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The methods below are described in our article
Larsson I & Held F, et al. (2023) Reconstructing the regulatory programs underlying the phenotypic plasticity of neural cancers. Preprint available at bioRxiv; 2023.03.10.532041.
Here we demonstrate the scregclust workflow using the PBMC data from 10X Genomics (available here). This is the same data used in an introductory vignette for the Seurat package. We use Seurat for pre-processing of the data.
We are focusing here on the filtered feature barcode matrix available as an HDF5 file from the website linked above. The data can be downloaded manually or using R.
However you obtain the data, the code below assumes that the HDF5
file containing it is placed in the same folder as this script with the
name
pbmc_granulocyte_sorted_3k_filtered_feature_bc_matrix.h5
.
url <- paste0(
"https://cf.10xgenomics.com/samples/cell-arc/2.0.0/",
"pbmc_granulocyte_sorted_3k/",
"pbmc_granulocyte_sorted_3k_filtered_feature_bc_matrix.h5"
)
data_path <- file.path(
tempdir(), "pbmc_granulocyte_sorted_3k_filtered_feature_bc_matrix.h5"
)
download.file(url, data_path, cacheOK = FALSE, mode = "wb")
To perform preprocessing use Seurat to load the data. The file ships with two modalities, “Gene Expression” and “Peaks”. We only use the former.
pbmc_data <- Read10X_h5(
data_path,
use.names = TRUE,
unique.features = TRUE
)[["Gene Expression"]]
#> Genome matrix has multiple modalities, returning a list of matrices for this genome
We create a Seurat object and follow the Seurat vignette to subset the cells and features (genes).
pbmc <- CreateSeuratObject(
counts = pbmc_data, min.cells = 3, min.features = 200
)
pbmc[["percent.mt"]] <- PercentageFeatureSet(pbmc, pattern = "^MT.")
pbmc <- subset(pbmc, subset = percent.mt < 30 & nFeature_RNA < 6000)
SCTransform
is used for variance stabilization of the data and Pearson residuals for
the 6000 most variable genes are extracted as matrix z
.
pbmc <- SCTransform(pbmc, variable.features.n = 6000)
#> Running SCTransform on assay: RNA
#> Running SCTransform on layer: counts
#> vst.flavor='v2' set. Using model with fixed slope and excluding poisson genes.
#> Variance stabilizing transformation of count matrix of size 19168 by 2686
#> Model formula is y ~ log_umi
#> Get Negative Binomial regression parameters per gene
#> Using 2000 genes, 2686 cells
#> Found 6 outliers - those will be ignored in fitting/regularization step
#> Second step: Get residuals using fitted parameters for 19168 genes
#> Computing corrected count matrix for 19168 genes
#> Calculating gene attributes
#> Wall clock passed: Time difference of 11.65273 secs
#> Determine variable features
#> Centering data matrix
#> Set default assay to SCT
z <- GetAssayData(pbmc, layer = "scale.data")
dim(z)
#> [1] 6000 2686
We then use scregclust_format
which extracts gene
symbols from the expression matrix and determines which genes are
considered regulators. By default, transcription factors are used as
regulators. Setting mode
to "kinase"
uses
kinases instead of transcription factors. A list of the regulators used
internally is returned by get_regulator_list()
.
The output of scregclust_format
is a list with three
elements.
genesymbols
contains the rownames of
z
sample_assignment
is initialized to be a vector of
1
s of length ncol(z)
and can be filled with a
known sample grouping. Here, we do not use it and just keep it uniform
across all cells.is_regulator
is an indicator vector (elements are 0 or
1) corresponding to the entries of genesymbols
with 1
marking that the genesymbol is selected as a regulator according to the
model of scregclust_format
("TF"
or
"kinase"
) and 0 otherwise.genesymbols <- out$genesymbols
sample_assignment <- out$sample_assignment
is_regulator <- out$is_regulator
Run scregclust
with number of initial modules set to 10
and test several penalties. The penalties provided to
penalization
are used during selection of regulators
associated with each module. An increasing penalty implies the selection
of fewer regulators. noise_threshold
controls the minimum
\(R^2\) a gene has to achieve across
modules. Otherwise the gene is marked as noise. The run can be
reproduced with the command below. A pre-fitted model can be downloaded
from GitHub
for convenience.
# set.seed(8374)
# fit <- scregclust(
# z, genesymbols, is_regulator, penalization = seq(0.1, 0.5, 0.05),
# n_modules = 10L, n_cycles = 50L, noise_threshold = 0.05
# )
# saveRDS(fit, file = "pbmc_scregclust.rds")
url <- paste0(
"https://github.com/scmethods/scregclust/raw/main/datasets/",
"pbmc_scregclust.rds"
)
fit_path <- file.path(tempdir(), "pbmc_scregclust.rds")
download.file(url, fit_path)
fit <- readRDS(fit_path)
Results can be visualized easily using built-in functions. Metrics
for helping in choosing an optimal penalty can be plotted by calling
plot
on the object returned from
scregclust
.
The results for each penalization parameter are placed in a list,
results
, attached to the fit
object. So
fit$results[[1]]
contains the results of running
scregclust
with penalization = 0.1
. For each
penalization parameter, the algorithm might end up finding multiple
optimal configurations. Each configuration describes target genes module
assignments and which regulators are associated with which modules. The
results for each such configuration are contained in the list
output
. This means that
fit$results[[1]]$output[[1]]
contains the results for the
first final configuration. More than one may be available.
In this example, at most two final configurations were found for each penalization parameters.
To plot the regulator network of the first configuration for
penalization = 0.1
the function
plot_regulator_network
can be used.
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.