392 C22H37NO5S even
## 3 NAE NAE 20:3;O2 381.2879 C22H39NO4 even
## 4 NAE NAE 20:4 347.2824 C22H37NO2 even
## 5 NAE NAE 18:2 323.2824 C20H37NO2 even
## 6 NAE NAE 18:3 321.2668 C20H35NO2 even
Functions whichQuery()
and whichTarget()
can be used to identify the rows in
the query and target data that could be matched:
whichQuery(matched_features)
## [1] 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64
## [20] 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83
## [39] 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100
whichTarget(matched_features)
## [1] 3149
The colnames
function can be used to evaluate which variables/columns are
available in the Matched
object.
colnames(matched_features)
## [1] "feature_id" "mz" "rtime"
## [4] "target_headgroup" "target_name" "target_exactmass"
## [7] "target_formula" "target_chain_type" "adduct"
## [10] "score" "ppm_error"
These are all columns from the query
, all columns from the target
(the
prefix "target_"
is added to the original column names in target
) and
information on the matching result (in this case columns "adduct"
, "score"
and "ppm_error"
).
We can extract the full matching table with matchedData()
. This returns a
DataFrame
with all rows in query the corresponding matches in target along
with the matching adduct (column "adduct"
) and the difference in m/z (column
"score"
for absolute differences and "ppm_error"
for the m/z relative
differences). Note that if a row in query matches multiple elements in
target, this row will be duplicated in the DataFrame
returned by
matchedData()
. For rows that can not be matched NA
values are reported.
matchedData(matched_features)
## DataFrame with 100 rows and 11 columns
## feature_id mz rtime target_headgroup target_name
## <character> <numeric> <numeric> <character> <character>
## 1 Cluster_00... 102.128 1.56015 NA NA
## 2 Cluster_00... 102.128 2.15359 NA NA
## 3 Cluster_00... 102.128 2.92557 NA NA
## 4 Cluster_00... 102.128 3.41962 NA NA
## 5 Cluster_00... 102.127 5.80104 NA NA
## ... ... ... ... ... ...
## 96 Cluster_00... 201.113 11.2722 FA FA 10:2;O2
## 97 Cluster_00... 201.113 11.4081 FA FA 10:2;O2
## 98 Cluster_00... 201.113 11.4760 FA FA 10:2;O2
## 99 Cluster_00... 201.114 11.5652 FA FA 10:2;O2
## 100 Cluster_01... 201.114 11.7752 FA FA 10:2;O2
## target_exactmass target_formula target_chain_type adduct score
## <numeric> <character> <character> <character> <numeric>
## 1 NA NA NA NA NA
## 2 NA NA NA NA NA
## 3 NA NA NA NA NA
## 4 NA NA NA NA NA
## 5 NA NA NA NA NA
## ... ... ... ... ... ...
## 96 200.105 C10H16O4 even [M+H]+ 0.0007312
## 97 200.105 C10H16O4 even [M+H]+ 0.0005444
## 98 200.105 C10H16O4 even [M+H]+ 0.0005328
## 99 200.105 C10H16O4 even [M+H]+ 0.0014619
## 100 200.105 C10H16O4 even [M+H]+ 0.0020342
## ppm_error
## <numeric>
## 1 NA
## 2 NA
## 3 NA
## 4 NA
## 5 NA
## ... ...
## 96 3.63578
## 97 2.70695
## 98 2.64927
## 99 7.26908
## 100 10.11476
Individual columns can be simply extracted with the $
operator:
matched_features$target_name
## [1] NA NA NA NA NA
## [6] NA NA NA NA NA
## [11] NA NA NA NA NA
## [16] NA NA NA NA NA
## [21] NA NA NA NA NA
## [26] NA NA NA NA NA
## [31] NA NA NA NA NA
## [36] NA NA NA NA NA
## [41] NA NA NA NA NA
## [46] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
## [51] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
## [56] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
## [61] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
## [66] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
## [71] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
## [76] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
## [81] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
## [86] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
## [91] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
## [96] "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2" "FA 10:2;O2"
NA
is reported for query entries for which no match was found. See also the
help page for ?Matched
for more details and information. In addition to the
matching of query m/z against target exact masses as described above it would
also be possible to match directly query m/z against target m/z values by using
the MzParam
instead of the Mass2MzParam
.
If expected retention time values were available for the target compounds, an
annotation with higher confidence could be performed with matchValues()
and a
Mass2MzRtParam
parameter object. To illustrate this we randomly assign
retention times from query features to the target compounds adding also 2
seconds difference. In a real use case the target data.frame
would contain
masses (or m/z values) for standards along with the retention times when ions of
these standards were measured on the same LC-MS setup from which the query data
derives.
Below we subset our data table with the MS1 features to the first 100 rows (to keep the runtime of the vignette short).
ms1_subset <- ms1_features[1:100, ]
head(ms1_subset)
## feature_id mz rtime
## 1 Cluster_0001 102.1281 1.560147
## 2 Cluster_0002 102.1279 2.153590
## 3 Cluster_0003 102.1281 2.925570
## 4 Cluster_0004 102.1281 3.419617
## 5 Cluster_0005 102.1270 5.801039
## 6 Cluster_0006 102.1230 8.137535
The table contains thus retention times of the features in a column named
"rtime"
.
Next we randomly assign retention times of the features to compounds in our target data adding a deviation of 2 seconds. As described above, in a real use case retention times are supposed to be determined by measuring the compounds with the same LC-MS setup.
set.seed(123)
target_df$rtime <- sample(ms1_subset$rtime,
nrow(target_df), replace = TRUE) + 2
We have now retention times available for both the query and the target data and
can thus perform a matching based on m/z and retention times. We use the
Mass2MzRtParam
which allows us to specify (as for the
Mass2MzParam
) the expected adducts, the maximal acceptable m/z relative
and absolute deviation as well as the maximal acceptable (absolute) difference
in retention times. We use the settings from the previous section and allow a
difference of 10 seconds in retention times. The retention times are provided in
columns named "rtime"
which is different from the default ("rt"
). We thus
specify the name of the column containing the retention times with parameter
rtColname
.
parm <- Mass2MzRtParam(adducts = c("[M+H]+", "[M+Na]+"),
tolerance = 0.005, ppm = 0,
toleranceRt = 10)
matched_features <- matchValues(ms1_subset, target_df, param = parm,
rtColname = "rtime")
matched_features
## Object of class Matched
## Total number of matches: 31
## Number of query objects: 100 (31 matched)
## Number of target objects: 57599 (1 matched)
Less features were matched based on m/z and retention times.
matchedData(matched_features)[whichQuery(matched_features), ]
## DataFrame with 31 rows and 13 columns
## feature_id mz rtime target_headgroup target_name
## <character> <numeric> <numeric> <character> <character>
## 1 Cluster_00... 201.113 5.87206 FA FA 10:2;O2
## 2 Cluster_00... 201.113 5.93346 FA FA 10:2;O2
## 3 Cluster_00... 201.113 6.03653 FA FA 10:2;O2
## 4 Cluster_00... 201.114 6.16709 FA FA 10:2;O2
## 5 Cluster_00... 201.113 6.31781 FA FA 10:2;O2
## ... ... ... ... ... ...
## 27 Cluster_00... 201.113 11.2722 FA FA 10:2;O2
## 28 Cluster_00... 201.113 11.4081 FA FA 10:2;O2
## 29 Cluster_00... 201.113 11.4760 FA FA 10:2;O2
## 30 Cluster_00... 201.114 11.5652 FA FA 10:2;O2
## 31 Cluster_01... 201.114 11.7752 FA FA 10:2;O2
## target_exactmass target_formula target_chain_type target_rtime adduct
## <numeric> <character> <character> <numeric> <character>
## 1 200.105 C10H16O4 even 15.8624 [M+H]+
## 2 200.105 C10H16O4 even 15.8624 [M+H]+
## 3 200.105 C10H16O4 even 15.8624 [M+H]+
## 4 200.105 C10H16O4 even 15.8624 [M+H]+
## 5 200.105 C10H16O4 even 15.8624 [M+H]+
## ... ... ... ... ... ...
## 27 200.105 C10H16O4 even 15.8624 [M+H]+
## 28 200.105 C10H16O4 even 15.8624 [M+H]+
## 29 200.105 C10H16O4 even 15.8624 [M+H]+
## 30 200.105 C10H16O4 even 15.8624 [M+H]+
## 31 200.105 C10H16O4 even 15.8624 [M+H]+
## score ppm_error score_rt
## <numeric> <numeric> <numeric>
## 1 0.0004538 2.25645 -9.99030
## 2 0.0004407 2.19131 -9.92890
## 3 0.0005655 2.81186 -9.82583
## 4 0.0015560 7.73698 -9.69527
## 5 0.0006845 3.40357 -9.54455
## ... ... ... ...
## 27 0.0007312 3.63578 -4.59014
## 28 0.0005444 2.70695 -4.45431
## 29 0.0005328 2.64927 -4.38634
## 30 0.0014619 7.26908 -4.29719
## 31 0.0020342 10.11476 -4.08719
SummarizedExperiment
or QFeatures
objectsResults from LC-MS preprocessing (e.g. by the xcms
package) or generally metabolomics results might be best represented and bundled
as SummarizedExperiment
or QFeatures
objects (from the same-named
Bioconductor packages). A XCMSnExp
preprocessing result from xcms
can for
example be converted to a SummarizedExperiment
using the quantify()
method
from the xcms
package. The feature definitions (i.e. their m/z and retention
time values) will then be stored in the object’s rowData()
while the assay
(the numerical matrix) will contain the feature abundances across all
samples. Such SummarizedExperiment
objects can be simply passed as query
objects to the matchValues()
method. To illustrate this, we create below a
simple SummarizedExperiment
using the ms1_features
data frame from the
example above as rowData
and adding a matrix
with random values as assay.
library(SummarizedExperiment)
## Loading required package: MatrixGenerics
## Loading required package: matrixStats
##
## Attaching package: 'MatrixGenerics'
## The following objects are masked from 'package:matrixStats':
##
## colAlls, colAnyNAs, colAnys, colAvgsPerRowSet, colCollapse,
## colCounts, colCummaxs, colCummins, colCumprods, colCumsums,
## colDiffs, colIQRDiffs, colIQRs, colLogSumExps, colMadDiffs,
## colMads, colMaxs, colMeans2, colMedians, colMins, colOrderStats,
## colProds, colQuantiles, colRanges, colRanks, colSdDiffs, colSds,
## colSums2, colTabulates, colVarDiffs, colVars, colWeightedMads,
## colWeightedMeans, colWeightedMedians, colWeightedSds,
## colWeightedVars, rowAlls, rowAnyNAs, rowAnys, rowAvgsPerColSet,
## rowCollapse, rowCounts, rowCummaxs, rowCummins, rowCumprods,
## rowCumsums, rowDiffs, rowIQRDiffs, rowIQRs, rowLogSumExps,
## rowMadDiffs, rowMads, rowMaxs, rowMeans2, rowMedians, rowMins,
## rowOrderStats, rowProds, rowQuantiles, rowRanges, rowRanks,
## rowSdDiffs, rowSds, rowSums2, rowTabulates, rowVarDiffs, rowVars,
## rowWeightedMads, rowWeightedMeans, rowWeightedMedians,
## rowWeightedSds, rowWeightedVars
## Loading required package: GenomicRanges
## Loading required package: IRanges
## Loading required package: GenomeInfoDb
## Loading required package: Biobase
## Welcome to Bioconductor
##
## Vignettes contain introductory material; view with
## 'browseVignettes()'. To cite Bioconductor, see
## 'citation("Biobase")', and for packages 'citation("pkgname")'.
##
## Attaching package: 'Biobase'
## The following object is masked from 'package:MatrixGenerics':
##
## rowMedians
## The following objects are masked from 'package:matrixStats':
##
## anyMissing, rowMedians
## The following object is masked from 'package:AnnotationHub':
##
## cache
se <- SummarizedExperiment(
assays = matrix(rnorm(nrow(ms1_features) * 4), ncol = 4,
dimnames = list(NULL, c("A", "B", "C", "D"))),
rowData = ms1_features)
We can now use the same matchValues()
call as before to perform the
matching. Matching will be performed on the object’s rowData
, i.e. each
row/element of the SummarizedExperiment
will be matched against the target
using e.g. m/z values available in columns of the object’s rowData
:
parm <- Mass2MzParam(adducts = c("[M+H]+", "[M+Na]+"),
tolerance = 0.005, ppm = 0)
matched_features <- matchValues(se, target_df, param = parm)
matched_features
## Object of class Matched
## Total number of matches: 9173
## Number of query objects: 2842 (1969 matched)
## Number of target objects: 57599 (3296 matched)
As query
, the result contains the full SummarizedExperiment
, but
colnames()
and matchedData()
will access the respective information from the
rowData
of this SummarizedExperiment
:
colnames(matched_features)
## [1] "feature_id" "mz" "rtime"
## [4] "target_headgroup" "target_name" "target_exactmass"
## [7] "target_formula" "target_chain_type" "target_rtime"
## [10] "adduct" "score" "ppm_error"
matchedData(matched_features)
## DataFrame with 10046 rows and 12 columns
## feature_id mz rtime target_headgroup target_name
## <character> <numeric> <numeric> <character> <character>
## 1 Cluster_00... 102.128 1.56015 NA NA
## 2 Cluster_00... 102.128 2.15359 NA NA
## 3 Cluster_00... 102.128 2.92557 NA NA
## 4 Cluster_00... 102.128 3.41962 NA NA
## 5 Cluster_00... 102.127 5.80104 NA NA
## ... ... ... ... ... ...
## 10042 Cluster_28... 957.771 20.2705 TG TG 54:2;O3
## 10043 Cluster_28... 960.791 20.8865 HexCer HexCer 52:...
## 10044 Cluster_28... 961.361 13.0214 NA NA
## 10045 Cluster_28... 970.873 22.0981 ACer ACer 60:1;...
## 10046 Cluster_28... 972.734 15.6914 Hex2Cer Hex2Cer 42...
## target_exactmass target_formula target_chain_type target_rtime
## <numeric> <character> <character> <numeric>
## 1 NA NA NA NA
## 2 NA NA NA NA
## 3 NA NA NA NA
## 4 NA NA NA NA
## 5 NA NA NA NA
## ... ... ... ... ...
## 10042 934.784 C57H106O9 even 15.9950
## 10043 959.779 C58H105NO9 even 10.5076
## 10044 NA NA NA NA
## 10045 947.888 C60H117NO6 even 4.2806
## 10046 971.727 C54H101NO1... even 19.7329
## adduct score ppm_error
## <character> <numeric> <numeric>
## 1 NA NA NA
## 2 NA NA NA
## 3 NA NA NA
## 4 NA NA NA
## 5 NA NA NA
## ... ... ... ...
## 10042 [M+Na]+ -0.0021897 2.286241
## 10043 [M+H]+ 0.0045398 4.725089
## 10044 NA NA NA
## 10045 [M+Na]+ -0.0045054 4.640545
## 10046 [M+H]+ -0.0004240 0.435885
Subsetting the result object, to e.g. just matched elements will also subset the
SummarizedExperiment
.
matched_sub <- matched_features[whichQuery(matched_features)]
MetaboAnnotation::query(matched_sub)
## class: SummarizedExperiment
## dim: 1969 4
## metadata(0):
## assays(1): ''
## rownames: NULL
## rowData names(3): feature_id mz rtime
## colnames(4): A B C D
## colData names(0):
A QFeatures
object is essentially a container for several
SummarizedExperiment
objects which rows (features) are related with each
other. Such an object could thus for example contain the full feature data from
an LC-MS experiment as one assay and a compounded feature data in which data
from ions of the same compound are aggregated as an additional
assay. Below we create such an object using our SummarizedExperiment
as an
assay of name "features"
. For now we don’t add any additional assay to that
QFeatures
, thus, the object contains only this single data set.
library(QFeatures)
## Loading required package: MultiAssayExperiment
##
## Attaching package: 'QFeatures'
## The following object is masked from 'package:MultiAssayExperiment':
##
## longFormat
## The following object is masked from 'package:base':
##
## sweep
qf <- QFeatures(list(features = se))
qf
## An instance of class QFeatures containing 1 assays:
## [1] features: SummarizedExperiment with 2842 rows and 4 columns
matchValues()
supports also matching of QFeatures
objects but the user
needs to define the assay which should be used for the matching with the
queryAssay
parameter.
matched_qf <- matchValues(qf, target_df, param = parm, queryAssay = "features")
matched_qf
## Object of class Matched
## Total number of matches: 9173
## Number of query objects: 2842 (1969 matched)
## Number of target objects: 57599 (3296 matched)
colnames()
and matchedData()
allow to access the rowData
of the
SummarizedExperiment
stored in the QFeatures
’ "features"
assay:
colnames(matched_qf)
## [1] "feature_id" "mz" "rtime"
## [4] "target_headgroup" "target_name" "target_exactmass"
## [7] "target_formula" "target_chain_type" "target_rtime"
## [10] "adduct" "score" "ppm_error"
matchedData(matched_qf)
## DataFrame with 10046 rows and 12 columns
## feature_id mz rtime target_headgroup target_name
## <character> <numeric> <numeric> <character> <character>
## 1 Cluster_00... 102.128 1.56015 NA NA
## 2 Cluster_00... 102.128 2.15359 NA NA
## 3 Cluster_00... 102.128 2.92557 NA NA
## 4 Cluster_00... 102.128 3.41962 NA NA
## 5 Cluster_00... 102.127 5.80104 NA NA
## ... ... ... ... ... ...
## 10042 Cluster_28... 957.771 20.2705 TG TG 54:2;O3
## 10043 Cluster_28... 960.791 20.8865 HexCer HexCer 52:...
## 10044 Cluster_28... 961.361 13.0214 NA NA
## 10045 Cluster_28... 970.873 22.0981 ACer ACer 60:1;...
## 10046 Cluster_28... 972.734 15.6914 Hex2Cer Hex2Cer 42...
## target_exactmass target_formula target_chain_type target_rtime
## <numeric> <character> <character> <numeric>
## 1 NA NA NA NA
## 2 NA NA NA NA
## 3 NA NA NA NA
## 4 NA NA NA NA
## 5 NA NA NA NA
## ... ... ... ... ...
## 10042 934.784 C57H106O9 even 15.9950
## 10043 959.779 C58H105NO9 even 10.5076
## 10044 NA NA NA NA
## 10045 947.888 C60H117NO6 even 4.2806
## 10046 971.727 C54H101NO1... even 19.7329
## adduct score ppm_error
## <character> <numeric> <numeric>
## 1 NA NA NA
## 2 NA NA NA
## 3 NA NA NA
## 4 NA NA NA
## 5 NA NA NA
## ... ... ... ...
## 10042 [M+Na]+ -0.0021897 2.286241
## 10043 [M+H]+ 0.0045398 4.725089
## 10044 NA NA NA
## 10045 [M+Na]+ -0.0045054 4.640545
## 10046 [M+H]+ -0.0004240 0.435885
In this section we match experimental MS/MS spectra against reference spectra. This can also be performed with functions from the Spectra package (see SpectraTutorials, but the functions and concepts used here are more suitable to the end user as they simplify the handling of the spectra matching results.
Below we load spectra from a file from a reversed-phase (DDA) LC-MS/MS run of
the Agilent Pesticide mix. With filterMsLevel()
we subset the data set to only
MS2 spectra. To reduce processing time of the example we further subset the
Spectra
to a small set of selected MS2 spectra. In addition we assign feature
identifiers to each spectrum (again, for this example these are arbitrary IDs,
but in a real data analysis such identifiers could indicate to which LC-MS
feature these spectra belong).
library(Spectra)
library(msdata)
fl <- system.file("TripleTOF-SWATH", "PestMix1_DDA.mzML", package = "msdata")
pest_ms2 <- filterMsLevel(Spectra(fl), 2L)
## subset to selected spectra.
pest_ms2 <- pest_ms2[c(808, 809, 945:955)]
## assign arbitrary *feature IDs* to each spectrum.
pest_ms2$feature_id <- c("FT001", "FT001", "FT002", "FT003", "FT003", "FT003",
"FT004", "FT004", "FT004", "FT005", "FT005", "FT006",
"FT006")
## assign also *spectra IDs* to each
pest_ms2$spectrum_id <- paste0("sp_", seq_along(pest_ms2))
pest_ms2
## MSn data (Spectra) with 13 spectra in a MsBackendMzR backend:
## msLevel rtime scanIndex
## <integer> <numeric> <integer>
## 1 2 361.651 2853
## 2 2 361.741 2854
## 3 2 377.609 3030
## 4 2 377.699 3031
## 5 2 378.120 3033
## ... ... ... ...
## 9 2 378.959 3039
## 10 2 379.379 3041
## 11 2 380.059 3045
## 12 2 380.609 3048
## 13 2 381.029 3050
## ... 35 more variables/columns.
##
## file(s):
## PestMix1_DDA.mzML
## Processing:
## Filter: select MS level(s) 2 [Thu Nov 21 18:28:28 2024]
This Spectra
should now represent MS2 spectra associated
with LC-MS features from an untargeted LC-MS/MS experiment that we would like to
annotate by matching them against a spectral reference library.
We thus load below a Spectra
object that represents MS2 data from a very small
subset of MassBank release 2021.03. This
small Spectra
object is provided within this package but it would be possible
to use any other Spectra
object with reference fragment spectra instead (see
also the SpectraTutorials
workshop). As an alternative, it would also be possible to use a CompDb
object
representing a compound annotation database (defined in the
CompoundDb package) with parameter target
. See the
matchSpectra()
help page or section Query against multiple reference
databases below for more details and options to retrieve such annotation
resources from Bioconductor’s AnnotationHub.
load(system.file("extdata", "minimb.RData", package = "MetaboAnnotation"))
minimb
## MSn data (Spectra) with 100 spectra in a MsBackendDataFrame backend:
## msLevel rtime scanIndex
## <integer> <numeric> <integer>
## 1 2 NA NA
## 2 2 NA NA
## 3 2 NA NA
## 4 2 NA NA
## 5 2 NA NA
## ... ... ... ...
## 96 NA NA NA
## 97 2 NA NA
## 98 2 NA NA
## 99 2 NA NA
## 100 2 NA NA
## ... 42 more variables/columns.
## Processing:
## Filter: select spectra with polarity 1 [Wed Mar 31 10:06:28 2021]
## Switch backend from MsBackendMassbankSql to MsBackendDataFrame [Wed Mar 31 10:07:59 2021]
We can now use the matchSpectra()
function to match each of our experimental
query spectra against the target (reference) spectra. Settings for this
matching can be defined with a dedicated param object. We use below the
CompareSpectraParam
that uses the compareSpectra()
function from the
Spectra
package to calculate similarities between each query spectrum and all
target spectra. CompareSpectraParam
allows to set all individual settings for
the compareSpectra()
call with parameters MAPFUN
, ppm
, tolerance
and
FUN
(see the help on compareSpectra()
in the Spectra package
for more details). In addition, we can pre-filter the target spectra for each
individual query spectrum to speed-up the calculations. By setting
requirePrecursor = TRUE
we compare below each query spectrum only to target
spectra with matching precursor m/z (accepting a deviation defined by parameters
ppm
and tolerance
). By default, matchSpectra()
with CompareSpectraParam
considers spectra with a similarity score higher than 0.7 as matching and
these are thus reported.
csp <- CompareSpectraParam(requirePrecursor = TRUE, ppm = 10)
mtches <- matchSpectra(pest_ms2, minimb, param = csp)
mtches
## Object of class MatchedSpectra
## Total number of matches: 16
## Number of query objects: 13 (5 matched)
## Number of target objects: 100 (11 matched)
The results are reported as a MatchedSpectra
object which represents the
matching results for all query spectra. This type of object contains all query
spectra, all target spectra, the matching information and the parameter object
with the settings of the matching. The object can be subsetted to e.g. matching
results for a specific query spectrum:
mtches[1]
## Object of class MatchedSpectra
## Total number of matches: 0
## Number of query objects: 1 (0 matched)
## Number of target objects: 100 (0 matched)
In this case, for the first query spectrum, no match was found among the target
spectra. Below we subset the MatchedSpectra
to results for the second query
spectrum:
mtches[2]
## Object of class MatchedSpectra
## Total number of matches: 4
## Number of query objects: 1 (1 matched)
## Number of target objects: 100 (4 matched)
The second query spectrum could be matched to 4 target spectra. The matching between query and target spectra can be n:m, i.e. each query spectrum can match no or multiple target spectra and each target spectrum can be matched to none, one or multiple query spectra.
Data (spectra variables of either the query and/or the target spectra) can be
extracted from the result object with the spectraData()
function or with $
(similar to a Spectra
object). The spectraVariables
function can be used to
list all available spectra variables in the result object:
spectraVariables(mtches)
## [1] "msLevel" "rtime"
## [3] "acquisitionNum" "scanIndex"
## [5] "dataStorage" "dataOrigin"
## [7] "centroided" "smoothed"
## [9] "polarity" "precScanNum"
## [11] "precursorMz" "precursorIntensity"
## [13] "precursorCharge" "collisionEnergy"
## [15] "isolationWindowLowerMz" "isolationWindowTargetMz"
## [17] "isolationWindowUpperMz" "peaksCount"
## [19] "totIonCurrent" "basePeakMZ"
## [21] "basePeakIntensity" "ionisationEnergy"
## [23] "lowMZ" "highMZ"
## [25] "mergedScan" "mergedResultScanNum"
## [27] "mergedResultStartScanNum" "mergedResultEndScanNum"
## [29] "injectionTime" "filterString"
## [31] "spectrumId" "ionMobilityDriftTime"
## [33] "scanWindowLowerLimit" "scanWindowUpperLimit"
## [35] "feature_id" "spectrum_id"
## [37] ".original_query_index" "target_msLevel"
## [39] "target_rtime" "target_acquisitionNum"
## [41] "target_scanIndex" "target_dataStorage"
## [43] "target_dataOrigin" "target_centroided"
## [45] "target_smoothed" "target_polarity"
## [47] "target_precScanNum" "target_precursorMz"
## [49] "target_precursorIntensity" "target_precursorCharge"
## [51] "target_collisionEnergy" "target_isolationWindowLowerMz"
## [53] "target_isolationWindowTargetMz" "target_isolationWindowUpperMz"
## [55] "target_spectrum_id" "target_spectrum_name"
## [57] "target_date" "target_authors"
## [59] "target_license" "target_copyright"
## [61] "target_publication" "target_splash"
## [63] "target_compound_id" "target_adduct"
## [65] "target_ionization" "target_ionization_voltage"
## [67] "target_fragmentation_mode" "target_collision_energy_text"
## [69] "target_instrument" "target_instrument_type"
## [71] "target_formula" "target_exactmass"
## [73] "target_smiles" "target_inchi"
## [75] "target_inchikey" "target_cas"
## [77] "target_pubchem" "target_synonym"
## [79] "target_precursor_mz_text" "target_compound_name"
## [81] "score"
This lists the spectra variables from both the query and the target
spectra, with the prefix "target_"
being used for spectra variable names of
the target spectra. Spectra variable "score"
contains the similarity score.
Note that by default also an additional column ".original_query_index"
is
added to the query
Spectra
object by the matchSpectra()
function, that
enables an easier mapping of results to the original query object used as
input, in particular, if the MatchedSpectra
object gets further subset. As the
name says, this column contains for each query spectrum the index in the
original Spectra
object provided with the query
parameter.
We could thus use $target_compound_name
to extract the compound name of the
matching target spectra for the second query spectrum:
mtches[2]$target_compound_name
## [1] "Azaconazole" "Azaconazole" "Azaconazole" "Azaconazole"
The same information can also be extracted on the full MatchedSpectra
.
Below we use $spectrum_id
to extract the query spectra identifiers we added
above from the full result object.
mtches$spectrum_id
## [1] "sp_1" "sp_2" "sp_2" "sp_2" "sp_2" "sp_3" "sp_4" "sp_4" "sp_5"
## [10] "sp_6" "sp_6" "sp_6" "sp_7" "sp_8" "sp_8" "sp_8" "sp_8" "sp_8"
## [19] "sp_9" "sp_9" "sp_10" "sp_11" "sp_12" "sp_13"
We added this column manually to the query object before the matchSpectra()
call, but the automatically added spectra variable ".original_query_index"
would provide the same information:
mtches$.original_query_index
## [1] 1 2 2 2 2 3 4 4 5 6 6 6 7 8 8 8 8 8 9 9 10 11 12 13
And the respective values in the query object:
query(mtches)$.original_query_index
## [1] 1 2 3 4 5 6 7 8 9 10 11 12 13
Because of the n:m mapping between query and target spectra, the number of
values returned by $
(or spectraData
) can be larger than the total number of
query spectra. Also in the example above, some of the spectra IDs are present
more than once in the result returned by $spectrum_id
. The respective spectra
could be matched to more than one target spectrum (based on our settings) and
hence their IDs are reported multiple times. Both spectraData
and $
for
MatchedSpectra
use a left join strategy to report/return values: a value
(row) is reported for each query spectrum (even if it does not match any
target spectrum) with eventually duplicated values (rows) if the query spectrum
matches more than one target spectrum (each value for a query spectrum is
repeated as many times as it matches target spectra). To illustrate this we
use below the spectraData()
function to extract specific data from our
result object, i.e. the spectrum and feature IDs for the query spectra we
defined above, the MS2 spectra similarity score, and the target spectra’s ID and
compound name.
mtches_df <- spectraData(mtches, columns = c("spectrum_id", "feature_id",
"score", "target_spectrum_id",
"target_compound_name"))
as.data.frame(mtches_df)
## spectrum_id feature_id score target_spectrum_id target_compound_name
## 1 sp_1 FT001 NA <NA> <NA>
## 2 sp_2 FT001 0.7869556 LU056604 Azaconazole
## 3 sp_2 FT001 0.8855473 LU056603 Azaconazole
## 4 sp_2 FT001 0.7234894 LU056602 Azaconazole
## 5 sp_2 FT001 0.7219942 LU056605 Azaconazole
## 6 sp_3 FT002 NA <NA> <NA>
## 7 sp_4 FT003 0.7769746 KW108103 triphenylphosphineoxide
## 8 sp_4 FT003 0.7577286 KW108102 triphenylphosphineoxide
## 9 sp_5 FT003 NA <NA> <NA>
## 10 sp_6 FT003 0.7433718 SM839501 Dimethachlor
## 11 sp_6 FT003 0.7019807 EA070705 Dimethachlor
## 12 sp_6 FT003 0.7081274 EA070711 Dimethachlor
## 13 sp_7 FT004 NA <NA> <NA>
## 14 sp_8 FT004 0.7320465 SM839501 Dimethachlor
## 15 sp_8 FT004 0.8106258 EA070705 Dimethachlor
## 16 sp_8 FT004 0.7290458 EA070710 Dimethachlor
## 17 sp_8 FT004 0.8168876 EA070711 Dimethachlor
## 18 sp_8 FT004 0.7247800 EA070704 Dimethachlor
## 19 sp_9 FT004 0.7412586 KW108103 triphenylphosphineoxide
## 20 sp_9 FT004 0.7198787 KW108102 triphenylphosphineoxide
## 21 sp_10 FT005 NA <NA> <NA>
## 22 sp_11 FT005 NA <NA> <NA>
## 23 sp_12 FT006 NA <NA> <NA>
## 24 sp_13 FT006 NA <NA> <NA>
Using the plotSpectraMirror()
function we can visualize the matching results
for one query spectrum. Note also that an interactive, shiny
-based, validation
of matching results is available with the validateMatchedSpectra()
function. Below we call this function to show all matches for the second
spectrum.
plotSpectraMirror(mtches[2])
Not unexpectedly, the peak intensities of query and target spectra are on
different scales. While this was no problem for the similarity calculation (the
normalized dot-product which is used by default is independent of the absolute
peak values) it is not ideal for visualization. Thus, we apply below a simple
scaling function to both the query and target spectra and plot the
spectra again afterwards (see the help for addProcessing()
in the Spectra
package for more details on spectra data manipulations). This function will
replace the absolute spectra intensities with intensities relative to the
maximum intensity of each spectrum. Note that functions for addProcessing()
should include (like in the example below) the ...
parameter.
scale_int <- function(x, ...) {
x[, "intensity"] <- x[, "intensity"] / max(x[, "intensity"], na.rm = TRUE)
x
}
mtches <- addProcessing(mtches, scale_int)
plotSpectraMirror(mtches[2])
The query spectrum seems to nicely match the identified target spectra. Below we extract the compound name of the target spectra for this second query spectrum.
mtches[2]$target_compound_name
## [1] "Azaconazole" "Azaconazole" "Azaconazole" "Azaconazole"
As alternative to the CompareSpectraParam
we could also use the
MatchForwardReverseParam
with matchSpectra()
. This has the same settings and
performs the same spectra similarity search than CompareSpectraParam
, but
reports in addition (similar to MS-DIAL) to the (forward) similarity score
also the reverse spectra similarity score as well as the presence ratio for
matching spectra. While the default forward score is calculated considering
all peaks from the query and the target spectrum (the peak mapping is performed
using an outer join strategy), the reverse score is calculated only on peaks
that are present in the target spectrum and the matching peaks from the query
spectrum (the peak mapping is performed using a right join strategy). The
presence ratio is the ratio between the number of mapped peaks between the
query and the target spectrum and the total number of peaks in the target
spectrum. These values are available as spectra variables "reverse_score"
and
"presence_ratio"
in the result object). Below we perform the same spectra
matching as above, but using the MatchForwardReverseParam
.
mp <- MatchForwardReverseParam(requirePrecursor = TRUE, ppm = 10)
mtches <- matchSpectra(pest_ms2, minimb, param = mp)
mtches
## Object of class MatchedSpectra
## Total number of matches: 16
## Number of query objects: 13 (5 matched)
## Number of target objects: 100 (11 matched)
Below we extract the query and target spectra IDs, the compound name and all scores.
as.data.frame(
spectraData(mtches, c("spectrum_id", "target_spectrum_id",
"target_compound_name", "score", "reverse_score",
"presence_ratio")))
## spectrum_id target_spectrum_id target_compound_name score
## 1 sp_1 <NA> <NA> NA
## 2 sp_2 LU056604 Azaconazole 0.7869556
## 3 sp_2 LU056603 Azaconazole 0.8855473
## 4 sp_2 LU056602 Azaconazole 0.7234894
## 5 sp_2 LU056605 Azaconazole 0.7219942
## 6 sp_3 <NA> <NA> NA
## 7 sp_4 KW108103 triphenylphosphineoxide 0.7769746
## 8 sp_4 KW108102 triphenylphosphineoxide 0.7577286
## 9 sp_5 <NA> <NA> NA
## 10 sp_6 SM839501 Dimethachlor 0.7433718
## 11 sp_6 EA070705 Dimethachlor 0.7019807
## 12 sp_6 EA070711 Dimethachlor 0.7081274
## 13 sp_7 <NA> <NA> NA
## 14 sp_8 SM839501 Dimethachlor 0.7320465
## 15 sp_8 EA070705 Dimethachlor 0.8106258
## 16 sp_8 EA070710 Dimethachlor 0.7290458
## 17 sp_8 EA070711 Dimethachlor 0.8168876
## 18 sp_8 EA070704 Dimethachlor 0.7247800
## 19 sp_9 KW108103 triphenylphosphineoxide 0.7412586
## 20 sp_9 KW108102 triphenylphosphineoxide 0.7198787
## 21 sp_10 <NA> <NA> NA
## 22 sp_11 <NA> <NA> NA
## 23 sp_12 <NA> <NA> NA
## 24 sp_13 <NA> <NA> NA
## reverse_score presence_ratio
## 1 NA NA
## 2 0.8764394 0.5833333
## 3 0.9239592 0.6250000
## 4 0.7573541 0.6250000
## 5 0.9519647 0.4285714
## 6 NA NA
## 7 0.9025051 0.7500000
## 8 0.9164348 0.5000000
## 9 NA NA
## 10 0.8915201 0.5000000
## 11 0.8687003 0.3333333
## 12 0.8687472 0.3703704
## 13 NA NA
## 14 0.8444402 0.5000000
## 15 0.9267965 0.5000000
## 16 0.8765496 0.7500000
## 17 0.9236674 0.4814815
## 18 0.8714208 0.8571429
## 19 0.8743130 0.7500000
## 20 0.8937751 0.5000000
## 21 NA NA
## 22 NA NA
## 23 NA NA
## 24 NA NA
In these examples we matched query spectra only to target spectra if their
precursor m/z is ~ equal and reported only matches with a similarity higher than
0.7. CompareSpectraParam
, through its parameter THRESHFUN
would however also
allow other types of analyses. We could for example also report the best
matching target spectrum for each query spectrum, independently of whether the
similarity score is higher than a certain threshold. Below we perform such an
analysis defining a THRESHFUN
that selects always the best match.
select_top_match <- function(x) {
which.max(x)
}
csp2 <- CompareSpectraParam(ppm = 10, requirePrecursor = FALSE,
THRESHFUN = select_top_match)
mtches <- matchSpectra(pest_ms2, minimb, param = csp2)
res <- spectraData(mtches, columns = c("spectrum_id", "target_spectrum_id",
"target_compound_name", "score"))
as.data.frame(res)
## spectrum_id target_spectrum_id target_compound_name
## 1 sp_1 SM839603 Flufenacet
## 2 sp_2 LU056603 Azaconazole
## 3 sp_3 SM839501 Dimethachlor
## 4 sp_4 KW108103 triphenylphosphineoxide
## 5 sp_5 LU100202 2,2'-(Tetradecylimino)diethanol
## 6 sp_6 SM839501 Dimethachlor
## 7 sp_7 RP005503 Glycoursodeoxycholic acid
## 8 sp_8 EA070711 Dimethachlor
## 9 sp_9 KW108103 triphenylphosphineoxide
## 10 sp_10 JP006901 1-PHENYLETHYL ACETATE
## 11 sp_11 EA070711 Dimethachlor
## 12 sp_12 EA070705 Dimethachlor
## 13 sp_13 LU101704 2-Ethylhexyl 4-(dimethylamino)benzoate
## score
## 1 0.000000e+00
## 2 8.855473e-01
## 3 6.313687e-01
## 4 7.769746e-01
## 5 1.772117e-05
## 6 7.433718e-01
## 7 1.906998e-03
## 8 8.168876e-01
## 9 7.412586e-01
## 10 4.085289e-04
## 11 4.323403e-01
## 12 3.469648e-03
## 13 7.612480e-06
Note that this whole example would work on any Spectra
object with MS2
spectra. Such objects could also be extracted from an xcms
-based LC-MS/MS data
analysis with the chromPeaksSpectra()
or featureSpectra()
functions from the
xcms package. Note also that retention times could in addition be
considered in the matching by selecting a non-infinite value for the
toleranceRt
of any of the parameter classes. By default this uses the
retention times provided by the query and target spectra (i.e. spectra variable
"rtime"
) but it is also possible to specify any other spectra variable for the
additional retention time matching (e.g. retention indices instead of times)
using the rtColname
parameter of the matchSpectra(0
function (see
?matchSpectra
help page for more information).
Matches can be also further validated using an interactive Shiny app by calling
validateMatchedSpectra()
on the MatchedSpectra
object. Individual matches
can be set to TRUE or FALSE in this app. By closing the app via the Save & Close
button a filtered MatchedSpectra
is returned, containing only matches manually
validated.
Getting access to reference spectra can sometimes be a little cumbersome since
it might involve lookup and download of specific resources or eventual
conversion of these into a format suitable for import. MetaboAnnotation
provides compound annotation sources to simplify this process. These
annotation source objects represent references (links) to annotation resources
and can be used in the matchSpectra()
call to define the targed/reference
spectra. The annotation source object takes then care, upon request, of
retrieving the annotation data or connecting to the annotation resources.
Also, compound annotation sources can be combined to allow matching query spectra against multiple reference libraries in a single call.
At present MetaboAnnotation
supports the following types of compound
annotation sources (i.e. objects extending CompAnnotationSource
):
Annotation resources that provide their data as a CompDb
database (defined
by the CompoundDb) package. These are supported by
the CompDbSource
class.
Annotation resources for which a dedicated MsBackend
backend is available
hence supporting to access the data via a Spectra
object. These are
supported by the SpectraDbSource
class.
Various helper functions, specific for the annotation resource, are available to create such annotation source objects:
CompDbSource
: creates a compound annotation source object from the provided
CompDb
SQLite data base file. This function can be used to integrate an
existing (locally available) CompDb
annotation database into an annotation
workflow.
MassBankSource
: creates a annotation source object for a specific MassBank
release. The desired release can be specified with the release
parameter
(e.g. release = "2021.03"
or release = "2022.06"
). The function will then
download the respective annotation database from Bioconductor’s
AnnotationHub.
In the example below we create a annotation source for MassBank release
2022.06. This call will lookup the requested version in Biocondutor’s (online)
AnnotationHub
and download the data. Subsequent requests for the same
annotation resource will load the locally cached version instead. Upcoming
MassBank database releases will be added to AnnotationHub
after their official
release and all previous releases will be available as well.
mbank <- MassBankSource("2022.06")
mbank
## Object of class CompDbSource
## Metadata information:
## - source: MassBank
## - url: https://massbank.eu/MassBank/
## - source_version: 2022.06
## - source_date: 2022-06-21
## - organism: NA
## - db_creation_date: Tue Aug 30 06:51:39 2022
## - supporting_package: CompoundDb
## - supporting_object: CompDb
We can now use that annotation source object in the matchSpectra()
call to
compare the experimental spectra from the previous examples against that release
of MassBank.
res <- matchSpectra(
pest_ms2, mbank,
param = CompareSpectraParam(requirePrecursor = TRUE, ppm = 10))
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
## 'MsBackendCompDb' does not support parallel processing. Switching to serial processing.
res
## Object of class MatchedSpectra
## Total number of matches: 14
## Number of query objects: 13 (6 matched)
## Number of target objects: 10 (10 matched)
The result object contains only the matching fragment spectra from the reference database.
target(res)
## MSn data (Spectra) with 10 spectra in a MsBackendDataFrame backend:
## msLevel rtime scanIndex
## <integer> <numeric> <integer>
## 1 2 NA NA
## 2 2 NA NA
## 3 2 NA NA
## 4 2 NA NA
## 5 2 NA NA
## 6 2 NA NA
## 7 2 NA NA
## 8 2 NA NA
## 9 2 NA NA
## 10 2 NA NA
## ... 46 more variables/columns.
## Processing:
## Switch backend from MsBackendCompDb to MsBackendDataFrame [Thu Nov 21 18:28:39 2024]
And the names of the compounds with matching fragment spectra.
matchedData(res)$target_name
## [1] NA "Azaconazole"
## [3] "Azaconazole" "Azaconazole"
## [5] "Azaconazole" NA
## [7] "triphenylphosphineoxide" "triphenylphosphineoxide"
## [9] "Triphenylphosphine oxide" "N,N-Dimethyldodecylamine"
## [11] "Dimethachlor" NA
## [13] "Dimethachlor" "Triphenylphosphine oxide"
## [15] "triphenylphosphineoxide" "triphenylphosphineoxide"
## [17] "Triphenylphosphine oxide" NA
## [19] NA NA
## [21] NA
Sometimes it is needed to identify fragment spectra in a Spectra
object for
selected (precursor) m/z values and retention times. An example would be if
compound quantification was performed with a LC-MS run and in a second LC-MS/MS
run (with the same chromatographic setup) fragment spectra of the same samples
were generated. From the first LC-MS data set features (or chromatographic
peaks) would be identified for which it would be necessary to retrieve fragment
spectra matching the m/z and retention times of these from the second, LC-MS/MS
data set (assuming that no big retention time shifts between the measurement
runs are expected). To illustrate this, we below first define a data.frame
that should represent a feature table such as defined by an analysis with the
xcms package.
fts <- data.frame(
feature_id = c("FT001", "FT002", "FT003", "FT004", "FT005"),
mzmed = c(313.43, 256.11, 224.08, 159.22, 224.08),
rtmed = c(38.5, 379.1, 168.2, 48.2, 381.1))
We next match the features from this data frame against the Spectra
object
using an MzRtParam
to identify fragment spectra with their precursor m/z and
retention times matching (with some tolerance) the values from the features.
fts_mtch <- matchValues(fts, pest_ms2, MzRtParam(ppm = 50, toleranceRt = 3),
mzColname = c("mzmed", "precursorMz"),
rtColname = c("rtmed", "rtime"))
fts_mtch
## Object of class Matched
## Total number of matches: 5
## Number of query objects: 5 (2 matched)
## Number of target objects: 13 (5 matched)
whichQuery(fts_mtch)
## [1] 2 5
Thus, we found fragment spectra matching the m/z and retention times for the 2nd
and 5th feature. To extract the Spectra
matching these features, it would be
best to first reduce the object to features with at least one matching fragment
spectrum. The indices of query elements (in our case features) with matches can
be returned using the whichQuery()
function. We use these below to subset our
matched result keeping only features for which matches were found:
fts_mtched <- fts_mtch[whichQuery(fts_mtch)]
fts_mtched
## Object of class Matched
## Total number of matches: 5
## Number of query objects: 2 (2 matched)
## Number of target objects: 13 (5 matched)
The feature IDs for the matched spectra can be extracted using:
fts_mtched$feature_id
## [1] "FT002" "FT002" "FT002" "FT005" "FT005"
We next need to extract the matching fragment spectra from the target
Spectra
object. Here we use the targetIndex()
function, that returns the
indices of the target spectra that were matched to the query.
targetIndex(fts_mtched)
## [1] 3 6 8 7 11
We extract thus next the fragment spectra matching at least one feature:
fts_ms2 <- target(fts_mtched)[targetIndex(fts_mtched)]
fts_ms2
## MSn data (Spectra) with 5 spectra in a MsBackendMzR backend:
## msLevel rtime scanIndex
## <integer> <numeric> <integer>
## 1 2 377.609 3030
## 2 2 378.539 3035
## 3 2 378.869 3038
## 4 2 378.779 3037
## 5 2 380.059 3045
## ... 35 more variables/columns.
##
## file(s):
## PestMix1_DDA.mzML
## Processing:
## Filter: select MS level(s) 2 [Thu Nov 21 18:28:28 2024]
While we have now the spectra, we can’t relate them (yet) to the features we
used as query
. Extracting the "feature_id"
column using the $
function
from the the matched object would however return, for each match (since we
restricted the matched object to contain only features with matches) the feature
ID (provided in the original data frame). We can thus add this information as an
additional spectra variable to our Spectra
object:
fts_ms2$feature_id <- fts_mtched$feature_id
Be aware that extracting the "feature_id"
column from the matched object
before restricting to features with matches would also return the values for
features for which no MS2 spectrum was found:
fts_mtch$feature_id
## [1] "FT001" "FT002" "FT002" "FT002" "FT003" "FT004" "FT005" "FT005"
Without the initial subsetting of the matched object to features with at least one matching spectra, the extraction would be a bit more complicated:
fts_ms2 <- target(fts_mtch)[targetIndex(fts_mtch)]
fts_ms2$feature_id <- query(fts_mtch)$feature_id[queryIndex(fts_mtch)]
fts_ms2$feature_id
## [1] "FT002" "FT002" "FT002" "FT005" "FT005"
This Spectra
could next be used to match the fragment spectra from the
experiment to e.g. a reference database and with the assigned spectra variable
"feature_id"
it would allow to map the results back to the quantified feature
matrix from the LC-MS run.
Pre-filtering the target spectra based on similar precursor m/z (using
requirePrecursor = TRUE
generally speeds up the call because a spectra
comparison needs only to be performed on subsets of target spectra. Performance
of the matchSpectra()
function depends however also on the backend used for
the query and target Spectra
. For some backends the peaks data (i.e. m/z and
intensity values) might not be already loaded into memory and hence spectra
comparisons might be slower because that data needs to be first loaded. As an
example, for Spectra
objects, such as our pest_ms2
variable, that use the
MsBackendMzR
backend, the peaks data needs to be loaded from the raw data files
before the spectra similarity scores can be calculated. Changing the backend to
an in-memory data representation before matchSpectra()
can thus improve the
performance (at the cost of a higher memory demand).
Below we change the backends of the pest_ms2
and minimb
objects to
MsBackendMemory
which keeps all data (spectra and peaks data) in memory and we
compare the performance against the originally used MsBackendMzR
(for
pest_ms2
) and MsBackendDataFrame
(for minimb
).
pest_ms2_mem <- setBackend(pest_ms2, MsBackendMemory())
minimb_mem <- setBackend(minimb, MsBackendMemory())
library(microbenchmark)
microbenchmark(compareSpectra(pest_ms2, minimb, param = csp),
compareSpectra(pest_ms2_mem, minimb_mem, param = csp),
times = 5)
## Unit: milliseconds
## expr min lq
## compareSpectra(pest_ms2, minimb, param = csp) 69.63141 70.63878
## compareSpectra(pest_ms2_mem, minimb_mem, param = csp) 42.82232 44.01335
## mean median uq max neval cld
## 81.80703 71.04759 74.25725 123.46015 5 a
## 50.11218 44.70132 49.73806 69.28583 5 b
There is a considerable performance gain by using the MsBackendMemory
over the
two other backends, that comes however at the cost of a higher memory
demand. Thus, for large data sets (or reference libraries) this might not be an
option. See also issue
#93 in the
MetaboAnnotation
github repository for more benchmarks and information on
performance of matchSpectra()
.
If for target
a Spectra
using a SQL database-based backend is used (such as
a MsBackendMassbankSql
, MsBackendCompDb
or MsBackendSql
) and spectra
matching is performed with requirePrecursorMz = TRUE
, simply caching the
precursor m/z values of all target spectra in memory improves the performance of
matchSpectra
considerably. This can be easily done with e.g.
target_sps$precursorMz <- precursorMz(target_sps)
where target_sps
is the
Spectra
object that uses one of the above mentioned backends. With this call
all precursor m/z values will be cached within target_sps
and any
precursorMz(target_sps)
call (which is used by matchSpectra()
to select the
candidate spectra against which to compare a query spectrum) will not require
a separate SQL call.
Parallel processing can also improve performance, but might not be possible for all backends. In particular, backends based on SQL databases don’t allow parallel processing because the database connection can not be shared across different processes.
MetaboAnnotation provides also other utility functions not directly related to the annotation process. These are presented in this section.
The function createStandardMixes()
allows for grouping of standard compounds
with a minimum difference in m/z based on user input.
library(MetaboCoreUtils)
As an example here I will extract a list of a 100 standard compounds with their formula from a tab delimited text file provided with the package. Such files could also be imported from an xlsx sheet using the readxl package.
standard <- read.table(system.file("extdata", "Standard_list_example.txt",
package = "MetaboAnnotation"),
header = TRUE, sep = "\t", quote = "")
We will use functions from the MetaboCoreUtil package to get the mass of each compounds and the m/z for the adducts wanted.
#' Calculate mass based on formula of compounds
standard$mass <- calculateMass(standard$formula)
#' Create input for function
#' Calculate charge for 2 adducts
standard_charged <- mass2mz(standard$mass, adduct = c("[M+H]+", "[M+Na]+"))
#' have compounds names as rownames
rownames(standard_charged) <- standard[ , 1]
#' ensure the input `x` is a matrix
if (!is.matrix(standard_charged))
standard_charged <- as.matrix(standard_charged)
The input table for the createStandardMixes should thus look like the one shown below, i.e. should be a numeric matrix with each row representing one compound. Columns are expected to contain m/z values for different adducts of that compound. Importantly, the row names of the matrix should represent the (unique) compound names (or any other unique identifier for the compound).
standard_charged
## [M+H]+ [M+Na]+
## 2-Acetylpyrazine 123.05529 145.03723
## Guanosine 5′-diphosphate sodium sa 444.03161 466.01355
## Quinoline-4-carboxylic acid 174.05495 196.03690
## Heneicosanoic acid 327.32576 349.30770
## Sudan III 353.13969 375.12163
## Erythrosine B 836.66234 858.64429
## Hypoxanthine 137.04579 159.02773
## 2-Oxoadipic acid 161.04445 183.02639
## N-Acetyl-L-cysteine 164.03759 186.01953
## Carbamazepine 237.10224 259.08418
## Famotidine 338.05221 360.03416
## "trans-2-Butene-1,4-dicarboxylic acid" 145.04953 167.03148
## DL-p-Hydroxyphenyllactic acid 183.06518 205.04713
## "Malachite Green, Oxalate" 365.17790 387.15985
## Brucine sulfate heptahydrate 395.19653 417.17848
## Uric acid 169.03562 191.01756
## Glycocholic acid hydrate 466.31631 488.29826
## DL-4-Hydroxy-3-methoxymandelic acid 199.06010 221.04204
## Phosphorylcholine chloride calcium salt tetrahydrate 185.08115 207.06309
## Imidazole 69.04472 91.02667
## Indole 118.06513 140.04707
## Perindopril erbumine 369.23840 391.22034
## Folinic acid calcium salt hydrate 474.17317 496.15512
## "Tauroursodeoxycholic acid, Na salt" 500.30404 522.28598
## Glycyl-L-leucine 189.12337 211.10531
## Carotene 537.44548 559.42742
## 2-Methylsuccinic acid 133.04953 155.03148
## DL-m-Tyrosine 182.08117 204.06311
## Ursodeoxycholic acid 393.29994 415.28188
## N-Acetyl-L-alanine 132.06552 154.04746
## 3-Hydroxybenzyl alcohol 125.05971 147.04165
## 2-Hydroxy-4-(methylthio)butyric acid calcium salt 151.04234 173.02429
## Myrcene 137.13248 159.11442
## "3,4-Dihydroxybenzeneacetic acid" 169.04953 191.03148
## Deoxycholic acid 393.29994 415.28188
## 2-Aminobenzenesulfonic acid 174.02194 196.00388
## Indole-3-acetamide 175.08659 197.06853
## L-Glutathione reduced 308.09108 330.07303
## (±)-3-Methyl-2-oxovaleric acid sodium sal 131.07027 153.05221
## Lithocholic acid 377.30502 399.28697
## Chenodeoxycholic acid sodium salt 393.29994 415.28188
## D-Allose 181.07066 203.05261
## Solvent Blue 35 351.20670 373.18865
## Tetradecanedioic acid 259.19039 281.17233
## Food Yellow 3 409.01587 430.99781
## L-Homocitrulline 190.11862 212.10056
## 3-Methylxanthine 167.05635 189.03830
## Acid Yellow 36 354.09069 376.07263
## L-Arabitol 153.07575 175.05769
## Sodium phytate hydrate 660.86865 682.85059
## Phosphoserine 186.01620 207.99814
## Deoxy-D-glucose 165.07575 187.05769
## Alanine methyl ester hydrochloride 104.07060 126.05255
## Phenylac-Gly-OH 194.08117 216.06311
## NADPH sodium salt 746.09838 768.08032
## Pyridoxine HCl 170.08117 192.06311
## L-Malic ac 135.02880 157.01074
## Uracil 113.03455 135.01650
## Adenosine 268.10403 290.08597
## L-Carnitine inner salt 162.11247 184.09441
## Acetyl-L-glutamin 189.08698 211.06893
## Aminobutyric acid 104.07060 126.05255
## Ortho-Hydroxyphenylacetic acid 153.05462 175.03656
## Riboflavin 377.14556 399.12750
## Diaminobutane dihydrochloride 89.10732 111.08927
## Sarcosine 90.05495 112.03690
## L-Carnosine 227.11387 249.09581
## Methylmalonic acid 119.03388 141.01583
## L-Pyroglutamic acid 130.04987 152.03181
## Rhodamine B 444.24074 466.22269
## Indigo Carmine 422.99513 444.97708
## Diaminopropionic acid monohydrochloride 105.06585 127.04780
## Dimethylbenzimidazole 147.09167 169.07362
## N-Acetyl-L-aspartic acid 176.05535 198.03729
## Thiamine hydrochloride hydrate 266.11958 288.10153
## Taurine 126.02194 148.00388
## Maleic acid 117.01823 139.00018
## O-Acetyl-L-carnitine HCl 204.12303 226.10498
## N-Acetyl-D-galactosamine 222.09721 244.07916
## Citric acid 193.03428 215.01622
## Dimethylglycine hydrochloride 104.07060 126.05255
## Erioglaucine disodium salt 750.17339 772.15534
## Sebacic acid 203.12779 225.10973
## Stearic acid 285.27881 307.26075
## L-Arginine 175.11895 197.10090
## 2'-Deoxyuridine 229.08190 251.06384
## Maltotriose 505.17631 527.15825
## dimethyl-L-Valine 146.11755 168.09950
## Acetylphenothiazine 242.06341 264.04535
## Methoxybenzoic acid 153.05462 175.03656
## Metyrosine 196.09682 218.07876
## Rhein 285.03936 307.02131
## N6-Methyladenine 150.07742 172.05937
## Hydroxybenzoic acid 139.03897 161.02091
## Sodium D-gluconate 197.06558 219.04752
## L-Threonic acid Calcium Salt 137.04445 159.02639
## Methyl 3-aminopyrazine-2-carboxylate 154.06110 176.04305
## DL-α-Lipoamid 206.06678 228.04873
## Lauric acid 201.18491 223.16685
## Nicotinamide mononucleotide 336.07170 358.05365
The createStandardMixes()
function organizes given compounds in such a way
that each compound is placed in a group where all ions (adducts) have a m/z
difference exceeding a user-defined threshold (default: min_diff = 2
). In
this initial example, we aim to group only a subset of our compound list and
execute the function with default parameters:
group_no_randomization <- createStandardMixes(standard_charged[1:20,])
group_no_randomization
## [M+H]+ [M+Na]+ group
## 2-Acetylpyrazine 123.05529 145.03723 1
## Guanosine 5′-diphosphate sodium sa 444.03161 466.01355 1
## Quinoline-4-carboxylic acid 174.05495 196.03690 1
## Heneicosanoic acid 327.32576 349.30770 1
## Sudan III 353.13969 375.12163 1
## Erythrosine B 836.66234 858.64429 1
## Hypoxanthine 137.04579 159.02773 1
## 2-Oxoadipic acid 161.04445 183.02639 1
## N-Acetyl-L-cysteine 164.03759 186.01953 1
## Carbamazepine 237.10224 259.08418 1
## Famotidine 338.05221 360.03416 2
## "trans-2-Butene-1,4-dicarboxylic acid" 145.04953 167.03148 2
## DL-p-Hydroxyphenyllactic acid 183.06518 205.04713 2
## "Malachite Green, Oxalate" 365.17790 387.15985 2
## Brucine sulfate heptahydrate 395.19653 417.17848 2
## Uric acid 169.03562 191.01756 2
## Glycocholic acid hydrate 466.31631 488.29826 2
## DL-4-Hydroxy-3-methoxymandelic acid 199.06010 221.04204 2
## Phosphorylcholine chloride calcium salt tetrahydrate 185.08115 207.06309 2
## Imidazole 69.04472 91.02667 2
Let’s see the number of compounds per group:
table(group_no_randomization$group)
##
## 1 2
## 10 10
The grouping here worked perfectly, but let’s now use the entire compound list and run with the default parameter again:
group_no_randomization <- createStandardMixes(standard_charged)
table(group_no_randomization$group)
##
## 1 2 3 4 5 6 7 8 9 10 11
## 10 10 10 10 10 10 10 10 10 7 3
This time we can see that the grouping is less ideal.
In this case we can switch the iterativeRandomization = TRUE
.
group_with_ramdomization <- createStandardMixes(standard_charged,
iterativeRandomization = TRUE)
table(group_with_ramdomization$group)
##
## 1 2 3 4 5 6 7 8 9 10
## 10 10 10 10 10 10 10 10 10 10
Changing iterativeRandomization =
from the default FALSE
to TRUE
enables
the randomization of input x
rows until it fits the min_nstd
parameter. If
the list of compounds is very long or the requirement is hard to fit, this
function can take a bit longer if iterativeRandomization =
is set to TRUE.
What if we want groups of a maximum of 20 and a minimum of 15 compounds, and
with a minimum difference of 2 m/z between compounds of the same group? If you
want to know more about the parameters of this function, look at
?createStandardMixes
.
set.seed(123)
group_with_ramdomization <- createStandardMixes(standard_charged,
max_nstd = 15,
min_nstd = 10,
min_diff = 2,
iterativeRandomization = TRUE)
table(group_with_ramdomization$group)
##
## 1 2 3 4 5 6 7
## 15 15 15 15 15 15 10
Great ! these groups look good; we can now export. As the function already
returns a data.frame
, you can directly save is as an Excel file using
write_xlsx()
from the writexl R package or as below in text format that can
also be open in Excel.
write.table(group_with_ramdomization,
file = "standard_mixes.txt", sep = "\t", quote = FALSE)
## R Under development (unstable) (2024-10-21 r87258)
## Platform: x86_64-pc-linux-gnu
## Running under: Ubuntu 24.04.1 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.21-bioc/R/lib/libRblas.so
## LAPACK: /usr/lib/x86_64-linux-gnu/lapack/liblapack.so.3.12.0
##
## 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
##
## time zone: America/New_York
## tzcode source: system (glibc)
##
## attached base packages:
## [1] stats4 stats graphics grDevices utils datasets methods
## [8] base
##
## other attached packages:
## [1] MetaboCoreUtils_1.15.0 microbenchmark_1.5.0
## [3] msdata_0.47.0 QFeatures_1.17.0
## [5] MultiAssayExperiment_1.33.1 SummarizedExperiment_1.37.0
## [7] Biobase_2.67.0 GenomicRanges_1.59.1
## [9] GenomeInfoDb_1.43.1 IRanges_2.41.1
## [11] MatrixGenerics_1.19.0 matrixStats_1.4.1
## [13] Spectra_1.17.1 BiocParallel_1.41.0
## [15] S4Vectors_0.45.2 MetaboAnnotation_1.11.1
## [17] AnnotationHub_3.15.0 BiocFileCache_2.15.0
## [19] dbplyr_2.5.0 BiocGenerics_0.53.3
## [21] generics_0.1.3 BiocStyle_2.35.0
##
## loaded via a namespace (and not attached):
## [1] jsonlite_1.8.9 magrittr_2.0.3 TH.data_1.1-2
## [4] magick_2.8.5 rmarkdown_2.29 fs_1.6.5
## [7] zlibbioc_1.53.0 vctrs_0.6.5 memoise_2.0.1
## [10] RCurl_1.98-1.16 base64enc_0.1-3 tinytex_0.54
## [13] htmltools_0.5.8.1 S4Arrays_1.7.1 curl_6.0.1
## [16] SparseArray_1.7.2 sass_0.4.9 bslib_0.8.0
## [19] htmlwidgets_1.6.4 plyr_1.8.9 sandwich_3.1-1
## [22] zoo_1.8-12 cachem_1.1.0 igraph_2.1.1
## [25] mime_0.12 lifecycle_1.0.4 pkgconfig_2.0.3
## [28] Matrix_1.7-1 R6_2.5.1 fastmap_1.2.0
## [31] GenomeInfoDbData_1.2.13 clue_0.3-66 digest_0.6.37
## [34] rsvg_2.6.1 colorspace_2.1-1 AnnotationDbi_1.69.0
## [37] RSQLite_2.3.8 filelock_1.0.3 fansi_1.0.6
## [40] httr_1.4.7 abind_1.4-8 compiler_4.5.0
## [43] bit64_4.5.2 withr_3.0.2 DBI_1.2.3
## [46] MASS_7.3-61 ChemmineR_3.59.0 rappdirs_0.3.3
## [49] DelayedArray_0.33.2 rjson_0.2.23 mzR_2.41.1
## [52] tools_4.5.0 CompoundDb_1.11.0 glue_1.8.0
## [55] grid_4.5.0 cluster_2.1.6 reshape2_1.4.4
## [58] gtable_0.3.6 tidyr_1.3.1 xml2_1.3.6
## [61] utf8_1.2.4 XVector_0.47.0 BiocVersion_3.21.1
## [64] pillar_1.9.0 stringr_1.5.1 splines_4.5.0
## [67] dplyr_1.1.4 lattice_0.22-6 survival_3.7-0
## [70] bit_4.5.0 tidyselect_1.2.1 Biostrings_2.75.1
## [73] knitr_1.49 gridExtra_2.3 bookdown_0.41
## [76] ProtGenerics_1.39.0 xfun_0.49 DT_0.33
## [79] stringi_1.8.4 UCSC.utils_1.3.0 lazyeval_0.2.2
## [82] yaml_2.3.10 evaluate_1.0.1 codetools_0.2-20
## [85] MsCoreUtils_1.19.0 tibble_3.2.1 BiocManager_1.30.25
## [88] cli_3.6.3 munsell_0.5.1 jquerylib_0.1.4
## [91] Rcpp_1.0.13-1 png_0.1-8 parallel_4.5.0
## [94] ggplot2_3.5.1 blob_1.2.4 AnnotationFilter_1.31.0
## [97] bitops_1.0-9 mvtnorm_1.3-2 scales_1.3.0
## [100] ncdf4_1.23 purrr_1.0.2 crayon_1.5.3
## [103] rlang_1.1.4 KEGGREST_1.47.0 multcomp_1.4-26