Splatter logo

Splatter logo

Welcome to Splatter! Splatter is an R package for the simple simulation of single-cell RNA sequencing data. This vignette gives an overview and introduction to Splatter’s functionality.

1 Installation

Splatter can be installed from Bioconductor:

BiocManager::install("splatter")

To install the most recent development version from Github use:

BiocManager::install("Oshlack/splatter", dependencies = TRUE,
                     build_vignettes = TRUE)

2 Quickstart

Assuming you already have a matrix of count data similar to that you wish to simulate there are two simple steps to creating a simulated data set with Splatter. Here is an example a mock dataset generated with the scater package:

# Load package
suppressPackageStartupMessages({
  library(splatter)
  library(scater)
})

# Create mock data
set.seed(1)
sce <- mockSCE()

# Estimate parameters from mock data
params <- splatEstimate(sce)
#> NOTE: Library sizes have been found to be normally distributed instead of log-normal. You may want to check this is correct.
# Simulate data using estimated parameters
sim <- splatSimulate(params)
#> Getting parameters...
#> Creating simulation object...
#> Simulating library sizes...
#> Simulating gene means...
#> Simulating BCV...
#> Simulating counts...
#> Simulating dropout (if needed)...
#> Sparsifying assays...
#> Automatically converting to sparse matrices, threshold = 0.95
#> Skipping 'BatchCellMeans': estimated sparse size 1.5 * dense matrix
#> Skipping 'BaseCellMeans': estimated sparse size 1.5 * dense matrix
#> Skipping 'BCV': estimated sparse size 1.5 * dense matrix
#> Skipping 'CellMeans': estimated sparse size 1.5 * dense matrix
#> Skipping 'TrueCounts': estimated sparse size 2.7 * dense matrix
#> Skipping 'counts': estimated sparse size 2.7 * dense matrix
#> Done!

These steps will be explained in detail in the following sections but briefly the first step takes a dataset and estimates simulation parameters from it and the second step takes those parameters and simulates a new dataset.

3 The Splat simulation

Before we look at how we estimate parameters let’s first look at how Splatter simulates data and what those parameters are. We use the term ‘Splat’ to refer to the Splatter’s own simulation and differentiate it from the package itself. The core of the Splat model is a gamma-Poisson distribution used to generate a gene by cell matrix of counts. Mean expression levels for each gene are simulated from a gamma distribution and the Biological Coefficient of Variation is used to enforce a mean-variance trend before counts are simulated from a Poisson distribution. Splat also allows you to simulate expression outlier genes (genes with mean expression outside the gamma distribution) and dropout (random knock out of counts based on mean expression). Each cell is given an expected library size (simulated from a log-normal distribution) that makes it easier to match to a given dataset.

Splat can also simulate differential expression between groups of different types of cells or differentiation paths between different cells types where expression changes in a continuous way. These are described further in the simulating counts section.

4 The SplatParams object

All the parameters for the Splat simulation are stored in a SplatParams object. Let’s create a new one and see what it looks like.

params <- newSplatParams()
params
#> A Params object of class SplatParams 
#> Parameters can be (estimable) or [not estimable], 'Default' or  'NOT DEFAULT' 
#> Secondary parameters are usually set during simulation
#> 
#> Global: 
#> (Genes)  (Cells)   [Seed] 
#>   10000      100   235771 
#> 
#> 29 additional parameters 
#> 
#> Batches: 
#>     [Batches]  [Batch Cells]     [Location]        [Scale]       [Remove] 
#>             1            100            0.1            0.1          FALSE 
#> 
#> Mean: 
#>  (Rate)  (Shape) 
#>     0.3      0.6 
#> 
#> Library size: 
#> (Location)     (Scale)      (Norm) 
#>         11         0.2       FALSE 
#> 
#> Exprs outliers: 
#> (Probability)     (Location)        (Scale) 
#>          0.05              4            0.5 
#> 
#> Groups: 
#>      [Groups]  [Group Probs] 
#>             1              1 
#> 
#> Diff expr: 
#> [Probability]    [Down Prob]     [Location]        [Scale] 
#>           0.1            0.5            0.1            0.4 
#> 
#> BCV: 
#> (Common Disp)          (DoF) 
#>           0.1             60 
#> 
#> Dropout: 
#>     [Type]  (Midpoint)     (Shape) 
#>       none           0          -1 
#> 
#> Paths: 
#>         [From]         [Steps]          [Skew]    [Non-linear]  [Sigma Factor] 
#>              0             100             0.5             0.1             0.8

As well as telling us what type of object we have (“A Params object of class SplatParams”) and showing us the values of the parameter this output gives us some extra information. We can see which parameters can be estimated by the splatEstimate function (those in parentheses), which can’t be estimated (those in brackets) and which have been changed from their default values (those in ALL CAPS). For more details about the parameters of the Splat simulation refer to the Splat parameters vignette.

4.1 Getting and setting

If we want to look at a particular parameter, for example the number of genes to simulate, we can extract it using the getParam function:

getParam(params, "nGenes")
#> [1] 10000

Alternatively, to give a parameter a new value we can use the setParam function:

params <- setParam(params, "nGenes", 5000)
getParam(params, "nGenes")
#> [1] 5000

If we want to extract multiple parameters (as a list) or set multiple parameters we can use the getParams or setParams functions:

# Set multiple parameters at once (using a list)
params <- setParams(params, update = list(nGenes = 8000, mean.rate = 0.5))
# Extract multiple parameters as a list
getParams(params, c("nGenes", "mean.rate", "mean.shape"))
#> $nGenes
#> [1] 8000
#> 
#> $mean.rate
#> [1] 0.5
#> 
#> $mean.shape
#> [1] 0.6
# Set multiple parameters at once (using additional arguments)
params <- setParams(params, mean.shape = 0.5, de.prob = 0.2)
params
#> A Params object of class SplatParams 
#> Parameters can be (estimable) or [not estimable], 'Default' or  'NOT DEFAULT' 
#> Secondary parameters are usually set during simulation
#> 
#> Global: 
#> (GENES)  (Cells)   [Seed] 
#>    8000      100   235771 
#> 
#> 29 additional parameters 
#> 
#> Batches: 
#>     [Batches]  [Batch Cells]     [Location]        [Scale]       [Remove] 
#>             1            100            0.1            0.1          FALSE 
#> 
#> Mean: 
#>  (RATE)  (SHAPE) 
#>     0.5      0.5 
#> 
#> Library size: 
#> (Location)     (Scale)      (Norm) 
#>         11         0.2       FALSE 
#> 
#> Exprs outliers: 
#> (Probability)     (Location)        (Scale) 
#>          0.05              4            0.5 
#> 
#> Groups: 
#>      [Groups]  [Group Probs] 
#>             1              1 
#> 
#> Diff expr: 
#> [PROBABILITY]    [Down Prob]     [Location]        [Scale] 
#>           0.2            0.5            0.1            0.4 
#> 
#> BCV: 
#> (Common Disp)          (DoF) 
#>           0.1             60 
#> 
#> Dropout: 
#>     [Type]  (Midpoint)     (Shape) 
#>       none           0          -1 
#> 
#> Paths: 
#>         [From]         [Steps]          [Skew]    [Non-linear]  [Sigma Factor] 
#>              0             100             0.5             0.1             0.8

The parameters with have changed are now shown in ALL CAPS to indicate that they been changed form the default.

We can also set parameters directly when we call newSplatParams:

params <- newSplatParams(lib.loc = 12, lib.scale = 0.6)
getParams(params, c("lib.loc", "lib.scale"))
#> $lib.loc
#> [1] 12
#> 
#> $lib.scale
#> [1] 0.6

5 Estimating parameters

Splat allows you to estimate many of it’s parameters from a data set containing counts using the splatEstimate function.

# Get the mock counts matrix
counts <- counts(sce)

# Check that counts is an integer matrix
class(counts)
#> [1] "matrix" "array"
typeof(counts)
#> [1] "double"

# Check the dimensions, each row is a gene, each column is a cell
dim(counts)
#> [1] 2000  200

# Show the first few entries
counts[1:5, 1:5]
#>           Cell_001 Cell_002 Cell_003 Cell_004 Cell_005
#> Gene_0001        0        5        7      276       50
#> Gene_0002       12        0        0        0        0
#> Gene_0003       97      292       58       64      541
#> Gene_0004        0        0        0      170       19
#> Gene_0005      105      123      174      565     1061

params <- splatEstimate(counts)
#> NOTE: Library sizes have been found to be normally distributed instead of log-normal. You may want to check this is correct.

Here we estimated parameters from a counts matrix but splatEstimate can also take a SingleCellExperiment object. The estimation process has the following steps:

  1. Mean parameters are estimated by fitting a gamma distribution to the mean expression levels.
  2. Library size parameters are estimated by fitting a log-normal distribution to the library sizes.
  3. Expression outlier parameters are estimated by determining the number of outliers and fitting a log-normal distribution to their difference from the median.
  4. BCV parameters are estimated using the estimateDisp function from the edgeR package.
  5. Dropout parameters are estimated by checking if dropout is present and fitting a logistic function to the relationship between mean expression and proportion of zeros.

For more details of the estimation procedures see ?splatEstimate.

6 Simulating counts

Once we have a set of parameters we are happy with we can use splatSimulate to simulate counts. If we want to make small adjustments to the parameters we can provide them as additional arguments, alternatively if we don’t supply any parameters the defaults will be used:

sim <- splatSimulate(params, nGenes = 1000)
#> Getting parameters...
#> Creating simulation object...
#> Simulating library sizes...
#> Simulating gene means...
#> Simulating BCV...
#> Simulating counts...
#> Simulating dropout (if needed)...
#> Sparsifying assays...
#> Automatically converting to sparse matrices, threshold = 0.95
#> Skipping 'BatchCellMeans': estimated sparse size 1.5 * dense matrix
#> Skipping 'BaseCellMeans': estimated sparse size 1.5 * dense matrix
#> Skipping 'BCV': estimated sparse size 1.5 * dense matrix
#> Skipping 'CellMeans': estimated sparse size 1.5 * dense matrix
#> Skipping 'TrueCounts': estimated sparse size 2.76 * dense matrix
#> Skipping 'counts': estimated sparse size 2.76 * dense matrix
#> Done!
sim
#> class: SingleCellExperiment 
#> dim: 1000 200 
#> metadata(1): Params
#> assays(6): BatchCellMeans BaseCellMeans ... TrueCounts counts
#> rownames(1000): Gene1 Gene2 ... Gene999 Gene1000
#> rowData names(4): Gene BaseGeneMean OutlierFactor GeneMean
#> colnames(200): Cell1 Cell2 ... Cell199 Cell200
#> colData names(3): Cell Batch ExpLibSize
#> reducedDimNames(0):
#> mainExpName: NULL
#> altExpNames(0):

Looking at the output of splatSimulate we can see that sim is SingleCellExperiment object with 1000 features (genes) and 200 samples (cells). The main part of this object is a features by samples matrix containing the simulated counts (accessed using counts), although it can also hold other expression measures such as FPKM or TPM. Additionally a SingleCellExperiment contains phenotype information about each cell (accessed using colData) and feature information about each gene (accessed using rowData). Splatter uses these slots, as well as assays, to store information about the intermediate values of the simulation.

# Access the counts
counts(sim)[1:5, 1:5]
#>       Cell1 Cell2 Cell3 Cell4 Cell5
#> Gene1   287   611  1792   576   305
#> Gene2    89    24    25    49    34
#> Gene3     0     4     3     0     7
#> Gene4   273     6   144    77    98
#> Gene5     2    17     3     3    19
# Information about genes
head(rowData(sim))
#> DataFrame with 6 rows and 4 columns
#>              Gene BaseGeneMean OutlierFactor  GeneMean
#>       <character>    <numeric>     <numeric> <numeric>
#> Gene1       Gene1    261.51307             1 261.51307
#> Gene2       Gene2     22.50047             1  22.50047
#> Gene3       Gene3      1.91976             1   1.91976
#> Gene4       Gene4     56.32753             1  56.32753
#> Gene5       Gene5      3.23510             1   3.23510
#> Gene6       Gene6     82.68913             1  82.68913
# Information about cells
head(colData(sim))
#> DataFrame with 6 rows and 3 columns
#>              Cell       Batch ExpLibSize
#>       <character> <character>  <numeric>
#> Cell1       Cell1      Batch1     351561
#> Cell2       Cell2      Batch1     381671
#> Cell3       Cell3      Batch1     351649
#> Cell4       Cell4      Batch1     347866
#> Cell5       Cell5      Batch1     358121
#> Cell6       Cell6      Batch1     357503
# Gene by cell matrices
names(assays(sim))
#> [1] "BatchCellMeans" "BaseCellMeans"  "BCV"            "CellMeans"     
#> [5] "TrueCounts"     "counts"
# Example of cell means matrix
assays(sim)$CellMeans[1:5, 1:5]
#>             Cell1      Cell2       Cell3       Cell4      Cell5
#> Gene1 277.5198950 567.597662 1779.427382 581.4536927 288.470733
#> Gene2  90.7428662  15.688444   24.798346  45.2719838  26.406873
#> Gene3   0.2980249   1.778304    1.734762   0.9889553   5.530084
#> Gene4 270.0105024   4.562314  132.888421  78.9766305  88.476912
#> Gene5   3.4656266  17.243333    5.302897   4.5562093  18.832348

An additional (big) advantage of outputting a SingleCellExperiment is that we get immediate access to other analysis packages, such as the plotting functions in scater. For example we can make a PCA plot:

# Use scater to calculate logcounts
sim <- logNormCounts(sim)
# Plot PCA
sim <- runPCA(sim)
plotPCA(sim)

(NOTE: Your values and plots may look different as the simulation is random and produces different results each time it is run.)

For more details about the SingleCellExperiment object refer to the vignette. For information about what you can do with scater refer to the scater documentation and vignette.

The splatSimulate function outputs the following additional information about the simulation:

  • Cell information (colData)
    • Cell - Unique cell identifier.
    • Group - The group or path the cell belongs to.
    • ExpLibSize - The expected library size for that cell.
    • Step (paths only) - How far along the path each cell is.
  • Gene information (rowData)
    • Gene - Unique gene identifier.
    • BaseGeneMean - The base expression level for that gene.
    • OutlierFactor - Expression outlier factor for that gene (1 is not an outlier).
    • GeneMean - Expression level after applying outlier factors.
    • DEFac[Group] - The differential expression factor for each gene in a particular group (1 is not differentially expressed).
    • GeneMean[Group] - Expression level of a gene in a particular group after applying differential expression factors.
  • Gene by cell information (assays)
    • BaseCellMeans - The expression of genes in each cell adjusted for expected library size.
    • BCV - The Biological Coefficient of Variation for each gene in each cell.
    • CellMeans - The expression level of genes in each cell adjusted for BCV.
    • TrueCounts - The simulated counts before dropout.
    • Dropout - Logical matrix showing which counts have been dropped in which cells.

Values that have been added by Splatter are named using UpperCamelCase to separate them from the underscore_naming used by scater and other packages. For more information on the simulation see ?splatSimulate.

6.1 Simulating groups

So far we have only simulated a single population of cells but often we are interested in investigating a mixed population of cells and looking to see what cell types are present or what differences there are between them. Splatter is able to simulate these situations by changing the method argument Here we are going to simulate two groups, by specifying the group.prob parameter and setting the method parameter to "groups":

(NOTE: We have also set the verbose argument to FALSE to stop Splatter printing progress messages.)

sim.groups <- splatSimulate(group.prob = c(0.5, 0.5), method = "groups",
                            verbose = FALSE)
sim.groups <- logNormCounts(sim.groups)
sim.groups <- runPCA(sim.groups)
plotPCA(sim.groups, colour_by = "Group")

As we have set both the group probabilities to 0.5 we should get approximately equal numbers of cells in each group (around 50 in this case). If we wanted uneven groups we could set group.prob to any set of probabilities that sum to 1.

6.2 Simulating paths

The other situation that is often of interest is a differentiation process where one cell type is changing into another. Splatter approximates this process by simulating a series of steps between two groups and randomly assigning each cell to a step. We can create this kind of simulation using the "paths" method.

sim.paths <- splatSimulate(de.prob = 0.2, nGenes = 1000, method = "paths",
                           verbose = FALSE)
sim.paths <- logNormCounts(sim.paths)
sim.paths <- runPCA(sim.paths)
plotPCA(sim.paths, colour_by = "Step")

Here the colours represent the “step” of each cell or how far along the differentiation path it is. We can see that the cells with dark colours are more similar to the originating cell type and the light coloured cells are closer to the final, differentiated, cell type. By setting additional parameters it is possible to simulate more complex process (for example multiple mature cell types from a single progenitor).

6.3 Batch effects

Another factor that is important in the analysis of any sequencing experiment are batch effects, technical variation that is common to a set of samples processed at the same time. We apply batch effects by telling Splatter how many cells are in each batch:

sim.batches <- splatSimulate(batchCells = c(50, 50), verbose = FALSE)
sim.batches <- logNormCounts(sim.batches)
sim.batches <- runPCA(sim.batches)
plotPCA(sim.batches, colour_by = "Batch")

This looks at lot like when we simulated groups and that is because the process is very similar. The difference is that batch effects are applied to all genes, not just those that are differentially expressed, and the effects are usually smaller. By combining groups and batches we can simulate both unwanted variation that we aren’t interested in (batch) and the wanted variation we are looking for (group):

sim.groups <- splatSimulate(batchCells = c(50, 50), group.prob = c(0.5, 0.5),
                            method = "groups", verbose = FALSE)
sim.groups <- logNormCounts(sim.groups)
sim.groups <- runPCA(sim.groups)
plotPCA(sim.groups, shape_by = "Batch", colour_by = "Group")

Here we see that the effects of the group (first component) are stronger than the batch effects (second component) but by adjusting the parameters we could made the batch effects dominate.

6.4 Convenience functions

Each of the Splatter simulation methods has it’s own convenience function. To simulate a single population use splatSimulateSingle() (equivalent to splatSimulate(method = "single")), to simulate groups use splatSimulateGroups() (equivalent to splatSimulate(method = "groups")) or to simulate paths use splatSimulatePaths() (equivalent to splatSimulate(method = "paths")).

6.5 splatPop: Simulating populations

splatPop uses the splat model to simulate single cell count data across a population with relationship structure including expression quantitative loci (eQTL) effects. The major addition in splatPop is the splatPopSimulateMeans function, which simulates gene means for each gene for each individual using parameters estimated from real data. These simulated means are then used as input tosplatPopSimulateSC, which is essentially a wrapper around the base splatSimulate. For more information on generating population scale single-cell count data, see the splatPop vignette.

7 Other simulations

As well as it’s own Splat simulation method the Splatter package contains implementations of other single-cell RNA-seq simulations that have been published or wrappers around simulations included in other packages. To see all the available simulations run the listSims() function:

listSims()
#> Splatter currently contains 15 simulations 
#> 
#> Splat (splat) 
#> DOI: 10.1186/s13059-017-1305-0    GitHub: Oshlack/splatter    Dependencies:  
#> The Splat simulation generates means from a gamma distribution, adjusts them for BCV and generates counts from a gamma-poisson. Dropout and batch effects can be optionally added. 
#> 
#> Splat Single (splatSingle) 
#> DOI: 10.1186/s13059-017-1305-0    GitHub: Oshlack/splatter    Dependencies:  
#> The Splat simulation with a single population. 
#> 
#> Splat Groups (splatGroups) 
#> DOI: 10.1186/s13059-017-1305-0    GitHub: Oshlack/splatter    Dependencies:  
#> The Splat simulation with multiple groups. Each group can have it's own differential expression probability and fold change distribution. 
#> 
#> Splat Paths (splatPaths) 
#> DOI: 10.1186/s13059-017-1305-0    GitHub: Oshlack/splatter    Dependencies:  
#> The Splat simulation with differentiation paths. Each path can have it's own length, skew and probability. Genes can change in non-linear ways. 
#> 
#> Kersplat (kersplat) 
#> DOI:      GitHub: Oshlack/splatter    Dependencies: scuttle, igraph 
#> The Kersplat simulation extends the Splat model by adding a gene network, more complex cell structure, doublets and empty cells (Experimental). 
#> 
#> splatPop (splatPop) 
#> DOI:      GitHub: Oshlack/splatter    Dependencies: VariantAnnotation, preprocessCore 
#> The splatPop simulation enables splat simulations to be generated for multiple individuals in a population, accounting for correlation structure by simulating expression quantitative trait loci (eQTL). 
#> 
#> Simple (simple) 
#> DOI: 10.1186/s13059-017-1305-0    GitHub: Oshlack/splatter    Dependencies:  
#> A simple simulation with gamma means and negative binomial counts. 
#> 
#> Lun (lun) 
#> DOI: 10.1186/s13059-016-0947-7    GitHub: MarioniLab/Deconvolution2016    Dependencies:  
#> Gamma distributed means and negative binomial counts. Cells are given a size factor and differential expression can be simulated with fixed fold changes. 
#> 
#> Lun 2 (lun2) 
#> DOI: 10.1093/biostatistics/kxw055     GitHub: MarioniLab/PlateEffects2016     Dependencies: scran, lme4, pscl, limSolve 
#> Negative binomial counts where the means and dispersions have been sampled from a real dataset. The core feature of the Lun 2 simulation is the addition of plate effects. Differential expression can be added between two groups of plates and optionally a zero-inflated negative-binomial can be used. 
#> 
#> scDD (scDD) 
#> DOI: 10.1186/s13059-016-1077-y    GitHub: kdkorthauer/scDD    Dependencies: scDD 
#> The scDD simulation samples a given dataset and can simulate differentially expressed and differentially distributed genes between two conditions. 
#> 
#> BASiCS (BASiCS) 
#> DOI: 10.1371/journal.pcbi.1004333     GitHub: catavallejos/BASiCS     Dependencies: BASiCS 
#> The BASiCS simulation is based on a bayesian model used to deconvolve biological and technical variation and includes spike-ins and batch effects. 
#> 
#> mfa (mfa) 
#> DOI: 10.12688/wellcomeopenres.11087.1     GitHub: kieranrcampbell/mfa     Dependencies: mfa 
#> The mfa simulation produces a bifurcating pseudotime trajectory. This can optionally include genes with transient changes in expression and added dropout. 
#> 
#> PhenoPath (pheno) 
#> DOI: 10.1101/159913   GitHub: kieranrcampbell/phenopath   Dependencies: phenopath 
#> The PhenoPath simulation produces a pseudotime trajectory with different types of genes. 
#> 
#> ZINB-WaVE (zinb) 
#> DOI: 10.1101/125112   GitHub: drisso/zinbwave     Dependencies: zinbwave 
#> The ZINB-WaVE simulation simulates counts from a sophisticated zero-inflated negative-binomial distribution including cell and gene-level covariates. 
#> 
#> SparseDC (sparseDC) 
#> DOI: 10.1093/nar/gkx1113      GitHub: cran/SparseDC   Dependencies: SparseDC 
#> The SparseDC simulation simulates a set of clusters across two conditions, where some clusters may be present in only one condition.

Each simulation has it’s own prefix which gives the name of the functions associated with that simulation. For example the prefix for the simple simulation is simple so it would store it’s parameters in a SimpleParams object that can be created using newSimpleParams() or estimated from real data using simpleEstimate(). To simulate data using that simulation you would use simpleSimulate(). Each simulation returns a SingleCellExperiment object with intermediate values similar to that returned by splatSimulate(). For more detailed information on each simulation see the appropriate help page (eg. ?simpleSimulate for information on how the simple simulation works or ? lun2Estimate for details of how the Lun 2 simulation estimates parameters) or refer to the appropriate paper or package.

8 Other expression values

Splatter is designed to simulate count data but some analysis methods expect other expression values, particularly length-normalised values such as TPM or FPKM. The scater package has functions for adding these values to a SingleCellExperiment object but they require a length for each gene. The addGeneLengths function can be used to simulate these lengths:

sim <- simpleSimulate(verbose = FALSE)
sim <- addGeneLengths(sim)
head(rowData(sim))
#> DataFrame with 6 rows and 3 columns
#>              Gene  GeneMean    Length
#>       <character> <numeric> <numeric>
#> Gene1       Gene1 0.2504815       953
#> Gene2       Gene2 9.8794242      2527
#> Gene3       Gene3 0.2559414      3056
#> Gene4       Gene4 0.0920302      2079
#> Gene5       Gene5 0.9477263      2317
#> Gene6       Gene6 0.8552610      1591

We can then use scater to calculate TPM:

tpm(sim) <- calculateTPM(sim, rowData(sim)$Length)
tpm(sim)[1:5, 1:5]
#> 5 x 5 sparse Matrix of class "dgCMatrix"
#>          Cell1     Cell2    Cell3     Cell4     Cell5
#> Gene1   .        .         .        .         .      
#> Gene2 249.5228 796.07660 637.2111 868.08687 125.72680
#> Gene3   .        .         .       51.27280   .      
#> Gene4  75.8230   .         .       75.36781   .      
#> Gene5 136.0691  66.78681   .        .        68.56099

The default method used by addGeneLengths to simulate lengths is to generate values from a log-normal distribution which are then rounded to give an integer length. The parameters for this distribution are based on human protein coding genes but can be adjusted if needed (for example for other species). Alternatively lengths can be sampled from a provided vector (see ?addGeneLengths for details and an example).

9 Reducing simulation size

The simulations in Splatter include many of the intermediate values used during the simulation process as part of the final output. These values can be useful for evaluating various things but if you don’t need them they can greatly increase the size of the object. If you would like to reduce the size of your simulation output you can use the minimiseSCE() function:

sim <- splatSimulate()
#> Getting parameters...
#> Creating simulation object...
#> Simulating library sizes...
#> Simulating gene means...
#> Simulating BCV...
#> Simulating counts...
#> Simulating dropout (if needed)...
#> Sparsifying assays...
#> Automatically converting to sparse matrices, threshold = 0.95
#> Skipping 'BatchCellMeans': estimated sparse size 1.5 * dense matrix
#> Skipping 'BaseCellMeans': estimated sparse size 1.5 * dense matrix
#> Skipping 'BCV': estimated sparse size 1.5 * dense matrix
#> Skipping 'CellMeans': estimated sparse size 1.49 * dense matrix
#> Skipping 'TrueCounts': estimated sparse size 1.65 * dense matrix
#> Skipping 'counts': estimated sparse size 1.65 * dense matrix
#> Done!
minimiseSCE(sim)
#> Minimising SingleCellExperiment...
#> Original size: 43.9 Mb
#> Removing all rowData columns
#> Removing all colData columns
#> Removing all metadata items
#> Keeping 1 assays: counts
#> Removing 5 assays: BatchCellMeans, BaseCellMeans, BCV, CellMeans, TrueCounts
#> Sparsifying assays...
#> Automatically converting to sparse matrices, threshold = 0.95
#> Skipping 'counts': estimated sparse size 1.65 * dense matrix
#> Minimised size: 5.3 Mb (12% of original)
#> class: SingleCellExperiment 
#> dim: 10000 100 
#> metadata(0):
#> assays(1): counts
#> rownames(10000): Gene1 Gene2 ... Gene9999 Gene10000
#> rowData names(0):
#> colnames(100): Cell1 Cell2 ... Cell99 Cell100
#> colData names(0):
#> reducedDimNames(0):
#> mainExpName: NULL
#> altExpNames(0):

By default it will remove everything in rowData(sce), colData(sce) and metadata(sce) and all assays except for counts. If there are other things you would like to keep you can specify them in the various keep arguments. Giving a character will keep only columns/items with those names or you can use TRUE to keep everything in that slot.

minimiseSCE(sim, rowData.keep = "Gene", colData.keep = c("Cell", "Batch"),
            metadata.keep = TRUE)
#> Minimising SingleCellExperiment...
#> Original size: 43.9 Mb
#> Keeping 1 rowData columns: Gene
#> Removing 3 rowData columns: BaseGeneMean, OutlierFactor, GeneMean
#> Keeping 2 colData columns: Cell, Batch
#> Removing 1 colData columns: ExpLibSize
#> Keeping 1 assays: counts
#> Removing 5 assays: BatchCellMeans, BaseCellMeans, BCV, CellMeans, TrueCounts
#> Sparsifying assays...
#> Automatically converting to sparse matrices, threshold = 0.95
#> Skipping 'counts': estimated sparse size 1.65 * dense matrix
#> Minimised size: 5.9 Mb (14% of original)
#> class: SingleCellExperiment 
#> dim: 10000 100 
#> metadata(1): Params
#> assays(1): counts
#> rownames(10000): Gene1 Gene2 ... Gene9999 Gene10000
#> rowData names(1): Gene
#> colnames(100): Cell1 Cell2 ... Cell99 Cell100
#> colData names(2): Cell Batch
#> reducedDimNames(0):
#> mainExpName: NULL
#> altExpNames(0):

10 Comparing simulations and real data

One thing you might like to do after simulating data is to compare it to a real dataset, or compare simulations with different parameters or models. Splatter provides a function compareSCEs that aims to make these comparisons easier. As the name suggests this function takes a list of SingleCellExperiment objects, combines the datasets and produces some plots comparing them. Let’s make two small simulations and see how they compare.

sim1 <- splatSimulate(nGenes = 1000, batchCells = 20, verbose = FALSE)
sim2 <- simpleSimulate(nGenes = 1000, nCells = 20, verbose = FALSE)
comparison <- compareSCEs(list(Splat = sim1, Simple = sim2))

names(comparison)
#> [1] "RowData" "ColData" "Plots"
names(comparison$Plots)
#> [1] "Means"        "Variances"    "MeanVar"      "LibrarySizes" "ZerosGene"   
#> [6] "ZerosCell"    "MeanZeros"    "VarGeneCor"

The returned list has three items. The first two are the combined datasets by gene (RowData) and by cell (ColData) and the third contains some comparison plots (produced using ggplot2), for example a plot of the distribution of means:

comparison$Plots$Means

These are only a few of the plots you might want to consider but it should be easy to make more using the returned data. For example, we could plot the number of expressed genes against the library size:

library("ggplot2")
ggplot(comparison$ColData, aes(x = sum, y = detected, colour = Dataset)) +
    geom_point()

10.1 Comparing differences

Sometimes instead of visually comparing datasets it may be more interesting to look at the differences between them. We can do this using the diffSCEs function. Similar to compareSCEs this function takes a list of SingleCellExperiment objects but now we also specify one to be a reference. A series of similar plots are returned but instead of showing the overall distributions they demonstrate differences from the reference.

difference <- diffSCEs(list(Splat = sim1, Simple = sim2), ref = "Simple")
difference$Plots$Means

We also get a series of Quantile-Quantile plot that can be used to compare distributions.

difference$QQPlots$Means

10.2 Making panels

Each of these comparisons makes several plots which can be a lot to look at. To make this easier, or to produce figures for publications, you can make use of the functions makeCompPanel, makeDiffPanel and makeOverallPanel.

These functions combine the plots into a single panel using the cowplot package. The panels can be quite large and hard to view (for example in RStudio’s plot viewer) so it can be better to output the panels and view them separately. Luckily cowplot provides a convenient function for saving the images. Here are some suggested parameters for outputting each of the panels:

# This code is just an example and is not run
panel <- makeCompPanel(comparison)
cowplot::save_plot("comp_panel.png", panel, nrow = 4, ncol = 3)

panel <- makeDiffPanel(difference)
cowplot::save_plot("diff_panel.png", panel, nrow = 3, ncol = 5)

panel <- makeOverallPanel(comparison, difference)
cowplot::save_plot("overall_panel.png", panel, ncol = 4, nrow = 7)

11 Citing Splatter

If you use Splatter in your work please cite our paper:

citation("splatter")
#> 
#>   Zappia L, Phipson B, Oshlack A. Splatter: Simulation of single-cell
#>   RNA sequencing data. Genome Biology. 2017;
#>   doi:10.1186/s13059-017-1305-0
#> 
#> A BibTeX entry for LaTeX users is
#> 
#>   @Article{,
#>     author = {Luke Zappia and Belinda Phipson and Alicia Oshlack},
#>     title = {Splatter: simulation of single-cell RNA sequencing data},
#>     journal = {Genome Biology},
#>     year = {2017},
#>     url = {http://dx.doi.org/10.1186/s13059-017-1305-0},
#>     doi = {10.1186/s13059-017-1305-0},
#>   }

Session information

sessionInfo()
#> R version 4.1.0 (2021-05-18)
#> Platform: x86_64-pc-linux-gnu (64-bit)
#> Running under: Ubuntu 20.04.2 LTS
#> 
#> Matrix products: default
#> BLAS:   /home/biocbuild/bbs-3.13-bioc/R/lib/libRblas.so
#> LAPACK: /home/biocbuild/bbs-3.13-bioc/R/lib/libRlapack.so
#> 
#> locale:
#>  [1] LC_CTYPE=en_US.UTF-8       LC_NUMERIC=C              
#>  [3] LC_TIME=en_GB              LC_COLLATE=C              
#>  [5] LC_MONETARY=en_US.UTF-8    LC_MESSAGES=en_US.UTF-8   
#>  [7] LC_PAPER=en_US.UTF-8       LC_NAME=C                 
#>  [9] LC_ADDRESS=C               LC_TELEPHONE=C            
#> [11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C       
#> 
#> attached base packages:
#> [1] parallel  stats4    stats     graphics  grDevices utils     datasets 
#> [8] methods   base     
#> 
#> other attached packages:
#>  [1] VariantAnnotation_1.38.0    Rsamtools_2.8.0            
#>  [3] Biostrings_2.60.0           XVector_0.32.0             
#>  [5] scater_1.20.0               ggplot2_3.3.3              
#>  [7] scuttle_1.2.0               splatter_1.16.1            
#>  [9] SingleCellExperiment_1.14.0 SummarizedExperiment_1.22.0
#> [11] Biobase_2.52.0              GenomicRanges_1.44.0       
#> [13] GenomeInfoDb_1.28.0         IRanges_2.26.0             
#> [15] S4Vectors_0.30.0            BiocGenerics_0.38.0        
#> [17] MatrixGenerics_1.4.0        matrixStats_0.58.0         
#> [19] BiocStyle_2.20.0           
#> 
#> loaded via a namespace (and not attached):
#>   [1] ggbeeswarm_0.6.0          colorspace_2.0-1         
#>   [3] rjson_0.2.20              ellipsis_0.3.2           
#>   [5] BiocNeighbors_1.10.0      farver_2.1.0             
#>   [7] bit64_4.0.5               AnnotationDbi_1.54.0     
#>   [9] fansi_0.4.2               splines_4.1.0            
#>  [11] sparseMatrixStats_1.4.0   cachem_1.0.5             
#>  [13] knitr_1.33                jsonlite_1.7.2           
#>  [15] dbplyr_2.1.1              png_0.1-7                
#>  [17] BiocManager_1.30.15       compiler_4.1.0           
#>  [19] httr_1.4.2                backports_1.2.1          
#>  [21] assertthat_0.2.1          Matrix_1.3-3             
#>  [23] fastmap_1.1.0             limma_3.48.0             
#>  [25] BiocSingular_1.8.0        htmltools_0.5.1.1        
#>  [27] prettyunits_1.1.1         tools_4.1.0              
#>  [29] rsvd_1.0.5                gtable_0.3.0             
#>  [31] glue_1.4.2                GenomeInfoDbData_1.2.6   
#>  [33] dplyr_1.0.6               rappdirs_0.3.3           
#>  [35] Rcpp_1.0.6                jquerylib_0.1.4          
#>  [37] vctrs_0.3.8               preprocessCore_1.54.0    
#>  [39] rtracklayer_1.52.0        DelayedMatrixStats_1.14.0
#>  [41] xfun_0.23                 stringr_1.4.0            
#>  [43] beachmat_2.8.0            lifecycle_1.0.0          
#>  [45] irlba_2.3.3               restfulr_0.0.13          
#>  [47] XML_3.99-0.6              edgeR_3.34.0             
#>  [49] MASS_7.3-54               zlibbioc_1.38.0          
#>  [51] scales_1.1.1              BSgenome_1.60.0          
#>  [53] hms_1.1.0                 RColorBrewer_1.1-2       
#>  [55] yaml_2.2.1                curl_4.3.1               
#>  [57] memoise_2.0.0             gridExtra_2.3            
#>  [59] sass_0.4.0                biomaRt_2.48.0           
#>  [61] stringi_1.6.2             RSQLite_2.2.7            
#>  [63] highr_0.9                 BiocIO_1.2.0             
#>  [65] ScaledMatrix_1.0.0        checkmate_2.0.0          
#>  [67] GenomicFeatures_1.44.0    filelock_1.0.2           
#>  [69] BiocParallel_1.26.0       rlang_0.4.11             
#>  [71] pkgconfig_2.0.3           bitops_1.0-7             
#>  [73] evaluate_0.14             lattice_0.20-44          
#>  [75] purrr_0.3.4               labeling_0.4.2           
#>  [77] GenomicAlignments_1.28.0  cowplot_1.1.1            
#>  [79] bit_4.0.4                 tidyselect_1.1.1         
#>  [81] magrittr_2.0.1            bookdown_0.22            
#>  [83] R6_2.5.0                  magick_2.7.2             
#>  [85] generics_0.1.0            DelayedArray_0.18.0      
#>  [87] DBI_1.1.1                 pillar_1.6.1             
#>  [89] withr_2.4.2               fitdistrplus_1.1-3       
#>  [91] survival_3.2-11           KEGGREST_1.32.0          
#>  [93] RCurl_1.98-1.3            tibble_3.1.2             
#>  [95] crayon_1.4.1              utf8_1.2.1               
#>  [97] BiocFileCache_2.0.0       rmarkdown_2.8            
#>  [99] viridis_0.6.1             progress_1.2.2           
#> [101] locfit_1.5-9.4            grid_4.1.0               
#> [103] blob_1.2.1                digest_0.6.27            
#> [105] munsell_0.5.0             beeswarm_0.3.1           
#> [107] viridisLite_0.4.0         vipor_0.4.5              
#> [109] bslib_0.2.5.1