1 Introduction

The MetCirc package comprises functionalities to display, (interactively) explore similarities and annotate features of MS/MS metabolomics data. It is especially designed to improve the interactive exploration of metabolomics data obtained from cross-species/cross-tissues comparative experiments. MetCirc relies on the Spectra infrastructure to handle MS/MS spectra. Specifically, MetCirc uses the Spectraclass from which similarities between features are calculated and which stores information on spectra in the columns of the slotmetadata`.

Notably, MetCirc provides functions to calculate the similarity between individual MS/MS spectra based on a normalised dot product (NDP, see Li, Baldwin, and Gaquerel (2015) for further details) calculation taking into account shared fragments or main neutral losses.

Visualisation of molecular networks was pioneered by the Dorrestein lab (Watrous et al. 2012) to efficiently organize MS/MS spectra in such a way that clusters of MS/MS spectra sharing multiple common fragments are rapidly inferred.

In contrary to the analysis there, the MetCirc framework offers two ways for the computation of mass spectrum similarity: one way deploys common (shared) fragments and the other shared neutral losses that are deduced from the spectra. Especially the latter approach allows to extract clusters of spectra corresponding to compound families facilitating the rapid dereplication of hitherto unknown metabolites. Small molecules, as produced by plants, return during fragmentation few fragments.
Sometimes only a few fragments among them are shared and diagnostic across the compound family. Compared to the MS/MS similarity scoring based on shared fragments, the second similarity measure incorporates, in a non-supervised manner, neutral losses, which definitely helps obtaining biochemically-meaningful MS/MS groupings. Furthermore, any other function to calculate similarities can be provided or a similarity matrix providing similarity (in the range from 0 to 1) for features that are present in the Spectra object.

The interpretation drawn from network reconstruction highly depends from topological parameters applied during the network construction steps. MetCirc circumvents this confinement. Furthermore, it uses instead smaller MS/MS datasets obtained from experiments involving a priori defined biological groups (organisms, tissues, etc.) to visualize within and between MS/MS feature similarities on a circular layout - inspired by the Circos framework (Krzywinski et al. 2009). The visualisation is adjustable (MS/MS ordering and similarity thresholds) via the shiny interface and does not uniquely emphasize on large clusters of MS/MS features (a frequent caveat of network visualisation). Furthermore, the implemented functionality for annotation may improve dereplication of known and unknown molecules.

This vignette uses as a case study indiscriminant MS/MS (idMS/MS) data from Li, Baldwin, and Gaquerel (2015), unpublished idMS/MS data collected from different organs of tobacco flowers and data from the Global Natural Product Social Molecular Networking (GNPS) library to navigate through the analysis pipeline. The pipeline includes the creation of Spectra objects, the calculation of a similarity measure (NDP), assignment to a similarity matrix and visualisation of similarity based on interactive and non-interactive graphical tools using the circlize framework (Gu et al. 2014).

MetCirc is currently under active development. If you discover any bugs, typos or develop ideas of improving MetCirc feel free to raise an issue via GitHub or send a mail to the developers.

2 Prepare the environment

To install MetCirc enter the following to the R console

if (!requireNamespace("BiocManager", quietly=TRUE))
    install.packages("BiocManager")
BiocManager::install("MetCirc")

Before starting, load the MetCirc package. This will also load the required packages Spectra, circlize, amap, scales and shiny:

library("MetCirc")
library("MsCoreUtils")
## 
## Attaching package: 'MsCoreUtils'
## The following objects are masked from 'package:Spectra':
## 
##     bin, smooth
## The following objects are masked from 'package:ProtGenerics':
## 
##     bin, smooth
## The following object is masked from 'package:stats':
## 
##     smooth

The central infrastructure class of the MetCirc package is the Spectra object. The Spectra objects stores information on precursor m/z, retention time, m/z and intensity values of fragments and possible additional information, e.g. to which class the MS/MS feature belong to, the identity of the MS/MS feature, information on the adduct of the precursor, additional information. Furthermore, the Spectra object can host information under which condition (in which tissue, etc.) the MS/MS feature was detected.

We provide here three examplary workflows to create Spectra from data frames that are loaded into R: (1) by loading a data frame with a minimum requirement of a column “id” (comprising unique identifiers for MS/MS features) and of the columns “mz” and “intensity” comprising the fragment ions and their intensities, respectively, or (2) by loading a data frame resembling a .MSP file object.

2.1 Load example data sets from Li, Baldwin, and Gaquerel (2015), tissue idMS/MS data and GNPS data

sd02_deconvoluted comprises 360 idMS/MS deconvoluted spectra with fragment ions (m/z, chromatographic retention time, relative intensity in %) and a column with unique identifiers for MS/MS features (here, the corresponding principal component group with the precursor ion). The data set is derived from the study of Li, Baldwin, and Gaquerel (2015).

## load data from Li et al., 2015
data("sd02_deconvoluted", package = "MetCirc")

The second data set comes from the data-independent MS/MS collection of different floral organs from tobacco plants. Using our pipeline, this data set will be used to visualize shared metabolites between tissues as well as structural relationships among within- and between-organ MS/MS spectra. MS/MS data are merged across floral organs in one unique data file idMSMStissueproject.Rdata as tissue. Information on the organ-localisation of each MS/MS spectrum is stored in
compartmentTissue.

## load idMSMStissueproject
data("idMSMStissueproject", package = "MetCirc")

The third data set comes from the GNPS data base (downloaded at February 11, 2017 from: \ http://prime.psc.riken.jp/Metabolomics_Software/MS-DIAL/MSMS-GNPS-Curated-Neg.msp). It contains 22 MS/MS features (a truncated file of the original one) and is formatted in the .MSP file format, a typical format for MS/MS libraries. The MS/MS spectra are (normally) separated by blank lines and give information on the metabolite (its name, precursor m/z value, retention time, class, adduct ion) and contain additional information.

## load data from GNPS
data("convertMsp2Spectra", package = "MetCirc")

3 Prepare data for mass spectral similarity calculations

3.1 Preparing the sd02_deconvoluted data set for analysis

Here, we convert the examplatory data from Li, Baldwin, and Gaquerel (2015) into a Spectra object that is later used as the input for mass spectral similarity calculations. Data in the form of the data frame sd02_deconvoluted require columns that store the m/z values of fragments, the intensity values for the respective fragments and a column containing an “id”. The latter column contains information about the precursor ion and should be a unique descriptor for the MS/MS features. For instance, this column may be the derived from the output of the xcms/CAMERA processing creating unique identifiers for each metabolite decoded in the column “pcgroup”. A pcgroup is defined as a peak correlation group obtained by this workflow. It corresponds to a MS or MS/MS spectrum deconvoluted by CAMERA and contains information about the precursor identity and its isotope cluster. The column “id” may additionally contain information about the precursor retention time.

Create Spectra object from the data of Li, Baldwin, and Gaquerel (2015):

## get all MS/MS spectra
id_uniq <- unique(sd02_deconvoluted[, "id"])

## obtain precursor m/z from id_uniq
prec_mz <- lapply(strsplit(as.character(id_uniq), split = " _ "), "[", 2) |>
    unlist() |>
    as.numeric()

## obtain m/z from fragments per precursor m/z
mz_l <- lapply(id_uniq, 
    function(id_i) sd02_deconvoluted[sd02_deconvoluted[, "id"] == id_i, "mz"])

## obtain corresponding intensity values 
int_l <- lapply(id_uniq, 
    function(id_i) sd02_deconvoluted[sd02_deconvoluted[, "id"] == id_i, "intensity"]) 

## obtain retention time by averaging all retention time values
rt <- lapply(id_uniq, function(x) sd02_deconvoluted[sd02_deconvoluted[, "id"] == x, "rt"]) |>
    lapply(function(i) mean(i)) |>
    unlist()

## create list of Spectra objects, concatenate, and add metadata
sps_l <- lapply(seq_len(length(mz_l)), function(i) {
    spd <- S4Vectors::DataFrame(
        name = as.character(i),
        rtime = rt[i], 
        msLevel = 2L,
        precursorMz = prec_mz[i])
    spd$mz <- list(mz_l[[i]])
    spd$intensity <- list(int_l[[i]])
    Spectra::Spectra(spd)})
sps_li <- Reduce(c, sps_l)
sps_li@metadata <- data.frame(show = rep(TRUE, length(sps_l)))

Furthermore, further columns in the data.frame passed to metadata can be specified to host additional information, e.g. metabolite name (column “names”) and classes (column “classes”), adduct ion names (column “adduct”), further information (column “information”).

3.2 Preparing the floral organ data set for analysis

We would like to restrict the proof-of-function analysis to four tissues (sepal, SPL; limb, LIM; anther, ANT; style, STY). We will truncate tissue in order that it contains only these instances belonging to these types of tissue. In a next step, we will create a Spectra-object, spl with information concerning if the MS/MS features are found in the tissues SPL, LIM, ANT and STY.

## get all MS/MS spectra
tissue <- tissue[tissue[, "id"] %in% compartmentTissue[, "mz_rt_pcgroup"], ]
id_uniq <- unique(tissue[, "id"])

## obtain precursor m/z from id_uniq
prec_mz <- lapply(strsplit(as.character(id_uniq), split = "_"), "[", 1) |>
    unlist() |>
    as.numeric()

## obtain m/z from fragments per precursor m/z
mz_l <- lapply(id_uniq, function(id_i) tissue[tissue[, "id"] == id_i, "mz"]) 

## obtain corresponding intensity values
int_l <- lapply(id_uniq, function(id_i) tissue[tissue[, "id"] == id_i, "intensity"])

## order mz and intensity values
int_l <- lapply(seq_along(int_l), function(i) int_l[[i]][order(mz_l[[i]])])
mz_l <- lapply(seq_along(mz_l), function(i) sort(mz_l[[i]]))

## obtain retention time by averaging all retention time values
rt <- lapply(id_uniq, function(x) tissue[tissue[, "id"] == x, "rt"]) |>
    lapply(FUN = mean) |>
    unlist()

## create list of Spectra objects and concatenate
sps_l <- lapply(seq_len(length(mz_l)), function(i) {
    spd <- S4Vectors::DataFrame(
        name = as.character(i),
        rtime = rt[i], 
        msLevel = 2L,
        precursorMz = prec_mz[i])
    spd$mz <- list(mz_l[[i]])
    spd$intensity <- list(int_l[[i]])
    Spectra::Spectra(spd)})
sps_tissue <- Reduce(c, sps_l)

## add metadata
## use SPL, LIM, ANT, STY for further analysis
sps_tissue@metadata <- data.frame(
    compartmentTissue[, c("SPL", "LIM", "ANT", "STY")])

3.3 Preparing the GNPS data set for analysis

Alternatively as mentioned above, an Spectra-object can also created from .MSP objects, that are typical data formats for storing MS/MS libraries. Required properties of such a data frame are the name of the metabolite (row entry “NAME:”), the m/z value of the precursor ion (“PRECURSORMZ” or “EXACTMASS:”), retention time (“RETENTIONTIME:”), information on the number of peaks (“Num Peaks:”) and information on fragments and peak areas (for further information see convertMsp2Spectra and retrieve data("convertMsp2Spectra", package = "MetCirc") for a typical msp data frame).

Create Spectra-object from the GNPS .MSP file:

sps_msp <- convertMsp2Spectra(msp2spectra)

4 Binning and calculation of similarity matrix

4.1 Workflow for tissue data set using fragment ions

4.1.1 Calculation of the similarity matrix

The similarity matrix can be obtained by by the Spectra package function compareSpectra which takes a Spectra object and a function for the similarity calculation as input.

The MetCirc package uses functions from the Spectra package to calculate pair-wise similarities between MS/MS features. The user can select the function (via FUN) how to calculate the similarity. The function ndotproduct from the MsCoreUtils package calculates the similarity coefficient between two MS/MS features using the normalised dot product (NDP). For a considered MS/MS pair, peak intensities of shared m/z values for precursor/fragment ions are employed as weights \(W_{S1, i}\) and \(W_{S1, i}\) within the following formula:

\[\begin{equation*} NDP = \frac{\sum(W_{S1, i} \cdot W_{S2, i}) ^ 2}{ \sum(W_{S1, i} ^ 2) * \sum(W_{S2, i} ^ 2) }, \end{equation*}\]

with S1 and S2 the spectra 1 and 2, respectively, of the i\(th\) of j common peaks differing by the tolerance parameter specified in compareSpectra’s argument binSize.

Weights are calculated according to \(W = [ peak~intensity] ^{m} \cdot [m/z]^n\), with m = 0.5 and n = 2 as default values as suggested by MassBank. For further information see Li, Baldwin, and Gaquerel (2015).

Similarly, the function neutralloss takes into account neutral losses between precursor m/z values and all fragments.

Alternatively, the user can specify a custom-defined function to calculate similarities between MS/MS features or use an implemented function in Spectra. The function compareSpectra returns a symmetrical squared similarity matrix with pair-wsie similarity coefficients between MS/MS features.

## similarity Matrix 
similarityMat <- Spectra::compareSpectra(sps_tissue[1:100,], 
    FUN = MsCoreUtils::ndotproduct, ppm = 10, m = 0.5, n = 2)
colnames(similarityMat) <- rownames(similarityMat) <- sps_tissue$name[1:100]

compareSpectra returns a square matrix; in a next step, we add the names of the Spectra MS/MS features as column and row names. The entries of the returned matrix have to be similarites cores ranging between 0 and 1 that are the pair-wise similarities between the MS/MS features.

4.1.2 Clustering/visualisation

At this stage, we would like to visualize the pair-wise similarities of MS/MS features after clustering them. Many functions are available to cluster features such as hclust from stats, Mclust from mclust or hcluster from amap. We would like to use the latter to cluster similar features. To cluster features and visualize the result (see figure ) we enter:

## load package amap
hClustMSP <- hcluster(similarityMat, method="spearman")

## visualize clusters
plot(hClustMSP, labels = FALSE, xlab="", sub="")

To promote readibility we will not show labels. These can be printed to the ~console by colnames(similarityMat)[hClustMSP\$order].

5 Visualisation using the shiny/circlize framework

MetCirc’s main functionality is to visualize metabolomics data, exploring it interactively and annotate unknown features based on similarity to other (known) features. One of the key features of the implemented interactive framework is, that groups can be compared. A group specifies the affiliation of the sample: it can be any biological identifier relevant to the comparitive experiment conducted, e.g. it can be a specific tissue, different times, different species, etc. The visualisation tools implemented in MetCirc allow then to display similarity between precursor ions between and/or within groups.

shinyCircos uses the functioncreateLinkDf which selects these precursor ions that have a similarity score (e.g. a normalised dot product) within the range defined by lower and higher to a precursor ion. Internally, inshinyCircos,createLinkDf will be called to produce a data.frame with link information based on the given thresholds.

linkDf <- createLinkDf(similarityMatrix = similarityMat, sps = sps_tissue,
    condition = c("SPL", "LIM", "ANT", "STY"), lower = 0.5, upper = 1)

As we have calculated similarity coefficients between precursors, we would like to visualize these connections interactively and explore the data. The MetCirc package implementsshinyCircos that allows for such kind of exploration. It is based on the shiny and on the circlize (Gu et al. 2014) framework. Inside ofshinyCircos information of precursor ions are displayed by (single-) clicking over precursors. Precursors can also be permanently selected by double-clicking on them. The similarity coefficients can be thresholded by changing the slider input. Also, on the sidebar panel, the type of link to be displayed can be selected: should only links between groups be displayed, should only links within groups be displayed or should all links be displayed? Ordering inside of groups can be changed by selecting the respective option in the sidebar panel. Momentarily, there are options to reorder features based on clustering, the m/z or the retention time of the precursor ion. In the “Appearance” tab, the size of the plot can be changed, as well as the precision of the displayed values for the m/z and retention time values. Please note, that the precision will only be changed in the text output (not in the graphical output). Also, the user can decide if the legend is displayed or not.

On exiting the shiny application via the exit button in the sidebar panel, selected precursors will be returned which are allocated here to selectedFeatures. selectedFeatures is a vector of the precursor names.

By way of example, we would like to analyse the tissue data set focusing on the tissues “SPL”, “LIM”, “ANT” and “STY”.

To start the shiny app, run

selectedFeatures <- shinyCircos(similarityMat, sps = sps_tissue, 
    condition = c("LIM", "ANT", "STY"))

in the console. This will load information stored in the Spectra object sps_tissue to the shinyCircos interface. Information (metabolite names and class, adduct ion name and further information) will be printed to the interface when (single-)clicking on MS/MS features. Since this Spectra object did not contain any information about metabolite names, class, adduct ion name and further information, initally all fields for these instances are set to “Unkwown”. Note, that on the sidebar on the right side text fields will appear, that allow for changing the annotation of the selected feature. Click “update annotation” to save the changes to the Spectra-object. On exiting shinyCircos via the exit button, selected precursors and the (updated) Spectra-object will be returned to the console. In the example above, enter selectedFeatures$sps to retrieve the Spectra object with updated annotation.

MetCirc allows also to create such figures outside of an interactive context, which might be helpful to create figures and export them e.g. in .pdf or .jpeg format.shinyCircos does currently not support to export figures as they can be easily rebuilt outside of shinyCircos; building figures outside of the interactive context also promotes reproducibility of such figures.

To rebuild the figure in a non-interactive environment, run

## order similarity matrix according to retention time
condition <- c("SPL", "LIM", "ANT", "STY")
simM <- orderSimilarityMatrix(similarityMatrix = similarityMat, 
    sps = sps_tissue, type = "retentionTime", group = FALSE)
groupname <- rownames(simM)
inds <- MetCirc:::spectraCondition(sps_tissue, 
    condition = condition)
inds_match <- lapply(inds, function(x) {inds_match <- match(groupname, x)
    inds_match <- inds_match[!is.na(inds_match)]; x[inds_match]})
inds_cond <- lapply(seq_along(inds_match), 
    function(x) {
        if (length(inds_match[[x]]) > 0) {
            paste(condition[x], inds_match[[x]], sep = "_")
        } else character()
})
inds_cond <- unique(unlist(inds_cond))

## create link matrix
linkDf <- createLinkDf(similarityMatrix = simM, sps = sps_tissue, 
    condition = c("SPL", "LIM", "ANT", "STY"), lower = 0.9, upper = 1)
## cut link matrix (here: only display links between groups)
linkDf_cut <- cutLinkDf(linkDf = linkDf, type = "inter")

## set circlize paramters
circos.par(gap.degree = 0, cell.padding = c(0, 0, 0, 0), 
    track.margin = c(0, 0))

## here set indSelected arbitrarily
indSelected <- 14
selectedFeatures <- inds_cond[indSelected]

## actual plotting
plotCircos(inds_cond, linkDf_cut, initialize = TRUE, featureNames = TRUE, 
    cexFeatureNames = 0.2, groupSector = TRUE, groupName = FALSE, 
    links = FALSE, highlight = TRUE)

highlight(groupname = inds_cond, ind = indSelected, linkDf = linkDf_cut)
## plot without highlighting
plotCircos(inds_cond, linkDf_cut, initialize = TRUE, featureNames = TRUE, 
    cexFeatureNames = 0.2, groupSector = TRUE, groupName = FALSE, links = TRUE, 
    highlight = FALSE)

Appendix

Session information

All software and respective versions to build this vignette are listed here:

## R version 4.3.1 (2023-06-16)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 22.04.3 LTS
## 
## Matrix products: default
## BLAS:   /home/biocbuild/bbs-3.18-bioc/R/lib/libRblas.so 
## LAPACK: /usr/lib/x86_64-linux-gnu/lapack/liblapack.so.3.10.0
## 
## locale:
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##  [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] MsCoreUtils_1.14.0  MetCirc_1.32.0      Spectra_1.12.0     
##  [4] ProtGenerics_1.34.0 BiocParallel_1.36.0 S4Vectors_0.40.0   
##  [7] BiocGenerics_0.48.0 shiny_1.7.5.1       scales_1.2.1       
## [10] circlize_0.4.15     amap_0.8-19         knitr_1.44         
## [13] BiocStyle_2.30.0   
## 
## loaded via a namespace (and not attached):
##  [1] generics_0.1.3         utf8_1.2.4             sass_0.4.7            
##  [4] shape_1.4.6            digest_0.6.33          magrittr_2.0.3        
##  [7] evaluate_0.22          grid_4.3.1             bookdown_0.36         
## [10] fastmap_1.1.1          jsonlite_1.8.7         GlobalOptions_0.1.2   
## [13] promises_1.2.1         BiocManager_1.30.22    fansi_1.0.5           
## [16] codetools_0.2-19       jquerylib_0.1.4        cli_3.6.1             
## [19] rlang_1.1.1            ellipsis_0.3.2         munsell_0.5.0         
## [22] cachem_1.0.8           yaml_2.3.7             tools_4.3.1           
## [25] parallel_4.3.1         dplyr_1.1.3            ggplot2_3.4.4         
## [28] colorspace_2.1-0       httpuv_1.6.12          vctrs_0.6.4           
## [31] R6_2.5.1               mime_0.12              magick_2.8.1          
## [34] lifecycle_1.0.3        fs_1.6.3               IRanges_2.36.0        
## [37] clue_0.3-65            MASS_7.3-60            cluster_2.1.4         
## [40] pkgconfig_2.0.3        pillar_1.9.0           gtable_0.3.4          
## [43] bslib_0.5.1            later_1.3.1            glue_1.6.2            
## [46] Rcpp_1.0.11            tidyselect_1.2.0       tibble_3.2.1          
## [49] xfun_0.40              farver_2.1.1           xtable_1.8-4          
## [52] htmltools_0.5.6.1      rmarkdown_2.25         compiler_4.3.1        
## [55] MetaboCoreUtils_1.10.0

Neutral losses

Bibliography

Gu, Z., L. Gu, R. Eils, M. Schlesner, and B. Brors. 2014. “Circlize Implements and Enhances Circular Visualization in R.” Bioinformatics 30: 2811–2. https://doi.org/10.1093/bioinformatics/btu393.

Krzywinski, M. I., J. Schein, I. Birol, J. Connors, R. Gascoyne, D. Horsman, S. J. Jones, and M. A. Marra. 2009. “Circos: An Information Aesthetic for Comparative Genomics.” Genome Research 19: 1639–45. https://doi.org/10.1101/gr.092759.109.

Li, D., I. T. Baldwin, and E. Gaquerel. 2015. “Navigating Natural Variation in Herbivory-Induced Secondary Metabolism in Coyote Tobacco Populations Using Ms/Ms Structural Analysis.” PNAS 112: E4147–E4155. https://doi.org/10.1073/pnas.1503106112.

Watrous, J., P. Roach, T. Alexandrov, B. S. Heath, J. Y. Yanga, R. D. Kersten, M. van der Voort, et al. 2012. “Mass Spectral Molecular Networking of Living Microbial Colonies.” PNAS 109: E1743–E1752. https://doi.org/10.1073/pnas.1203689109.