Single-Cell Consensus Clustering (SC3
) is a tool for unsupervised clustering of scRNA-seq data. SC3
achieves high accuracy and robustness by consistently integrating different clustering solutions through a consensus approach. An interactive graphical implementation makes SC3
accessible to a wide audience of users. In addition, SC3
also aids biological interpretation by identifying marker genes, differentially expressed genes and outlier cells. A manuscript describing SC3
in details is published in Nature Methods.
SingleCellExperiment
, QC and scater
SC3
is a purely clustering tool and it does not provide functions for the sequencing quality control (QC) or normalisation. On the contrary it is expected that these preprocessing steps are performed by a user in advance. To encourage the preprocessing, SC3
is built on top of the Bioconductor’s SingleCellExperiment class and uses functionality of scater package for QC.
SC3
InputIf you already have a SingleCellExperiment
object created and QCed using scater
then proceed to the next chapter.
If you have a matrix containing expression data that was QCed and normalised by some other tool, then we first need to form an SingleCellExperiment
object containing the data. For illustrative purposes we will use an example expression matrix provided with SC3
. The dataset (yan
) represents FPKM gene expression of 90 cells derived from human embryo. The authors (Yan et al.) have defined developmental stages of all cells in the original publication (ann
data frame). The rows in the yan
dataset correspond to genes and columns correspond to cells.
library(SingleCellExperiment)
library(SC3)
library(scater)
head(ann)
## cell_type1
## Oocyte..1.RPKM. zygote
## Oocyte..2.RPKM. zygote
## Oocyte..3.RPKM. zygote
## Zygote..1.RPKM. zygote
## Zygote..2.RPKM. zygote
## Zygote..3.RPKM. zygote
yan[1:3, 1:3]
## Oocyte..1.RPKM. Oocyte..2.RPKM. Oocyte..3.RPKM.
## C9orf152 0.0 0.0 0.0
## RPS11 1219.9 1021.1 931.6
## ELMO2 7.0 12.2 9.3
The ann
dataframe contains just cell_type1
column which correspond to the cell labels provided by authors of the original publication. Note that in general it can also contain more information about the cells, such as plate, run, well, date etc.
Now we can create a SingleCellExperiment
object from yan
expression matrix.
Note that SC3
requires both counts
and logcounts
slots to exist in the input SingleCellExperiment
object. The counts
slot is used for gene filtering, which is based on gene dropout rates. logcounts
slot, which is supposed to contain both normalised and log-transformed expression matrix, is used in the main clustering algorithm. In the case of the yan
dataset even though the counts
are not available (we only have FPKM values) we can use the FPKM values for gene dropout rate calculations since FPKM normalisation does not change the dropout rate.
SC3
also requires the feature_symbol
column of the rowData
slot of the input SingleCellExperiment
object to contain preferable feature names (genes/transcript) which will be used in the futher visualisations.
Additionally, if spike-ins are defined via isSpike
function, SC3
will automatically remove them before doing clustering:
# create a SingleCellExperiment object
sce <- SingleCellExperiment(
assays = list(
counts = as.matrix(yan),
logcounts = log2(as.matrix(yan) + 1)
),
colData = ann
)
# define feature names in feature_symbol column
rowData(sce)$feature_symbol <- rownames(sce)
# remove features with duplicated names
sce <- sce[!duplicated(rowData(sce)$feature_symbol), ]
# define spike-ins
isSpike(sce, "ERCC") <- grepl("ERCC", rowData(sce)$feature_symbol)
scater
allows a user to quickly visualize and assess any SingleCellExperiment
object, for example using a PCA plot:
plotPCA(sce, colour_by = "cell_type1")
If you would like to explore clustering of your data in the range of k
s (the number of clusters) from 2 to 4, you just need to run the main sc3
method and define the range of k
s using the ks
parameter (here we also ask SC3
to calculate biological features based on the identified cell clusters):
sce <- sc3(sce, ks = 2:4, biology = TRUE)
## Setting SC3 parameters...
## Calculating distances between the cells...
## Performing transformations and calculating eigenvectors...
## Performing k-means clustering...
## Calculating consensus matrix...
## Calculating biology...
By default
SC3
will use all but one cores of your machine. You can manually set the number of cores to be used by setting then_cores
parameter in thesc3
call.
To quickly and easily explore the SC3
solutions using an interactive Shiny application use the following method:
sc3_interactive(sce)
Visual exploration can provide a reasonable estimate of the number of clusters k
. Once a preferable k
is chosen it is also possible to export the results into an Excel file:
sc3_export_results_xls(sce)
This will write all results to sc3_results.xls
file. The name of the file can be controlled by the filename
parameter.
SC3
writes all its results obtained for cells to the colData
slot of the sce
object by adding additional columns to it. This slot also contains all other cell features calculated by the scater
package either automatically during the sce
object creation or during the calculateQCMetrics
call. One can identify the SC3
results using the "sc3_"
prefix:
col_data <- colData(sce)
head(col_data[ , grep("sc3_", colnames(col_data))])
## DataFrame with 6 rows and 6 columns
## sc3_2_clusters sc3_3_clusters sc3_4_clusters
## <factor> <factor> <factor>
## Oocyte..1.RPKM. 2 2 2
## Oocyte..2.RPKM. 2 2 2
## Oocyte..3.RPKM. 2 2 2
## Zygote..1.RPKM. 2 2 2
## Zygote..2.RPKM. 2 2 2
## Zygote..3.RPKM. 2 2 2
## sc3_2_log2_outlier_score sc3_3_log2_outlier_score
## <numeric> <numeric>
## Oocyte..1.RPKM. 0 1.67032836742415
## Oocyte..2.RPKM. 0 1.69878936817061
## Oocyte..3.RPKM. 0 1.16603348178053
## Zygote..1.RPKM. 0 0
## Zygote..2.RPKM. 0 0
## Zygote..3.RPKM. 0 0
## sc3_4_log2_outlier_score
## <numeric>
## Oocyte..1.RPKM. 1.67032836742407
## Oocyte..2.RPKM. 1.69878936817053
## Oocyte..3.RPKM. 1.16603348178043
## Zygote..1.RPKM. 0
## Zygote..2.RPKM. 0
## Zygote..3.RPKM. 0
Additionally, having SC3
results stored in the same slot makes it possible to highlight them during any of the scater
’s plotting function call, for example:
plotPCA(
sce,
colour_by = "sc3_3_clusters",
size_by = "sc3_3_log2_outlier_score"
)
SC3
writes all its results obtained for features (genes/transcripts) to the rowData
slot of the sce
object by adding additional columns to it. This slot also contains all other feature values calculated by the scater
package either automatically during the sce
object creation or during the calculateQCMetrics
call. One can identify the SC3
results using the "sc3_"
prefix:
row_data <- rowData(sce)
head(row_data[ , grep("sc3_", colnames(row_data))])
## DataFrame with 6 rows and 13 columns
## sc3_gene_filter sc3_2_markers_clusts sc3_2_markers_padj
## <logical> <numeric> <numeric>
## C9orf152 FALSE NA NA
## RPS11 FALSE NA NA
## ELMO2 TRUE 2 3.42891755294448e-06
## CREB3L1 TRUE 2 1
## PNMA1 FALSE NA NA
## MMP2 TRUE 1 1
## sc3_2_markers_auroc sc3_3_markers_clusts sc3_3_markers_padj
## <numeric> <numeric> <numeric>
## C9orf152 NA NA NA
## RPS11 NA NA NA
## ELMO2 0.905833333333333 2 8.74957155809462e-08
## CREB3L1 0.635833333333333 2 0.000364998858198823
## PNMA1 NA NA NA
## MMP2 0.549722222222222 1 1
## sc3_3_markers_auroc sc3_4_markers_clusts sc3_4_markers_padj
## <numeric> <numeric> <numeric>
## C9orf152 NA NA NA
## RPS11 NA NA NA
## ELMO2 0.96969696969697 2 8.97459044385902e-08
## CREB3L1 0.827020202020202 2 0.00038529310418705
## PNMA1 NA NA NA
## MMP2 0.549722222222222 3 1
## sc3_4_markers_auroc sc3_2_de_padj sc3_3_de_padj
## <numeric> <numeric> <numeric>
## C9orf152 NA NA NA
## RPS11 NA NA NA
## ELMO2 0.96969696969697 3.33654105464895e-06 7.88333987242478e-10
## CREB3L1 0.827020202020202 1 0.00203864534241844
## PNMA1 NA NA NA
## MMP2 0.543928571428571 1 1
## sc3_4_de_padj
## <numeric>
## C9orf152 NA
## RPS11 NA
## ELMO2 1.86540162226264e-09
## CREB3L1 0.00616104934849165
## PNMA1 NA
## MMP2 1
Because the biological features were also calculated for each k
, one can find ajusted p-values for both differential expression and marker genes, as well as the area under the ROC curve values (see ?sc3_calc_biology
for more information).
The default settings of SC3
allow to cluster (using a single k
) a dataset of 2,000 cells in about 20-30 minutes.
For datasets with more than 2,000 cells SC3
automatically adjusts some of its parameters (see below). This allows to cluster a dataset of 5,000 cells in about 20-30 minutes. The parameters can also be manually adjusted for datasets with any number of cells.
For datasets with more than 5,000 cells SC3
utilizes a hybrid approach that combines unsupervised and supervised clusterings (see below). Namely, SC3
selects a subset of cells uniformly at random, and obtains clusters from this subset. Subsequently, the inferred labels are used to train a Support Vector Machine (SVM), which is employed to assign labels to the remaining cells. Training cells can also be manually selected by providing their indeces.
SC3
also provides methods for plotting all figures from the interactive session.
The consensus matrix is a N by N matrix, where N is the number of cells in the input dataset. It represents similarity between the cells based on the averaging of clustering results from all combinations of clustering parameters. Similarity 0 (blue) means that the two cells are always assigned to different clusters. In contrast, similarity 1 (red) means that the two cells are always assigned to the same cluster. The consensus matrix is clustered by hierarchical clustering and has a diagonal-block structure. Intuitively, the perfect clustering is achieved when all diagonal blocks are completely red and all off-diagonal elements are completely blue.
sc3_plot_consensus(sce, k = 3)
It is also possible to annotate cells (columns of the consensus matrix) with any column of the colData
slot of the sce
object.
sc3_plot_consensus(
sce, k = 3,
show_pdata = c(
"cell_type1",
"log10_total_features",
"sc3_3_clusters",
"sc3_3_log2_outlier_score"
)
)
## Provided columns 'log10_total_features' do not exist in the phenoData table!
A silhouette is a quantitative measure of the diagonality of the consensus matrix. An average silhouette width (shown at the bottom left of the silhouette plot) varies from 0 to 1, where 1 represents a perfectly block-diagonal consensus matrix and 0 represents a situation where there is no block-diagonal structure. The best clustering is achieved when the average silhouette width is close to 1.
sc3_plot_silhouette(sce, k = 3)
The expression panel represents the original input expression matrix (cells in columns and genes in rows) after cell and gene filters. Genes are clustered by kmeans with k = 100 (dendrogram on the left) and the heatmap represents the expression levels of the gene cluster centers after log2-scaling.
sc3_plot_expression(sce, k = 3)
It is also possible to annotate cells (columns of the expression matrix) with any column of the colData
slot of the sce
object.
sc3_plot_expression(
sce, k = 3,
show_pdata = c(
"cell_type1",
"log10_total_features",
"sc3_3_clusters",
"sc3_3_log2_outlier_score"
)
)
## Provided columns 'log10_total_features' do not exist in the phenoData table!
Stability index shows how stable each cluster is accross the selected range of k
s. The stability index varies between 0 and 1, where 1 means that the same cluster appears in every solution for different k
.
sc3_plot_cluster_stability(sce, k = 3)
Differential expression is calculated using the non-parametric Kruskal-Wallis test. A significant p-value indicates that gene expression in at least one cluster stochastically dominates one other cluster. SC3 provides a list of all differentially expressed genes with adjusted p-values < 0.01 and plots gene expression profiles of the 50 genes with the lowest p-values. Note that the calculation of differential expression after clustering can introduce a bias in the distribution of p-values, and thus we advise to use the p-values for ranking the genes only.
sc3_plot_de_genes(sce, k = 3)
It is also possible to annotate cells (columns of the matrix containing DE genes) with any column of the colData
slot of the sce
object.
sc3_plot_de_genes(
sce, k = 3,
show_pdata = c(
"cell_type1",
"log10_total_features",
"sc3_3_clusters",
"sc3_3_log2_outlier_score"
)
)
## Provided columns 'log10_total_features' do not exist in the phenoData table!
To find marker genes, for each gene a binary classifier is constructed based on the mean cluster expression values. The classifier prediction is then calculated using the gene expression ranks. The area under the receiver operating characteristic (ROC) curve is used to quantify the accuracy of the prediction. A p-value is assigned to each gene by using the Wilcoxon signed rank test. By default the genes with the area under the ROC curve (AUROC) > 0.85 and with the p-value < 0.01 are selected and the top 10 marker genes of each cluster are visualized in this heatmap.
sc3_plot_markers(sce, k = 3)
It is also possible to annotate cells (columns of the matrix containing marker genes) with any column of the colData
slot of the sce
object.
sc3_plot_markers(
sce, k = 3,
show_pdata = c(
"cell_type1",
"log10_total_features",
"sc3_3_clusters",
"sc3_3_log2_outlier_score"
)
)
## Provided columns 'log10_total_features' do not exist in the phenoData table!
The main sc3
method explained above is a wrapper that calls several other SC3
methods in the following order:
sc3_prepare
sc3_estimate_k
sc3_calc_dists
sc3_calc_transfs
sc3_kmeans
sc3_calc_consens
sc3_calc_biology
Let us go through each of them independently.
sc3_prepare
We start with sc3_prepare
. This method prepares an object of sce
class for SC3
clustering. This method also defines all parameters needed for clustering and stores them in the sc3
slot. The parameters have their own defaults but can be manually changed. For more information on the parameters please use ?sc3_prepare
.
sce <- sc3_prepare(sce)
## Setting SC3 parameters...
str(metadata(sce)$sc3)
## List of 5
## $ kmeans_iter_max: num 1e+09
## $ kmeans_nstart : num 1000
## $ n_dim : int [1:5] 3 4 5 6 7
## $ rand_seed : num 1
## $ n_cores : num 19
By default
SC3
will use all but one cores of your machine. You can manually set the number of cores to be used by setting then_cores
parameter in thesc3_prepare
call.
sc3_estimate_k
When the sce
object is prepared for clustering, SC3
can also estimate the optimal number of clusters k
in the dataset. SC3
utilizes the Tracy-Widom theory on random matrices to estimate k
. sc3_estimate_k
method creates and populates the following items of the sc3
slot:
k_estimation
- contains the estimated value of k
.sce <- sc3_estimate_k(sce)
## Estimating k...
str(metadata(sce)$sc3)
## List of 6
## $ kmeans_iter_max: num 1e+09
## $ kmeans_nstart : num 1000
## $ n_dim : int [1:5] 3 4 5 6 7
## $ rand_seed : num 1
## $ n_cores : num 19
## $ k_estimation : num 6
sc3_calc_dists
Now we are ready to perform the clustering itself. First SC3
calculates distances between the cells. Method sc3_calc_dists
calculates the distances, creates and populates the following items of the sc3
slot:
distances
- contains a list of distance matrices corresponding to Euclidean, Pearson and Spearman distances.sce <- sc3_calc_dists(sce)
## Calculating distances between the cells...
names(metadata(sce)$sc3$distances)
## [1] "euclidean" "pearson" "spearman"
sc3_calc_transfs
Next the distance matrices are transformed using PCA and graph Laplacian. Method sc3_calc_transfs
calculates transforamtions of the distance matrices contained in
the distances
item of the sc3
slot. It then creates and populates the following items of the sc3
slot:
transformations
- contains a list of transformations of the distance matrices corresponding to PCA and graph Laplacian transformations.sce <- sc3_calc_transfs(sce)
## Performing transformations and calculating eigenvectors...
names(metadata(sce)$sc3$transformations)
## [1] "euclidean_pca" "pearson_pca" "spearman_pca"
## [4] "euclidean_laplacian" "pearson_laplacian" "spearman_laplacian"
It also removes the previously calculated distances
item from the sc3
slot:
metadata(sce)$sc3$distances
## NULL
sc3_kmeans
kmeans should then be performed on the transformed distance matrices contained in the transformations
item of the sc3
slot. Method sc3_kmeans
creates and populates the following items of the sc3
slot:
kmeans
- contains a list of kmeans clusterings.By default the nstart
parameter passed to kmeans
defined in sc3_prepare
method, is set 1000 and written to kmeans_nstart
item of the sc3
slot. If the number of cells in the dataset is more than 2,000, this parameter is set to 50. A user can also manually define this parameter by changing the value of the kmeans_nstart
item of the sc3
slot.
sce <- sc3_kmeans(sce, ks = 2:4)
## Performing k-means clustering...
names(metadata(sce)$sc3$kmeans)
## [1] "euclidean_pca_2_3" "pearson_pca_2_3"
## [3] "spearman_pca_2_3" "euclidean_laplacian_2_3"
## [5] "pearson_laplacian_2_3" "spearman_laplacian_2_3"
## [7] "euclidean_pca_3_3" "pearson_pca_3_3"
## [9] "spearman_pca_3_3" "euclidean_laplacian_3_3"
## [11] "pearson_laplacian_3_3" "spearman_laplacian_3_3"
## [13] "euclidean_pca_4_3" "pearson_pca_4_3"
## [15] "spearman_pca_4_3" "euclidean_laplacian_4_3"
## [17] "pearson_laplacian_4_3" "spearman_laplacian_4_3"
## [19] "euclidean_pca_2_4" "pearson_pca_2_4"
## [21] "spearman_pca_2_4" "euclidean_laplacian_2_4"
## [23] "pearson_laplacian_2_4" "spearman_laplacian_2_4"
## [25] "euclidean_pca_3_4" "pearson_pca_3_4"
## [27] "spearman_pca_3_4" "euclidean_laplacian_3_4"
## [29] "pearson_laplacian_3_4" "spearman_laplacian_3_4"
## [31] "euclidean_pca_4_4" "pearson_pca_4_4"
## [33] "spearman_pca_4_4" "euclidean_laplacian_4_4"
## [35] "pearson_laplacian_4_4" "spearman_laplacian_4_4"
## [37] "euclidean_pca_2_5" "pearson_pca_2_5"
## [39] "spearman_pca_2_5" "euclidean_laplacian_2_5"
## [41] "pearson_laplacian_2_5" "spearman_laplacian_2_5"
## [43] "euclidean_pca_3_5" "pearson_pca_3_5"
## [45] "spearman_pca_3_5" "euclidean_laplacian_3_5"
## [47] "pearson_laplacian_3_5" "spearman_laplacian_3_5"
## [49] "euclidean_pca_4_5" "pearson_pca_4_5"
## [51] "spearman_pca_4_5" "euclidean_laplacian_4_5"
## [53] "pearson_laplacian_4_5" "spearman_laplacian_4_5"
## [55] "euclidean_pca_2_6" "pearson_pca_2_6"
## [57] "spearman_pca_2_6" "euclidean_laplacian_2_6"
## [59] "pearson_laplacian_2_6" "spearman_laplacian_2_6"
## [61] "euclidean_pca_3_6" "pearson_pca_3_6"
## [63] "spearman_pca_3_6" "euclidean_laplacian_3_6"
## [65] "pearson_laplacian_3_6" "spearman_laplacian_3_6"
## [67] "euclidean_pca_4_6" "pearson_pca_4_6"
## [69] "spearman_pca_4_6" "euclidean_laplacian_4_6"
## [71] "pearson_laplacian_4_6" "spearman_laplacian_4_6"
## [73] "euclidean_pca_2_7" "pearson_pca_2_7"
## [75] "spearman_pca_2_7" "euclidean_laplacian_2_7"
## [77] "pearson_laplacian_2_7" "spearman_laplacian_2_7"
## [79] "euclidean_pca_3_7" "pearson_pca_3_7"
## [81] "spearman_pca_3_7" "euclidean_laplacian_3_7"
## [83] "pearson_laplacian_3_7" "spearman_laplacian_3_7"
## [85] "euclidean_pca_4_7" "pearson_pca_4_7"
## [87] "spearman_pca_4_7" "euclidean_laplacian_4_7"
## [89] "pearson_laplacian_4_7" "spearman_laplacian_4_7"
sc3_calc_consens
In this step SC3
will provide you with a clustering solution. Let’s first check that there are no SC3
related columns in the colData
slot:
col_data <- colData(sce)
head(col_data[ , grep("sc3_", colnames(col_data))])
## DataFrame with 6 rows and 0 columns
When calculating consensus for each value of k
SC3
averages the clustering results of kmeans
using a consensus approach. Method sc3_calc_consens
calculates consensus matrices based on the clustering solutions contained in the kmeans
item of the sc3
slot. It then creates and populates the following items of the sc3
slot:
consensus
- for each value of k
it contains: a consensus matrix, an hclust
object, corresponding to hierarchical clustering of the consensus matrix and the Silhouette indeces of the clusters.sce <- sc3_calc_consens(sce)
## Calculating consensus matrix...
names(metadata(sce)$sc3$consensus)
## [1] "2" "3" "4"
names(metadata(sce)$sc3$consensus$`3`)
## [1] "consensus" "hc" "silhouette"
It also removes the previously calculated kmeans
item from the sc3
slot:
metadata(sce)$sc3$kmeans
## NULL
As mentioned before all the clustering results (cell-related information) are written to the colData
slot of the sce
object:
col_data <- colData(sce)
head(col_data[ , grep("sc3_", colnames(col_data))])
## DataFrame with 6 rows and 3 columns
## sc3_2_clusters sc3_3_clusters sc3_4_clusters
## <factor> <factor> <factor>
## Oocyte..1.RPKM. 2 2 2
## Oocyte..2.RPKM. 2 2 2
## Oocyte..3.RPKM. 2 2 2
## Zygote..1.RPKM. 2 2 2
## Zygote..2.RPKM. 2 2 2
## Zygote..3.RPKM. 2 2 2
We can see that SC3
calculated clusters for k = 2, 3
and 4
and wrote them to the colData
slot of the sce
object.
sc3_calc_biology
SC3
can also calculates DE genes, marker genes and cell outliers based on the calculated consensus clusterings. Similary to the clustering solutions, method sc3_calc_biology
writes the results for the cell outliers (cell-related information) to the colData
slot of the sce
object. In contrast, DE and marker genes results (gene-related information) is are written to the rowData
slot. In addition biology
item of the sc3
slot is set to TRUE
.
sce <- sc3_calc_biology(sce, ks = 2:4)
## Calculating biology...
Now we can see that cell outlier scores have been calculated for each value of k
:
col_data <- colData(sce)
head(col_data[ , grep("sc3_", colnames(col_data))])
## DataFrame with 6 rows and 6 columns
## sc3_2_clusters sc3_3_clusters sc3_4_clusters
## <factor> <factor> <factor>
## Oocyte..1.RPKM. 2 2 2
## Oocyte..2.RPKM. 2 2 2
## Oocyte..3.RPKM. 2 2 2
## Zygote..1.RPKM. 2 2 2
## Zygote..2.RPKM. 2 2 2
## Zygote..3.RPKM. 2 2 2
## sc3_2_log2_outlier_score sc3_3_log2_outlier_score
## <numeric> <numeric>
## Oocyte..1.RPKM. 0 1.67032836742399
## Oocyte..2.RPKM. 0 1.69878936817046
## Oocyte..3.RPKM. 0 1.16603348178035
## Zygote..1.RPKM. 0 0
## Zygote..2.RPKM. 0 0
## Zygote..3.RPKM. 0 0
## sc3_4_log2_outlier_score
## <numeric>
## Oocyte..1.RPKM. 1.67032836742415
## Oocyte..2.RPKM. 1.69878936817061
## Oocyte..3.RPKM. 1.16603348178053
## Zygote..1.RPKM. 0
## Zygote..2.RPKM. 0
## Zygote..3.RPKM. 0
For more information on how the cell outliers are calculated please see ?get_outl_cells
.
We can also see that DE and marker genes characteristics (adjusted p-values and area under the ROC curve) have been calculated for each value of k
row_data <- rowData(sce)
head(row_data[ , grep("sc3_", colnames(row_data))])
## DataFrame with 6 rows and 13 columns
## sc3_gene_filter sc3_2_markers_clusts sc3_2_markers_padj
## <logical> <numeric> <numeric>
## C9orf152 FALSE NA NA
## RPS11 FALSE NA NA
## ELMO2 TRUE 2 3.42891755294448e-06
## CREB3L1 TRUE 2 1
## PNMA1 FALSE NA NA
## MMP2 TRUE 1 1
## sc3_2_markers_auroc sc3_3_markers_clusts sc3_3_markers_padj
## <numeric> <numeric> <numeric>
## C9orf152 NA NA NA
## RPS11 NA NA NA
## ELMO2 0.905833333333333 2 8.74957155809462e-08
## CREB3L1 0.635833333333333 2 0.000364998858198823
## PNMA1 NA NA NA
## MMP2 0.549722222222222 1 1
## sc3_3_markers_auroc sc3_4_markers_clusts sc3_4_markers_padj
## <numeric> <numeric> <numeric>
## C9orf152 NA NA NA
## RPS11 NA NA NA
## ELMO2 0.96969696969697 2 8.97459044385902e-08
## CREB3L1 0.827020202020202 2 0.00038529310418705
## PNMA1 NA NA NA
## MMP2 0.549722222222222 3 1
## sc3_4_markers_auroc sc3_2_de_padj sc3_3_de_padj
## <numeric> <numeric> <numeric>
## C9orf152 NA NA NA
## RPS11 NA NA NA
## ELMO2 0.96969696969697 3.33654105464895e-06 7.88333987242478e-10
## CREB3L1 0.827020202020202 1 0.00203864534241844
## PNMA1 NA NA NA
## MMP2 0.543928571428571 1 1
## sc3_4_de_padj
## <numeric>
## C9orf152 NA
## RPS11 NA
## ELMO2 1.86540162226264e-09
## CREB3L1 0.00616104934849165
## PNMA1 NA
## MMP2 1
For more information on how the DE and marker genes are calculated please see ?get_de_genes
and ?get_marker_genes
.
SVM
ApproachFor datasets with more than 5,000 cells SC3
automatically utilizes a hybrid approach that combines unsupervised and supervised clusterings. Namely, SC3
selects a subset of cells uniformly at random (5,000), and obtains clusters from this subset. The inferred labels can be used to train a Support Vector Machine (SVM
), which is employed to assign labels to the remaining cells.
The hybrid approach can also be triggered by defining either the svm_num_cells
parameter (the number of training cells, which is different from 5,000) or svm_train_inds
parameter (training cells are manually selected by providing their indexes).
Let us first save the SC3
results for k = 3
obtained without using the hybrid approach:
no_svm_labels <- colData(sce)$sc3_3_clusters
Now let us trigger the hybrid approach by asking for 50 training cells:
sce <- sc3(sce, ks = 2:4, biology = TRUE, svm_num_cells = 50)
## Setting SC3 parameters...
## Defining training cells for SVM using svm_num_cells parameter...
## Calculating distances between the cells...
## Performing transformations and calculating eigenvectors...
## Performing k-means clustering...
## Calculating consensus matrix...
## Calculating biology...
Note that when SVM
is used all results (including marker genes, DE genes and cell outliers) correspond to the training cells only (50 cells), and values of all other cells are set to NA
:
col_data <- colData(sce)
head(col_data[ , grep("sc3_", colnames(col_data))])
## DataFrame with 6 rows and 6 columns
## sc3_2_clusters sc3_3_clusters sc3_4_clusters
## <factor> <factor> <factor>
## Oocyte..1.RPKM. 2 3 2
## Oocyte..2.RPKM. NA NA NA
## Oocyte..3.RPKM. 2 3 2
## Zygote..1.RPKM. NA NA NA
## Zygote..2.RPKM. NA NA NA
## Zygote..3.RPKM. NA NA NA
## sc3_2_log2_outlier_score sc3_3_log2_outlier_score
## <numeric> <numeric>
## Oocyte..1.RPKM. 4.17617511760319 0
## Oocyte..2.RPKM. NA NA
## Oocyte..3.RPKM. 4.21008138262028 0
## Zygote..1.RPKM. NA NA
## Zygote..2.RPKM. NA NA
## Zygote..3.RPKM. NA NA
## sc3_4_log2_outlier_score
## <numeric>
## Oocyte..1.RPKM. 2.66829116556097
## Oocyte..2.RPKM. NA
## Oocyte..3.RPKM. 2.72237674306917
## Zygote..1.RPKM. NA
## Zygote..2.RPKM. NA
## Zygote..3.RPKM. NA
Now we can run the SVM
and predict labels of all the other cells:
sce <- sc3_run_svm(sce, ks = 2:4)
col_data <- colData(sce)
head(col_data[ , grep("sc3_", colnames(col_data))])
## DataFrame with 6 rows and 6 columns
## sc3_2_clusters sc3_3_clusters sc3_4_clusters
## <integer> <integer> <integer>
## Oocyte..1.RPKM. 2 3 2
## Oocyte..2.RPKM. 2 3 2
## Oocyte..3.RPKM. 2 3 2
## Zygote..1.RPKM. 2 3 2
## Zygote..2.RPKM. 2 3 2
## Zygote..3.RPKM. 2 3 2
## sc3_2_log2_outlier_score sc3_3_log2_outlier_score
## <numeric> <numeric>
## Oocyte..1.RPKM. 4.17617511760319 0
## Oocyte..2.RPKM. NA NA
## Oocyte..3.RPKM. 4.21008138262028 0
## Zygote..1.RPKM. NA NA
## Zygote..2.RPKM. NA NA
## Zygote..3.RPKM. NA NA
## sc3_4_log2_outlier_score
## <numeric>
## Oocyte..1.RPKM. 2.66829116556097
## Oocyte..2.RPKM. NA
## Oocyte..3.RPKM. 2.72237674306917
## Zygote..1.RPKM. NA
## Zygote..2.RPKM. NA
## Zygote..3.RPKM. NA
Note that the cell outlier scores (and also DE and marker genes values) were not updated and they still contain NA
values for non-training cells. To recalculate biological characteristics using the labels predicted by SVM
one need to clear the svm_train_inds
item in the sc3
slot and rerun the sc3_calc_biology
method:
metadata(sce)$sc3$svm_train_inds <- NULL
sce <- sc3_calc_biology(sce, ks = 2:4)
## Calculating biology...
col_data <- colData(sce)
head(col_data[ , grep("sc3_", colnames(col_data))])
## DataFrame with 6 rows and 6 columns
## sc3_2_clusters sc3_3_clusters sc3_4_clusters
## <integer> <integer> <integer>
## Oocyte..1.RPKM. 2 3 2
## Oocyte..2.RPKM. 2 3 2
## Oocyte..3.RPKM. 2 3 2
## Zygote..1.RPKM. 2 3 2
## Zygote..2.RPKM. 2 3 2
## Zygote..3.RPKM. 2 3 2
## sc3_2_log2_outlier_score sc3_3_log2_outlier_score
## <numeric> <numeric>
## Oocyte..1.RPKM. 0 2.64862049547445
## Oocyte..2.RPKM. 0 2.86774574215453
## Oocyte..3.RPKM. 0 2.44304697437403
## Zygote..1.RPKM. 0 0
## Zygote..2.RPKM. 0 0
## Zygote..3.RPKM. 0 0
## sc3_4_log2_outlier_score
## <numeric>
## Oocyte..1.RPKM. 1.67032836742406
## Oocyte..2.RPKM. 1.69878936817052
## Oocyte..3.RPKM. 1.16603348178042
## Zygote..1.RPKM. 0
## Zygote..2.RPKM. 0
## Zygote..3.RPKM. 0
Now the biological characteristics are calculated for all cells (including those predicted by the SVM
)
svm_labels <- colData(sce)$sc3_3_clusters
Now we can compare the labels using the adjusted rand index (ARI
):
if (require("mclust")) {
adjustedRandIndex(no_svm_labels, svm_labels)
}
## Loading required package: mclust
## Package 'mclust' version 5.4.3
## Type 'citation("mclust")' for citing this R package in publications.
## [1] 0.8736898
ARI
is less than 1
, which means that SVM
results are different from the non-SVM
results, however ARI
is still pretty close to 1
meaning that the solutions are very similar.