## ----install, eval = FALSE---------------------------------------------------- # if (!requireNamespace("BiocManager", quietly = TRUE)) # install.packages("BiocManager") # # BiocManager::install("RegionalST") ## ----readVisium, eval=FALSE--------------------------------------------------- # sce <- readVisium("path/to/spaceranger/outs/") ## ----manual.sce, eval=FALSE--------------------------------------------------- # library(Matrix) # # rowData <- read.csv("path/to/rowData.csv", stringsAsFactors=FALSE) # colData <- read.csv("path/to/colData.csv", stringsAsFactors=FALSE, row.names=1) # counts <- read.csv("path/to/counts.csv.gz", # row.names=1, check.names=F, stringsAsFactors=FALSE)) # # sce <- SingleCellExperiment(assays=list(counts=as(counts, "dgCMatrix")), # rowData=rowData, # colData=colData) ## ----CARDexample, eval=FALSE-------------------------------------------------- # ### read in spatial transcriptomics data for analysis # library(BayesSpace) # outdir = "/Dir/To/Data/BreastCancer_10x" # sce <- readVisium(outdir) # sce <- spatialPreprocess(sce, platform="Visium", log.normalize=TRUE) # spatial_count <- assays(sce)$counts # spatial_location <- data.frame(x = sce$imagecol, # y = max(sce$imagerow) - sce$imagerow) # rownames(spatial_location) <- colnames(spatial_count) # # ### assuming the single cell reference data for BRCA has been loaded # ### BRCA_countmat: the count matrix of the BRCA single cell reference # ### cellType: the cell types of the BRCA reference data # sc_count <- BRCA_countmat # sc_meta <- data.frame(cellID = colnames(BRCA_countmat), # cellType = cellType) # rownames(sc_meta) <- colnames(BRCA_countmat) # # library(CARD) # CARD_obj <- createCARDObject( # sc_count = sc_count, # sc_meta = sc_meta, # spatial_count = spatial_count, # spatial_location = spatial_location, # ct.varname = "cellType", # ct.select = unique(sc_meta$cellType), # sample.varname = "sampleInfo", # minCountGene = 100, # minCountSpot = 5) # CARD_obj <- CARD_deconvolution(CARD_object = CARD_obj) # # ## add proportion to the sce object # S4Vectors::metadata(sce)$Proportions <- RegionalST::getProportions(CARD_obj) ## ----loadExample, eval=TRUE--------------------------------------------------- set.seed(1234) library(RegionalST) library("gridExtra") data(example_sce) ## the proportion information is saved under the metadata S4Vectors::metadata(example_sce)$Proportions[seq_len(5),seq_len(5)] ## the cell type information is saved under a cell type variable head(example_sce$celltype) ## ----pre1, eval=TRUE, message = FALSE----------------------------------------- library(BayesSpace) example_sce <- example_sce[, colSums(counts(example_sce)) > 0] example_sce <- mySpatialPreprocess(example_sce, platform="Visium") ## ----addweight, eval=TRUE, message=FALSE, progress=FALSE, results='hide'------ weight <- data.frame(celltype = c("Cancer Epithelial", "CAFs", "T-cells", "Endothelial", "PVL", "Myeloid", "B-cells", "Normal Epithelial", "Plasmablasts"), weight = c(0.25,0.05, 0.25,0.05, 0.025,0.05, 0.25,0.05,0.025)) OneRad <- GetOneRadiusEntropy_withProp(example_sce, selectN = length(example_sce$spot), weight = weight, radius = 5, doPlot = TRUE, mytitle = "Radius 5 weighted entropy") ## ----selectROI1, eval=TRUE, message=FALSE, progress=FALSE, results='hide'----- example_sce <- RankCenterByEntropy_withProp(example_sce, weight, selectN = round(length(example_sce$spot)/5), topN = 3, min_radius = 10, radius_vec = c(5,10), doPlot = TRUE) ### visualize one selected ROI: PlotOneSelectedCenter(example_sce,ploti = 1) ## ----vis1, eval=TRUE, message=FALSE, progress=FALSE, fig.show='hide'---------- ## let's visualize the selected regions: palette <- colorspace::qualitative_hcl(9, palette = "Set2") selplot <- list() topN <- 3 for(i in seq_len(topN)) { selplot[[i]] <- print(PlotOneSelectedCenter(example_sce,ploti = i)) } selplot[[topN+1]] <- print(clusterPlot(example_sce, palette=palette, label = "celltype", size=0.1) ) ## ----vis2, eval = TRUE-------------------------------------------------------- do.call("grid.arrange", c(selplot, ncol = 2)) ## ----saveres, eval=FALSE------------------------------------------------------ # thisSelection <- S4Vectors::metadata(sce)$selectCenters # save(thisSelection, file = "/Your/Directory/SelectionResults_withProportions.RData") ## ----shiny1, eval=FALSE------------------------------------------------------- # example_sce <- ManualSelectCenter(example_sce) # S4Vectors::metadata(example_sce)$selectCenters ## ----draw1, eval=TRUE--------------------------------------------------------- DrawRegionProportion_withProp(example_sce, label = "CellType", selCenter = c(1,2,3)) ## ----DE1, eval=TRUE, message=FALSE, progress=FALSE, warning=FALSE------------- CR12_DE <- GetCrossRegionalDE_withProp(example_sce, twoCenter = c(1,2), label = "celltype", angle = 30, hjust = 0, size = 3, padj_filter = 0.05, doHeatmap = TRUE) dim(CR12_DE$allDE) table(CR12_DE$allDE$Comparison) ## we find very few DE genes in the current dataset as the example data is very small and truncated. ## ----DE2, eval=FALSE---------------------------------------------------------- # CR13_DE <- GetCrossRegionalDE_withProp(example_sce, # twoCenter = c(1,3), # label = "celltype", # padj_filter = 0.05, # doHeatmap = TRUE) # CR23_DE <- GetCrossRegionalDE_withProp(example_sce, # twoCenter = c(2,3), # label = "celltype", # padj_filter = 0.05, # doHeatmap = TRUE) # exampleRes <- list(CR12_DE, # CR13_DE, # CR23_DE) ## ----DE3, eval=TRUE----------------------------------------------------------- data("exampleRes") ## check the number of DEs for each cell type-specific comparison table(exampleRes[[1]]$allDE$Comparison) table(exampleRes[[2]]$allDE$Comparison) table(exampleRes[[3]]$allDE$Comparison) ## ----anno, eval=FALSE--------------------------------------------------------- # outdir = "/Users/zli16/Dropbox/TrySTData/Ovarian_10x" # sce <- readVisium(outdir) # sce <- sce[, colSums(counts(sce)) > 0] # sce <- spatialPreprocess(sce, platform="Visium", log.normalize=TRUE) # sce <- qTune(sce, qs=seq(2, 10), platform="Visium", d=15) # sce <- spatialCluster(sce, q=10, platform="Visium", d=15, # init.method="mclust", model="t", gamma=2, # nrep=50000, burn.in=1000, # save.chain=FALSE) # clusterPlot(sce) # # markers <- list() # markers[["Epithelial"]] <- c("EPCAM") # markers[["Tumor"]] <- c("EPCAM","MUC6", "MMP7") # markers[["Macrophages"]] <- c("CD14", "CSF1R") # markers[["Dendritic cells"]] <- c("CCR7") # markers[["Immune cells"]] <- c("CD19", "CD79A", "CD79B", "PTPRC") # # sum_counts <- function(sce, features) { # if (length(features) > 1) { # colSums(logcounts(sce)[features, ]) # } else { # logcounts(sce)[features, ] # } # } # spot_expr <- purrr::map(markers, function(xs) sum_counts(sce, xs)) # # library(ggplot2) # plot_expression <- function(sce, expr, name, mylimits) { # # fix.sc <- scale_color_gradientn(colours = c('lightgrey', 'blue'), limits = c(0, 6)) # featurePlot(sce, expr, color=NA) + # viridis::scale_fill_viridis(option="A") + # labs(title=name, fill="Log-normalized\nexpression") # } # spot_plots <- purrr::imap(spot_expr, function(x, y) plot_expression(sce, x, y)) # patchwork::wrap_plots(spot_plots, ncol=3) # # #### assign celltype based on marker distribution # sce$celltype <- sce$spatial.cluster # sce$celltype[sce$spatial.cluster %in% c(1,2,6,8)] <- "Epithelial" # sce$celltype[sce$spatial.cluster %in% c(3)] <- "Macrophages" # sce$celltype[sce$spatial.cluster %in% c(4,5)] <- "Immune" # sce$celltype[sce$spatial.cluster %in% c(9,7,10)] <- "Tumor" # colData(sce)$celltype <- sce$celltype ## ----loadExample2, eval=FALSE------------------------------------------------- # library(RegionalST) # data(example_sce) # # ## the cell type information is saved under a cell type variable # table(example_sce$celltype) ## ----weight2, eval=TRUE, message=FALSE, warning=FALSE, results=FALSE---------- weight <- data.frame(celltype = c("Cancer Epithelial", "CAFs", "T-cells", "Endothelial", "PVL", "Myeloid", "B-cells", "Normal Epithelial", "Plasmablasts"), weight = c(0.25,0.05, 0.25,0.05, 0.025,0.05, 0.25,0.05,0.025)) OneRad <- GetOneRadiusEntropy(example_sce, selectN = length(example_sce$spot), weight = weight, label = "celltype", radius = 5, doPlot = TRUE, mytitle = "Radius 5 weighted entropy") ## ----select2, eval=TRUE, message=FALSE, warning=FALSE, fig.show='hide', results=FALSE---- example_sce <- RankCenterByEntropy(example_sce, weight, selectN = round(length(example_sce$spot)/2), label = "celltype", topN = 3, min_radius = 10, radius_vec = c(5,10), doPlot = TRUE) ## ----vis12, eval=TRUE, message=FALSE, progress=FALSE, fig.show='hide'--------- ## let's visualize the selected regions: palette <- colorspace::qualitative_hcl(9, palette = "Set2") selplot <- list() topN = 3 for(i in seq_len(topN)) { selplot[[i]] <- print(PlotOneSelectedCenter(example_sce,ploti = i)) } selplot[[topN+1]] <- print(clusterPlot(example_sce, palette=palette, label = "celltype", size=0.1) ) ## ----vis22, eval = TRUE------------------------------------------------------- do.call("grid.arrange", c(selplot, ncol = 2)) ## ----saveres2, eval=FALSE----------------------------------------------------- # thisSelection <- S4Vectors::metadata(example_sce)$selectCenters # save(thisSelection, file = "/Your/Directory/SelectionResults_withProportions.RData") ## ----DE122, eval=FALSE-------------------------------------------------------- # ## I didn't run this in the vignette as the current dataset has been truncated and couldn't find any DE genes # CR12_DE <- GetCrossRegionalDE_raw(example_sce, # twoCenter = c(1,2), # label = "celltype", # logfc.threshold = 0.1, # min.pct = 0.1, # angle = 30, # hjust = 0, # size = 3, # padj_filter = 0.05, # doHeatmap = FALSE) ## ----DE123, eval=FALSE-------------------------------------------------------- # CR13_DE <- GetCrossRegionalDE_raw(example_sce, # twoCenter = c(1,3), # label = "celltype", # padj_filter = 0.05, # doHeatmap = FALSE) # CR23_DE <- GetCrossRegionalDE_raw(example_sce, # twoCenter = c(2,3), # label = "celltype", # padj_filter = 0.05, # doHeatmap = FALSE) ## ----gsea1, eval=TRUE, message=FALSE, warning=FALSE, fig.show='hide', results=FALSE---- allfigure <- list() allCTres <- DoGSEA(exampleRes, whichDB = "hallmark", withProp = TRUE) for(i in seq_len(3)) { allfigure[[i]] <- DrawDotplot(allCTres, CT = i, angle = 15, vjust = 1, chooseP = "padj") } ## ----gsea2, eval=TRUE, fig.width=20, message=FALSE, warning=FALSE,fig.height=8, results=FALSE---- do.call("grid.arrange", c(allfigure[c(1,2,3)], ncol = 3)) ## ----gsea22, eval=TRUE, message=FALSE, warning=FALSE, results=FALSE----------- ### draw each cell type individually, here I am drawing cell type = 3 DrawDotplot(allCTres, CT = 3, angle = 15, vjust = 1, chooseP = "padj") ## ----gsea3, eval=TRUE, warning=FALSE, message=FALSE--------------------------- allCTres <- DoGSEA(exampleRes, whichDB = "kegg", withProp = TRUE) DrawDotplot(allCTres, CT = 3, angle = 15, vjust = 1, chooseP = "padj") ## ----gsea4, eval=TRUE, warning=FALSE, message=FALSE, fig.width=15, fig.height=8---- allCTres <- DoGSEA(exampleRes, whichDB = "reactome", withProp = TRUE) DrawDotplot(allCTres, CT = 3, angle = 15, vjust = 1, chooseP = "padj") ## ----sessionInfo, echo=FALSE-------------------------------------------------- sessionInfo()