Spaniel is an R package designed to visualise results of Spatial Transcriptomics experiments. The current stable version of Spaniel (version 1.1.0) is available from Bioconductor:
BiocManager::install('Spaniel')
This vignette refers to a development version of Spaniel (version 1.2) designed to import data from a 10X Genomics Visium experiment.
This version will be tested and pushed to Bioconductor. In the meantime, if you would like to test the features described in this vignette you can install a development Spaniel (version 1.2) using the following command:
devtools::install_github("RachelQueen1/Spaniel", ref = "Development" )
library(Spaniel)
library(DropletUtils)
library(scater)
This vignette will show how to load the results of 10X Visium spatial transcriptomics experiment which has been run through the Space Ranger pipeline. The data is distributed as part of the Space Ranger software package which can be downloaded here:
https://support.10xgenomics.com/spatial-gene-expression/software/overview/welcome
The output from from the "spaceranger testrun" is used as an example here.
Spaniel can be load the output directly from SpaceRanger output using the createVisiumSCE function. This which imports the gene expression data, spatial barcodes, and image dimensions into the SingleCellExperiment object.
pathToTenXOuts <- file.path(system.file(package = "Spaniel"), "extData/outs")
sce <- createVisiumSCE(tenXDir=pathToTenXOuts,
resolution="Low")
The pixel coordinates are added to the colData of the SCE object shown below:
colData(sce)[, c("Barcode", "pixel_x", "pixel_y")]
The image dimensions are added to the metadata of the SCE object:
metadata(sce)$ImgDims
The image is stored as a rasterised grob.
metadata(sce)$Grob
Assessing the number of genes and number of counts per spot is a useful quality control step. Spaniel allows QC metrics to be viewed on top of the histological image so that any quality issues can be pinpointed. Spots within the tissue region which have a low number of genes or counts may be due to experimental problems which should be addressed. Conversely spots which lie outside of the tissue and have a high number of counts or large number of genes may indicate that there is background contamination.
The plotting function allows the use of a binary filter to visualise which spots pass filtering thresholds. We create a filter to show spots at 1 gene is detected. Spots where no genes are detected will be removed from the remainder of the analysis.
NOTE: The parameters are set for subset of counts used in this dataset.
The filter thresholds will be experiment specific and should be adjusted as
necessary.
filter <- sce$detected > 0
spanielPlot(object = sce,
plotType = "NoGenes",
showFilter = filter,
techType = "Visium",
ptSizeMax = 3)
Spots where no genes are detected can be removed from the remainder of the analysis.
sce <- sce[, filter]
The filtered data can then be normalised using the the "normalize" function from scater and the expression of selected genes can be viewed on the histological image.
sce <- logNormCounts(sce)
gene <- "ENSMUSG00000024843"
p2 <- spanielPlot(object = sce,
plotType = "Gene", gene = gene,
showFilter = NULL,
techType = "Visium",
ptSizeMax = 3)
p2