# Contents

This document provides an introduction to the capabilities of slalom. The package can be used to identify hidden and biological drivers of variation in single-cell gene expression data using factorial single-cell latent variable models.

# 1 Quickstart

Slalom requires: 1. expression data in a SingleCellExperiment object (defined in SingleCellExperiment package), typically with log transformed gene expression values; 2. Gene set annotations in a GeneSetCollection class (defined in the GSEABase package). A GeneSetCollection can be read into R from a *.gmt file as shown below.

Here, we show the minimal steps required to run a slalom analysis on a subset of a mouse embryonic stem cell (mESC) cell cycle-staged dataset.

First, we load the mesc dataset included with the package. The mesc object loaded is a SingleCellExperiment object ready for input to slalom

library(slalom)
data("mesc")

If we only had a matrix of expression values (assumed to be on the log2-counts scale), then we can easily construct a SingleCellExperiment object as follows:

exprs_matrix <- SingleCellExperiment::logcounts(mesc)
mesc <- SingleCellExperiment::SingleCellExperiment(
assays = list(logcounts = exprs_matrix)
)

We also need to supply slalom with genesets in a GeneSetCollection object. If we have genesets stored in a *.gmt file (e.g. obtained from MSigDB or REACTOME) then it is easy to read these directory into an appropriate object, as shown below for a subset of REACTOME genesets.

gmtfile <- system.file("extdata", "reactome_subset.gmt", package = "slalom")
genesets <- GSEABase::getGmt(gmtfile)

Next we need to create an Rcpp_SlalomModel object containing the input data and genesets (and subsequent results) for the model. We create the object with the newSlalomModel function.

We need to define the number of hidden factors to include in the model (n_hidden argument; 2–5 hidden factors recommended) and the minimum number of genes required to be present in order to retain a geneset (min_genes argument; default is 10).

model <- newSlalomModel(mesc, genesets, n_hidden = 5, min_genes = 10)
## 14 annotated factors retained;  16 annotated factors dropped.
## 196  genes retained for analysis.

Next we need to initialise the model with the init function.

model <- initSlalom(model)

With the model prepared, we then train the model with the train function.

model <- trainSlalom(model, nIterations = 10)
## pre-training model for faster convergence
## iteration 0
## Model not converged after 50 iterations.
## iteration 0
## Model not converged after 50 iterations.
## iteration 0
## Switched off factor 17
## Switched off factor 18
## Model not converged after 10 iterations.

Typically, over 1,000 iterations will be required for the model to converge.

Finally, we can analyse and interpret the output of the model and the sources of variation that it identifies. This process will typically include plots of factor relevance, gene set augmentation and a scatter plots of the most relevant factors.

# 2 Input data and genesets

As introduced above, slalom requires: 1. expression data in a SingleCellExperiment object (defined in SingleCellExperiment package), typically with log transformed gene expression values; 2. Gene set annotations in a GeneSetCollection class (defined in the GSEABase package).

Slalom works best with log-scale expression data that has been QC’d, normalized and subsetted down to highly-variable genes. Happily, there are Bioconductor packages available for QC and normalization that also use the SingleCellExperiment class and can provide appropriate input for slalom. The combination of scater and scran is very effective for QC, normalization and selection of highly-variable genes. A Bioconductor workflow shows how those packages can be combined to good effect to prepare data suitable for analysis with slalom.

Here, to demonstrate slalom we will use simulated data. First, we make a new SingleCellExperiment object. The code below reads in an expression matrix from file, creates a SingleCellExperiment object with these expression values in the logcounts slot.

rdsfile <- system.file("extdata", "sim_N_20_v3.rds", package = "slalom")
sce <- SingleCellExperiment::SingleCellExperiment(
assays = list(logcounts = sim[["init"]][["Y"]])
)

The second crucial input for slalom is the set of genesets or pathways that we provide to the model to see which are active. The model is capable of handling hundreds of genesets (pathways) simultaneously.

Geneset annotations must be provided as a GeneSetCollection object as defined in the GSEABase package.

Genesets are typically distributed as *.gmt files and are available from such sources as MSigDB or REACTOME. The gmt format is very simple, so it is straight-forward to augment established genesets with custom sets tailored to the data at hand, or indeed to construct custom geneset collections completely from scratch.

If we have genesets stored in a *.gmt file (e.g. from MSigDB, REACTOME or elsewhere) then it is easy to read these directory into an appropriate object, as shown below for a subset of REACTOME genesets.

gmtfile <- system.file("extdata", "reactome_subset.gmt", package = "slalom")
genesets <- GSEABase::getGmt(gmtfile)

Geneset names can be very long, so below we trim the REACTOME geneset names to remove the “REACTOME_” string and truncate the names to 30 characters. (This is much more convenient downstream when we want to print relevant terms and create plots that show geneset names.)

We also tweak the row (gene) and column (cell) names so that our example data works nicely.

genesets <- GSEABase::GeneSetCollection(
lapply(genesets, function(x) {
GSEABase::setName(x) <- gsub("REACTOME_", "", GSEABase::setName(x))
GSEABase::setName(x) <- strtrim(GSEABase::setName(x), 30)
x
})
)
rownames(sce) <- unique(unlist(GSEABase::geneIds(genesets[1:20])))[1:500]
colnames(sce) <- 1:ncol(sce)

With our input data prepared, we can proceed to creating a new model.

# 3 Creating a new model

The newSlalomModel function takes the SingleCellExperiment and GeneSetCollection arguments as input and returns an object of class Rcpp_SlalomModel: our new object for fitting the slalom model. All of the computationally intensive model fitting in the package is done in C++, so the Rcpp_SlalomModel object provides an R interface to an underlying SlalomModel class in C++.

Here we create a small model object, specifying that we want to include one hidden factor (n_hidden) and will retain genesets as long as they have at least one gene present (min_genes) in the SingleCellExperiment object (default value is 10, which would be a better choice for analyses of experimental data).

m <- newSlalomModel(sce, genesets[1:23], n_hidden = 1, min_genes = 1)
## 20 annotated factors retained;  3 annotated factors dropped.
## 500  genes retained for analysis.

Twenty annotated factors are retained here, and three annotated factors are dropped. 500 genes (all present in the sce object) are retained for analysis. For more options in creating the slalom model object consult the documentation (?newSlalomModel).

See documentation (?Rcpp_SlalomModel) for more details about what the class contains.

# 4 Initializing the model

Before training (fitting) the model, we first need to establish a sensible initialisation. Results of variational Bayes methods, in general, can depend on starting conditions and we have found developed initialisation approaches that help the slalom model converge to good results.

The initSlalom function initialises the model appropriately. Generally, all that is required is the call initSlalom(m), but here the genesets we are using do not correspond to anything meaningful (this is just dummy simulated data), so we explicitly provide the “Pi” matrix containing the prior probability for each gene to be active (“on”) for each factor. We also tell the initialisation function that we are fitting one hidden factor and set a randomisation seed to make analyses reproducible.

m <- initSlalom(m, pi_prior = sim[["init"]][["Pi"]], n_hidden = 1, seed = 222)

See documentation (?initSlalom) for more details.

# 5 Training the model

With the model initialised, we can proceed to training (fitting) it. Training typically requires one to several thousand iterations, so despite being linear in the nubmer of factors can be computationally expensive for large datasets ( many cells or many factors, or both).

mm <- trainSlalom(m, minIterations = 400, nIterations = 5000, shuffle = TRUE,
pretrain = TRUE, seed = 222)
## pre-training model for faster convergence
## iteration 0
## Model not converged after 50 iterations.
## iteration 0
## Model not converged after 50 iterations.
## iteration 0
## Switched off factor 20
## Switched off factor 17
## Switched off factor 10
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## Switched off factor 16
## iteration 100
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## Model converged after 4550 iterations.

We apply the shuffle (shuffling the update order of factors at each iteration of the model) and pretrain (burn 100 iterations of the model determine the best intial update order of factors) options as these generally aid the convergence of the model. See documentation (?trainSlalom) for more details and further options.

Here the model converges in under 2000 iterations. This takes seconds for 21 factors, 20 cells and 500 genes. The model is, broadly speaking, very scalable, but could still require hours for many thousands of cells and/or hundreds of factors.

# 6 Interpretation of results

With the model trained we can move on to the interpretation of results.

## 6.1 Top terms

The topTerms function provides a convenient means to identify the most “relevant” (i.e. important) factors identified by the model.

topTerms(m)
##                              term    relevance      type n_prior n_gain
## 1  APOPTOTIC_CLEAVAGE_OF_CELLULAR 1.1862945226 annotated      46      0
## 2  NEF_MEDIATED_DOWNREGULATION_OF 0.9533517719 annotated      27      0
## 3         CELL_CELL_COMMUNICATION 0.8834821681 annotated      76      0
## 4  NEF_MEDIATES_DOWN_MODULATION_O 0.8194190105 annotated      49      0
## 5                      CELL_CYCLE 0.5370374523 annotated     466      0
## 6  NEUROTRANSMITTER_RECEPTOR_BIND 0.0008010153 annotated      33      0
## 7              CELL_CYCLE_MITOTIC 0.0007054114 annotated      70      0
## 8  CELL_SURFACE_INTERACTIONS_AT_T 0.0006495766 annotated     101      0
## 9  ACTIVATION_OF_NF_KAPPAB_IN_B_C 0.0005060579 annotated     104      0
## 10 INTEGRIN_CELL_SURFACE_INTERACT 0.0004000095 annotated     179      0
## 11 ANTIGEN_ACTIVATES_B_CELL_RECEP 0.0003983484 annotated     107      0
## 12 DOWNSTREAM_SIGNALING_EVENTS_OF 0.0003473931 annotated     205      0
## 13 NOTCH1_INTRACELLULAR_DOMAIN_RE 0.0003460340 annotated     325      0
##    n_loss
## 1       0
## 2       0
## 3       0
## 4       0
## 5       0
## 6       0
## 7       0
## 8       0
## 9       0
## 10      0
## 11      0
## 12      0
## 13      0

We can see the name of the term (factor/pathway), its relevance and type (annotated or unannotated (i.e. hidden)), the number genes initially in the gene set (n_prior), the number of genes the model thinks should be added as active genes to the term (n_gain) and the number that should be dropped from the set (n_loss).

## 6.2 Plotting results

The plotRelevance, plotTerms and plotLoadings functions enable us to visualise the slalom results.

The plotRelevance function displays the most relevant terms (factors/pathways) ranked by relevance, showing gene set size and the number of genes gained/lost as active in the pathway as learnt by the model.

plotRelevance(m)

The plotTerms function shows the relevance of all terms in the model, enabling the identification of the most important pathways in the context of all that were included in the model.

plotTerms(m)

Once we have identified terms (factors/pathways) of interest we can look specifically at the loadings (weights) of genes for that term to see which genes are particularly active or influential in that pathway.

plotLoadings(m, "CELL_CYCLE")

See the appropriate documentation for more options for these plotting functions.

# 7 Using results for further analyses

Having obtained slalom model results we would like to use them in downstream analyses. We can add the results to a SingleCellExperiment object, which allows to plug into other tools, particularly the scater package which provides useful further plotting methods and ways to regress out unwanted hidden factors or biologically uninteresting pathways (like cell cycle, in some circumstances).

## 7.1 Adding results to a SingleCellExperiment object

The addResultsToSingleCellExperiment function allows us to conveniently add factor states (cell-level states) to the reducedDim slot of the SingleCellExperiment object and the gene loadings to the rowData of the object.

It typically makes most sense to add the slalom results to the SingleCellExperiment object we started with, which is what we do here.

sce <- addResultsToSingleCellExperiment(sce, m)

## 7.2 More plots and egressing out hidden/unwanted factors

Now that our results are available in the SingleCelExperiment object we can use the plotReducedDim function in the scater package to plot factors against each other in the context of gene expression values and other cell covariates. We could also use the normaliseExprs function in scater to regress out unwanted factors to generate expression values removing the effect of hidden factors (which may represent batch or other technical variation) or factors like cell cycle.

# 8 Session Info

sessionInfo()
## R version 3.4.2 (2017-09-28)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 16.04.3 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.6-bioc/R/lib/libRblas.so
## LAPACK: /home/biocbuild/bbs-3.6-bioc/R/lib/libRlapack.so
##
## locale:
##  [1] LC_CTYPE=en_US.UTF-8       LC_NUMERIC=C
##  [3] LC_TIME=en_US.UTF-8        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
## [11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
##
## attached base packages:
## [1] stats     graphics  grDevices utils     datasets  methods   base
##
## other attached packages:
## [1] slalom_1.0.0    knitr_1.17      BiocStyle_2.6.0
##
## loaded via a namespace (and not attached):
##  [1] SummarizedExperiment_1.8.0 lattice_0.20-35
##  [3] colorspace_1.3-2           htmltools_0.3.6
##  [5] stats4_3.4.2               yaml_2.1.14
##  [7] blob_1.1.0                 XML_3.98-1.9
##  [9] rlang_0.1.2                DBI_0.7
## [11] SingleCellExperiment_1.0.0 BiocGenerics_0.24.0
## [13] bit64_0.9-7                matrixStats_0.52.2
## [15] GenomeInfoDbData_0.99.1    plyr_1.8.4
## [17] stringr_1.2.0              zlibbioc_1.24.0
## [19] munsell_0.4.3              gtable_0.2.0
## [21] rsvd_0.6                   codetools_0.2-15
## [23] evaluate_0.10.1            memoise_1.1.0
## [25] labeling_0.3               Biobase_2.38.0
## [29] GenomeInfoDb_1.14.0        parallel_3.4.2
## [31] AnnotationDbi_1.40.0       GSEABase_1.40.0
## [33] Rcpp_0.12.13               xtable_1.8-2
## [35] scales_0.5.0               backports_1.1.1
## [37] DelayedArray_0.4.0         S4Vectors_0.16.0
## [39] graph_1.56.0               annotate_1.56.0
## [41] XVector_0.18.0             bit_1.1-12
## [43] ggplot2_2.2.1              digest_0.6.12
## [45] stringi_1.1.5              bookdown_0.5
## [47] GenomicRanges_1.30.0       grid_3.4.2
## [49] rprojroot_1.2              BH_1.65.0-1
## [51] tools_3.4.2                bitops_1.0-6
## [53] magrittr_1.5               RCurl_1.95-4.8
## [55] lazyeval_0.2.1             tibble_1.3.4
## [57] RSQLite_2.0                Matrix_1.2-11
## [59] rmarkdown_1.6              compiler_3.4.2