Nebulosa 1.2.0
Due to the sparsity observed in single-cell data (e.g. RNA-seq, ATAC-seq), the
visualization of cell features (e.g. gene, peak) is frequently affected and
unclear, especially when it is overlaid with clustering to annotate cell
types. Nebulosa
is an R package to visualize data from single cells based on
kernel density estimation. It aims to recover the signal from dropped-out
features by incorporating the similarity between cells allowing a “convolution”
of the cell features.
For this vignette, let’s use Nebulosa
with the Seurat
package.
First, we’ll do a brief/standard data processing.
library("Nebulosa")
library("Seurat")
## Attaching SeuratObject
##
## Attaching package: 'Seurat'
## The following object is masked from 'package:SummarizedExperiment':
##
## Assays
library("BiocFileCache")
Let’s download a dataset of 3k PBMCs (available from 10X Genomics). This same dataset is commonly used in Seurat vignettes. The code below will download, store, and uncompress the data in a temporary directory.
bfc <- BiocFileCache(ask = FALSE)
data_file <- bfcrpath(bfc, file.path(
"https://s3-us-west-2.amazonaws.com/10x.files/samples/cell",
"pbmc3k",
"pbmc3k_filtered_gene_bc_matrices.tar.gz"
))
untar(data_file, exdir = tempdir())
Then, we can read the gene expression matrix using the Read10X
from Seurat
data <- Read10X(data.dir = file.path(tempdir(),
"filtered_gene_bc_matrices",
"hg19"
))
Let’s create a Seurat object with features being expressed in at least 3 cells and cells expressing at least 200 genes.
pbmc <- CreateSeuratObject(
counts = data,
project = "pbmc3k",
min.cells = 3,
min.features = 200
)
## Warning: Feature names cannot have underscores ('_'), replacing with dashes
## ('-')
Remove outlier cells based on the number of genes being expressed in each cell (below 2500 genes) and expression of mitochondrial genes (below 5%).
pbmc[["percent.mt"]] <- PercentageFeatureSet(pbmc, pattern = "^MT-")
pbmc <- subset(pbmc, subset = nFeature_RNA < 2500 & percent.mt < 5)
Let’s use SCTransform
to stabilize the variance of the data by regressing out
the effect of the sequencing depth from each cell.
pbmc <- SCTransform(pbmc, verbose = FALSE)
Once the data is normalized and scaled, we can run a Principal Component Analysis (PCA) first to reduce the dimensions of our data from 26286 features to 50 principal components. To visualize the principal components, we can run a Uniform Manifold Approximation and Projection for Dimension Reduction (UMAP) using the first 30 principal components to obtain a two-dimentional space.
pbmc <- RunPCA(pbmc)
pbmc <- RunUMAP(pbmc, dims = 1:30)
To assess cell similarity, let’s cluster the data by constructing a Shared Nearest Neighbor (SNN) Graph using the first 30 principal components and applying the Louvain algorithm.
pbmc <- FindNeighbors(pbmc, dims = 1:30)
pbmc <- FindClusters(pbmc)
## Modularity Optimizer version 1.3.0 by Ludo Waltman and Nees Jan van Eck
##
## Number of nodes: 2638
## Number of edges: 111648
##
## Running Louvain algorithm...
## Maximum modularity in 10 random starts: 0.8334
## Number of communities: 13
## Elapsed time: 0 seconds
Nebulosa
The main function from Nebulosa
is the plot_density
. For usability, it
resembles the FeaturePlot
function from Seurat
.
Let’s plot the kernel density estimate for CD4
as follows
plot_density(pbmc, "CD4")
For comparison, let’s also plot a standard scatterplot using Seurat
FeaturePlot(pbmc, "CD4")
FeaturePlot(pbmc, "CD4", order = TRUE)
By smoothing the data, Nebulosa
allows a better visualization of the global
expression of CD4 in myeloid and CD4+ T cells. Notice that the “random”
expression of CD4 in other areas of the plot is removed as the expression of
this gene is not supported by many cells in those areas. Furthermore, CD4+
cells appear to show considerable dropout rate.
Let’s plot the expression of CD4 with Nebulosa
next to the clustering results
DimPlot(pbmc, label = TRUE, repel = TRUE)
We can now easily identify that clusters 0
and 2
correspond to CD4+ T cells
if we plot CD3D too.
plot_density(pbmc, "CD3D")
Characterize cell populations usually relies in more than a single marker. Nebulosa allows the visualization of the joint density of from multiple features in a single plot.
Users familiarized with PBMC datasets may know that CD8+ CCR7+ cells usually cluster next to CD4+ CCR7+ and separate from the rest of CD8+ cells. Let’s aim to identify Naive CD8+ T cells. To do so, we can just add another gene to the vector containing the features to visualize.
p3 <- plot_density(pbmc, c("CD8A", "CCR7"))
p3 + plot_layout(ncol = 1)
Nebulosa
can return a joint density plot by multiplying the densities
from all query genes by using the joint = TRUE
parameter:
p4 <- plot_density(pbmc, c("CD8A", "CCR7"), joint = TRUE)
p4 + plot_layout(ncol = 1)
When compared to the clustering results, we can easily identify that Naive
CD8+ T cells correspond to cluster 8
.
Nebulosa
returns the density estimates for each gene along with the joint
density across all provided genes. By setting combine = FALSE
, we can obtain
a list of ggplot objects where the last plot corresponds to the joint density
estimate.
p_list <- plot_density(pbmc, c("CD8A", "CCR7"), joint = TRUE, combine = FALSE)
p_list[[length(p_list)]]
Likewise, the identification of Naive CD4+ T cells becomes straightforward by
combining CD4
and CCR7
:
p4 <- plot_density(pbmc, c("CD4", "CCR7"), joint = TRUE)
p4 + plot_layout(ncol = 1)
Notice that these cells are mainly constrained to cluster 0
p4[[3]] / DimPlot(pbmc, label = TRUE, repel = TRUE)
In summary,Nebulosa
can be useful to recover the signal from dropped-out genes
and improve their visualization in a two-dimensional space. We recommend using
Nebulosa
particularly for dropped-out genes. For fairly well-expressed genes,
the direct visualization of the gene expression may be preferable. We encourage
users to use Nebulosa
along with the core visualization methods from the
Seurat
and Bioconductor
environments as well as other visualization methods
to draw more informed conclusions about their data.