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singleCell_integration.R
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singleCell_integration.R
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# script to integrate scRNA-Seq datasets to correct for batch effects
# setwd("~/Desktop/demo/single_cell_integrate")
# load libraries
library(Seurat)
library(ggplot2)
library(tidyverse)
library(gridExtra)
# get data location
dirs <- list.dirs(path = 'data/', recursive = F, full.names = F)
for(x in dirs){
name <- gsub('_filtered_feature_bc_matrix','', x)
cts <- ReadMtx(mtx = paste0('data/',x,'/matrix.mtx.gz'),
features = paste0('data/',x,'/features.tsv.gz'),
cells = paste0('data/',x,'/barcodes.tsv.gz'))
# create seurat objects
assign(name, CreateSeuratObject(counts = cts))
}
# merge datasets
merged_seurat <- merge(HB17_background, y = c(HB17_PDX, HB17_tumor, HB30_PDX, HB30_tumor, HB53_background,
HB53_tumor),
add.cell.ids = ls()[3:9],
project = 'HB')
merged_seurat
# QC & filtering -----------------------
View(merged_seurat@meta.data)
# create a sample column
merged_seurat$sample <- rownames(merged_seurat@meta.data)
# split sample column
merged_seurat@meta.data <- separate(merged_seurat@meta.data, col = 'sample', into = c('Patient', 'Type', 'Barcode'),
sep = '_')
# calculate mitochondrial percentage
merged_seurat$mitoPercent <- PercentageFeatureSet(merged_seurat, pattern='^MT-')
# explore QC
# filtering
merged_seurat_filtered <- subset(merged_seurat, subset = nCount_RNA > 800 &
nFeature_RNA > 500 &
mitoPercent < 10)
merged_seurat_filtered
merged_seurat
# perform standard workflow steps to figure out if we see any batch effects --------
merged_seurat_filtered <- NormalizeData(object = merged_seurat_filtered)
merged_seurat_filtered <- FindVariableFeatures(object = merged_seurat_filtered)
merged_seurat_filtered <- ScaleData(object = merged_seurat_filtered)
merged_seurat_filtered <- RunPCA(object = merged_seurat_filtered)
ElbowPlot(merged_seurat_filtered)
merged_seurat_filtered <- FindNeighbors(object = merged_seurat_filtered, dims = 1:20)
merged_seurat_filtered <- FindClusters(object = merged_seurat_filtered)
merged_seurat_filtered <- RunUMAP(object = merged_seurat_filtered, dims = 1:20)
# plot
p1 <- DimPlot(merged_seurat_filtered, reduction = 'umap', group.by = 'Patient')
p2 <- DimPlot(merged_seurat_filtered, reduction = 'umap', group.by = 'Type',
cols = c('red','green','blue'))
grid.arrange(p1, p2, ncol = 2, nrow = 2)
# perform integration to correct for batch effects ------
obj.list <- SplitObject(merged_seurat_filtered, split.by = 'Patient')
for(i in 1:length(obj.list)){
obj.list[[i]] <- NormalizeData(object = obj.list[[i]])
obj.list[[i]] <- FindVariableFeatures(object = obj.list[[i]])
}
# select integration features
features <- SelectIntegrationFeatures(object.list = obj.list)
# find integration anchors (CCA)
anchors <- FindIntegrationAnchors(object.list = obj.list,
anchor.features = features)
# integrate data
seurat.integrated <- IntegrateData(anchorset = anchors)
# Scale data, run PCA and UMAP and visualize integrated data
seurat.integrated <- ScaleData(object = seurat.integrated)
seurat.integrated <- RunPCA(object = seurat.integrated)
seurat.integrated <- RunUMAP(object = seurat.integrated, dims = 1:50)
p3 <- DimPlot(seurat.integrated, reduction = 'umap', group.by = 'Patient')
p4 <- DimPlot(seurat.integrated, reduction = 'umap', group.by = 'Type',
cols = c('red','green','blue'))
grid.arrange(p1, p2, p3, p4, ncol = 2, nrow = 2)