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README.Rmd
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---
output: github_document
---
```{r opts, include = FALSE}
knitr::opts_chunk$set(
cache = FALSE,
collapse = TRUE,
tidy = FALSE,
comment = "#>",
results = "hide",
message = FALSE,
warning = FALSE,
fig.path = "man/figures/",
fig.height = 5,
fig.width = 10,
fig.align = "center",
dpi = 300,
out.width = "100%"
)
```
# SCP: Single-Cell Pipeline
<!-- badges: start -->
[![version](https://img.shields.io/github/r-package/v/zhanghao-njmu/SCP)](https://github.com/zhanghao-njmu/SCP) [![codesize](https://img.shields.io/github/languages/code-size/zhanghao-njmu/SCP.svg)](https://github.com/zhanghao-njmu/SCP) [![license](https://img.shields.io/github/license/zhanghao-njmu/SCP)](https://github.com/zhanghao-njmu/SCP)
<!-- badges: end -->
SCP provides a comprehensive set of tools for single-cell data processing and downstream analysis.
The package includes the following facilities:
- Integrated single-cell quality control methods.
- Pipelines embedded with multiple methods for normalization, feature reduction, and cell population identification (standard Seurat workflow).
- Pipelines embedded with multiple integration methods for scRNA-seq or scATAC-seq data, including Uncorrected, [Seurat](https://github.com/satijalab/seurat), [scVI](https://github.com/scverse/scvi-tools), [MNN](http://www.bioconductor.org/packages/release/bioc/html/batchelor.html), [fastMNN](http://www.bioconductor.org/packages/release/bioc/html/batchelor.html), [Harmony](https://github.com/immunogenomics/harmony), [Scanorama](https://github.com/brianhie/scanorama), [BBKNN](https://github.com/Teichlab/bbknn), [CSS](https://github.com/quadbiolab/simspec), [LIGER](https://github.com/welch-lab/liger), [Conos](https://github.com/kharchenkolab/conos), [ComBat](https://bioconductor.org/packages/release/bioc/html/sva.html).
- Multiple single-cell downstream analyses such as identification of differential features, enrichment analysis, GSEA analysis, identification of dynamic features, [PAGA](https://github.com/theislab/paga), [RNA velocity](https://github.com/theislab/scvelo), [Palantir](https://github.com/dpeerlab/Palantir), [Monocle2](http://cole-trapnell-lab.github.io/monocle-release), [Monocle3](https://cole-trapnell-lab.github.io/monocle3), etc.
- Multiple methods for automatic annotation of single-cell data and methods for projection between single-cell datasets.
- High-quality data visualization methods.
- Fast deployment of single-cell data into SCExplorer, a [shiny app](https://shiny.rstudio.com/) that provides an interactive visualization interface.
The functions in the SCP package are all developed around the [Seurat object](https://github.com/mojaveazure/seurat-object) and are compatible with other Seurat functions.
## R version requirement
- R \>= 4.1.0
## Installation in the global R environment
You can install the latest version of SCP from [GitHub](https://github.com/zhanghao-njmu/SCP) with:
```{r install, eval=FALSE}
if (!require("devtools", quietly = TRUE)) {
install.packages("devtools")
}
devtools::install_github("zhanghao-njmu/SCP")
```
#### Create a python environment for SCP
To run functions such as `RunPAGA` or `RunSCVELO`, SCP requires [conda](https://docs.conda.io/en/latest/miniconda.html) to create a separate python environment. The default environment name is `"SCP_env"`. You can specify the environment name for SCP by setting `options(SCP_env_name="new_name")`
Now, you can run `PrepareEnv()` to create the python environment for SCP. If the conda binary is not found, it will automatically download and install miniconda.
```{r eval=FALSE}
SCP::PrepareEnv()
```
To force SCP to use a specific conda binary, it is recommended to set `reticulate.conda_binary` R option:
```{r eval=FALSE}
options(reticulate.conda_binary = "/path/to/conda")
SCP::PrepareEnv()
```
If the download of miniconda or pip packages is slow, you can specify the miniconda repo and PyPI mirror according to your network region.
```{r eval=FALSE}
SCP::PrepareEnv(
miniconda_repo = "https://mirrors.bfsu.edu.cn/anaconda/miniconda",
pip_options = "-i https://pypi.tuna.tsinghua.edu.cn/simple"
)
```
Available miniconda repositories:
- <https://repo.anaconda.com/miniconda> (default)
- <http://mirrors.aliyun.com/anaconda/miniconda>
- <https://mirrors.bfsu.edu.cn/anaconda/miniconda>
- <https://mirrors.pku.edu.cn/anaconda/miniconda>
- <https://mirror.nju.edu.cn/anaconda/miniconda>
- <https://mirrors.sustech.edu.cn/anaconda/miniconda>
- <https://mirrors.xjtu.edu.cn/anaconda/miniconda>
- <https://mirrors.hit.edu.cn/anaconda/miniconda>
Available PyPI mirrors:
- <https://pypi.python.org/simple> (default)
- <https://mirrors.aliyun.com/pypi/simple>
- <https://pypi.tuna.tsinghua.edu.cn/simple>
- <https://mirrors.pku.edu.cn/pypi/simple>
- <https://mirror.nju.edu.cn/pypi/web/simple>
- <https://mirrors.sustech.edu.cn/pypi/simple>
- <https://mirrors.xjtu.edu.cn/pypi/simple>
- <https://mirrors.hit.edu.cn/pypi/web/simple>
## Installation in an isolated R environment using renv
If you do not want to change your current R environment or require reproducibility, you can use the [renv](https://rstudio.github.io/renv/) package to install SCP into an isolated R environment.
#### Create an isolated R environment
```{r eval=FALSE}
if (!require("renv", quietly = TRUE)) {
install.packages("renv")
}
dir.create("~/SCP_env", recursive = TRUE) # It cannot be the home directory "~" !
renv::init(project = "~/SCP_env", bare = TRUE, restart = TRUE)
```
Option 1: Install SCP from GitHub and create SCP python environment
```{r eval=FALSE}
renv::activate(project = "~/SCP_env")
renv::install("BiocManager")
renv::install("zhanghao-njmu/SCP", repos = BiocManager::repositories())
SCP::PrepareEnv()
```
Option 2: If SCP is already installed in the global environment, copy SCP from the local library
```{r eval=FALSE}
renv::activate(project = "~/SCP_env")
renv::hydrate("SCP")
SCP::PrepareEnv()
```
#### Activate SCP environment first before use
```{r eval=FALSE}
renv::activate(project = "~/SCP_env")
library(SCP)
data("pancreas_sub")
pancreas_sub <- RunPAGA(srt = pancreas_sub, group_by = "SubCellType", linear_reduction = "PCA", nonlinear_reduction = "UMAP")
CellDimPlot(pancreas_sub, group.by = "SubCellType", reduction = "draw_graph_fr")
```
#### Save and restore the state of SCP environment
```{r eval=FALSE}
renv::snapshot(project = "~/SCP_env")
renv::restore(project = "~/SCP_env")
```
## Quick Start
- [Data exploration]
- [CellQC]
- [Standard pipeline]
- [Integration pipeline]
- [Cell projection between single-cell datasets]
- [Cell annotation using bulk RNA-seq datasets]
- [Cell annotation using single-cell datasets]
- [PAGA analysis]
- [Velocity analysis]
- [Differential expression analysis]
- [Enrichment analysis(over-representation)](#enrichment-analysisover-representation)
- [Enrichment analysis(GSEA)](#enrichment-analysisgsea)
- [Trajectory inference]
- [Dynamic features]
- [Interactive data visualization with SCExplorer]
- [Other visualization examples]
### Data exploration
The analysis is based on a subsetted version of [mouse pancreas data](https://doi.org/10.1242/dev.173849).
```{r library,results='markup'}
library(SCP)
library(BiocParallel)
register(MulticoreParam(workers = 8, progressbar = TRUE))
data("pancreas_sub")
print(pancreas_sub)
```
```{r EDA}
CellDimPlot(
srt = pancreas_sub, group.by = c("CellType", "SubCellType"),
reduction = "UMAP", theme_use = "theme_blank"
)
CellDimPlot(
srt = pancreas_sub, group.by = "SubCellType", stat.by = "Phase",
reduction = "UMAP", theme_use = "theme_blank"
)
FeatureDimPlot(
srt = pancreas_sub, features = c("Sox9", "Neurog3", "Fev", "Rbp4"),
reduction = "UMAP", theme_use = "theme_blank"
)
FeatureDimPlot(
srt = pancreas_sub, features = c("Ins1", "Gcg", "Sst", "Ghrl"),
compare_features = TRUE, label = TRUE, label_insitu = TRUE,
reduction = "UMAP", theme_use = "theme_blank"
)
ht <- GroupHeatmap(
srt = pancreas_sub,
features = c(
"Sox9", "Anxa2", # Ductal
"Neurog3", "Hes6", # EPs
"Fev", "Neurod1", # Pre-endocrine
"Rbp4", "Pyy", # Endocrine
"Ins1", "Gcg", "Sst", "Ghrl" # Beta, Alpha, Delta, Epsilon
),
group.by = c("CellType", "SubCellType"),
heatmap_palette = "YlOrRd",
cell_annotation = c("Phase", "G2M_score", "Cdh2"),
cell_annotation_palette = c("Dark2", "Paired", "Paired"),
show_row_names = TRUE, row_names_side = "left",
add_dot = TRUE, add_reticle = TRUE
)
print(ht$plot)
```
### CellQC
```{r RunCellQC}
pancreas_sub <- RunCellQC(srt = pancreas_sub)
CellDimPlot(srt = pancreas_sub, group.by = "CellQC", reduction = "UMAP")
CellStatPlot(srt = pancreas_sub, stat.by = "CellQC", group.by = "CellType", label = TRUE)
CellStatPlot(
srt = pancreas_sub,
stat.by = c(
"db_qc", "outlier_qc", "umi_qc", "gene_qc",
"mito_qc", "ribo_qc", "ribo_mito_ratio_qc", "species_qc"
),
plot_type = "upset", stat_level = "Fail"
)
```
### Standard pipeline
```{r Standard_SCP}
pancreas_sub <- Standard_SCP(srt = pancreas_sub)
CellDimPlot(
srt = pancreas_sub, group.by = c("CellType", "SubCellType"),
reduction = "StandardUMAP2D", theme_use = "theme_blank"
)
```
```{r CellDimPlot3D,eval=FALSE}
CellDimPlot3D(srt = pancreas_sub, group.by = "SubCellType")
```
![CellDimPlot3D](man/figures/CellDimPlot3D-1.png)
```{r FeatureDimPlot3D,eval=FALSE}
FeatureDimPlot3D(srt = pancreas_sub, features = c("Sox9", "Neurog3", "Fev", "Rbp4"))
```
![FeatureDimPlot3D](man/figures/FeatureDimPlot3D-1.png)
### Integration pipeline
Example data for integration is a subsetted version of [panc8(eight human pancreas datasets)](https://github.com/satijalab/seurat-data)
```{r Integration_SCP}
data("panc8_sub")
panc8_sub <- Integration_SCP(srtMerge = panc8_sub, batch = "tech", integration_method = "Seurat")
CellDimPlot(
srt = panc8_sub, group.by = c("celltype", "tech"), reduction = "SeuratUMAP2D",
title = "Seurat", theme_use = "theme_blank"
)
```
UMAP embeddings based on different integration methods in SCP:
```{r Integration-all, echo=FALSE, fig.height=13.5, fig.width=8.5,eval=FALSE}
library(ggplot2)
library(cowplot)
library(gtable)
integration_methods <- c("Uncorrected", "Seurat", "scVI", "MNN", "fastMNN", "Harmony", "Scanorama", "BBKNN", "CSS", "LIGER", "Conos", "ComBat")
plist <- list()
for (method in integration_methods) {
panc8_sub <- Integration_SCP(
srtMerge = panc8_sub, batch = "tech", linear_reduction_dims_use = 1:50,
integration_method = method, nonlinear_reduction = "umap"
)
plist[[method]] <- CellDimPlot(panc8_sub,
title = method, group.by = c("celltype"), reduction = paste0(method, "UMAP2D"), theme_use = "theme_blank",
xlab = "UMAP_1", ylab = "UMAP_2", legend.position = "none"
)
}
p <- plot_grid(plotlist = plist, ncol = 3)
grob <- ggplotGrob(p)
legend <- get_legend(CellDimPlot(panc8_sub, group.by = c("celltype"), reduction = paste0(method, "UMAP2D"), theme_use = "theme_blank", legend.position = "bottom", legend.direction = "horizontal"))
grob <- gtable_add_rows(grob, sum(legend$heights) + unit(1, "cm"), 0)
grob <- gtable_add_grob(grob, legend, t = 1, l = min(grob$layout[grepl(pattern = "panel", x = grob$layout$name), "l"]))
panel_fix(grob, height = 2)
```
![Integration-all](man/figures/Integration-all.png)
### Cell projection between single-cell datasets
```{r RunKNNMap}
panc8_rename <- RenameFeatures(
srt = panc8_sub,
newnames = make.unique(capitalize(rownames(panc8_sub[["RNA"]]), force_tolower = TRUE)),
assays = "RNA"
)
srt_query <- RunKNNMap(srt_query = pancreas_sub, srt_ref = panc8_rename, ref_umap = "SeuratUMAP2D")
ProjectionPlot(
srt_query = srt_query, srt_ref = panc8_rename,
query_group = "SubCellType", ref_group = "celltype"
)
```
### Cell annotation using bulk RNA-seq datasets
```{r RunKNNPredict-bulk}
data("ref_scMCA")
pancreas_sub <- RunKNNPredict(srt_query = pancreas_sub, bulk_ref = ref_scMCA, filter_lowfreq = 20)
CellDimPlot(srt = pancreas_sub, group.by = "KNNPredict_classification", reduction = "UMAP", label = TRUE)
```
### Cell annotation using single-cell datasets
```{r RunKNNPredict-scrna}
pancreas_sub <- RunKNNPredict(
srt_query = pancreas_sub, srt_ref = panc8_rename,
ref_group = "celltype", filter_lowfreq = 20
)
CellDimPlot(srt = pancreas_sub, group.by = "KNNPredict_classification", reduction = "UMAP", label = TRUE)
pancreas_sub <- RunKNNPredict(
srt_query = pancreas_sub, srt_ref = panc8_rename,
query_group = "SubCellType", ref_group = "celltype",
return_full_distance_matrix = TRUE
)
CellDimPlot(srt = pancreas_sub, group.by = "KNNPredict_classification", reduction = "UMAP", label = TRUE)
ht <- CellCorHeatmap(
srt_query = pancreas_sub, srt_ref = panc8_rename,
query_group = "SubCellType", ref_group = "celltype",
nlabel = 3, label_by = "row",
show_row_names = TRUE, show_column_names = TRUE
)
print(ht$plot)
```
### PAGA analysis
```{r RunPAGA}
pancreas_sub <- RunPAGA(
srt = pancreas_sub, group_by = "SubCellType",
linear_reduction = "PCA", nonlinear_reduction = "UMAP"
)
PAGAPlot(srt = pancreas_sub, reduction = "UMAP", label = TRUE, label_insitu = TRUE, label_repel = TRUE)
```
### Velocity analysis
> To estimate RNA velocity, you need to have both "spliced" and "unspliced" assays in your Seurat object. You can generate these matrices using [velocyto](http://velocyto.org/velocyto.py/index.html), [bustools](https://bustools.github.io/BUS_notebooks_R/velocity.html), or [alevin](https://combine-lab.github.io/alevin-fry-tutorials/2021/alevin-fry-velocity/).
```{r RunSCVELO}
pancreas_sub <- RunSCVELO(
srt = pancreas_sub, group_by = "SubCellType",
linear_reduction = "PCA", nonlinear_reduction = "UMAP"
)
VelocityPlot(srt = pancreas_sub, reduction = "UMAP", group_by = "SubCellType")
VelocityPlot(srt = pancreas_sub, reduction = "UMAP", plot_type = "stream")
```
### Differential expression analysis
```{r RunDEtest,fig.height=6, fig.width=12}
pancreas_sub <- RunDEtest(srt = pancreas_sub, group_by = "CellType", fc.threshold = 1, only.pos = FALSE)
VolcanoPlot(srt = pancreas_sub, group_by = "CellType")
```
```{r FeatureHeatmap, fig.height=6, fig.width=18}
DEGs <- pancreas_sub@tools$DEtest_CellType$AllMarkers_wilcox
DEGs <- DEGs[with(DEGs, avg_log2FC > 1 & p_val_adj < 0.05), ]
# Annotate features with transcription factors and surface proteins
pancreas_sub <- AnnotateFeatures(pancreas_sub, species = "Mus_musculus", db = c("TF", "CSPA"))
ht <- FeatureHeatmap(
srt = pancreas_sub, group.by = "CellType", features = DEGs$gene, feature_split = DEGs$group1,
species = "Mus_musculus", db = c("GO_BP", "KEGG", "WikiPathway"), anno_terms = TRUE,
feature_annotation = c("TF", "CSPA"), feature_annotation_palcolor = list(c("gold", "steelblue"), c("forestgreen")),
height = 5, width = 4
)
print(ht$plot)
```
### Enrichment analysis(over-representation) {#enrichment-analysisover-representation}
```{r RunEnrichment}
pancreas_sub <- RunEnrichment(
srt = pancreas_sub, group_by = "CellType", db = "GO_BP", species = "Mus_musculus",
DE_threshold = "avg_log2FC > log2(1.5) & p_val_adj < 0.05"
)
EnrichmentPlot(
srt = pancreas_sub, group_by = "CellType", group_use = c("Ductal", "Endocrine"),
plot_type = "bar"
)
EnrichmentPlot(
srt = pancreas_sub, group_by = "CellType", group_use = c("Ductal", "Endocrine"),
plot_type = "wordcloud"
)
EnrichmentPlot(
srt = pancreas_sub, group_by = "CellType", group_use = c("Ductal", "Endocrine"),
plot_type = "wordcloud", word_type = "feature"
)
EnrichmentPlot(
srt = pancreas_sub, group_by = "CellType", group_use = "Ductal",
plot_type = "network"
)
```
> To ensure that labels are visible, you can adjust the size of the viewer panel on Rstudio IDE.
```{r Enrichment_enrichmap, fig.height=9.5, fig.width=15}
EnrichmentPlot(
srt = pancreas_sub, group_by = "CellType", group_use = "Ductal",
plot_type = "enrichmap"
)
```
```{r Enrichment_comparison, fig.height=6}
EnrichmentPlot(srt = pancreas_sub, group_by = "CellType", plot_type = "comparison")
```
### Enrichment analysis(GSEA) {#enrichment-analysisgsea}
```{r RunGSEA}
pancreas_sub <- RunGSEA(
srt = pancreas_sub, group_by = "CellType", db = "GO_BP", species = "Mus_musculus",
DE_threshold = "p_val_adj < 0.05"
)
GSEAPlot(srt = pancreas_sub, group_by = "CellType", group_use = "Endocrine", id_use = "GO:0007186")
```
```{r GSEA_bar}
GSEAPlot(
srt = pancreas_sub, group_by = "CellType", group_use = "Endocrine", plot_type = "bar",
direction = "both", topTerm = 20
)
```
```{r GSEA_comparison, fig.height=6}
GSEAPlot(srt = pancreas_sub, group_by = "CellType", plot_type = "comparison")
```
### Trajectory inference
```{r RunSlingshot}
pancreas_sub <- RunSlingshot(srt = pancreas_sub, group.by = "SubCellType", reduction = "UMAP")
FeatureDimPlot(pancreas_sub, features = paste0("Lineage", 1:3), reduction = "UMAP", theme_use = "theme_blank")
CellDimPlot(pancreas_sub, group.by = "SubCellType", reduction = "UMAP", lineages = paste0("Lineage", 1:3), lineages_span = 0.1)
```
### Dynamic features
```{r DynamicHeatmap, fig.height=9, fig.width=18}
pancreas_sub <- RunDynamicFeatures(srt = pancreas_sub, lineages = c("Lineage1", "Lineage2"), n_candidates = 200)
ht <- DynamicHeatmap(
srt = pancreas_sub, lineages = c("Lineage1", "Lineage2"),
use_fitted = TRUE, n_split = 6, reverse_ht = "Lineage1",
species = "Mus_musculus", db = "GO_BP", anno_terms = TRUE, anno_keys = TRUE, anno_features = TRUE,
heatmap_palette = "viridis", cell_annotation = "SubCellType",
separate_annotation = list("SubCellType", c("Nnat", "Irx1")), separate_annotation_palette = c("Paired", "Set1"),
feature_annotation = c("TF", "CSPA"), feature_annotation_palcolor = list(c("gold", "steelblue"), c("forestgreen")),
pseudotime_label = 25, pseudotime_label_color = "red",
height = 5, width = 2
)
print(ht$plot)
```
```{r DynamicPlot}
DynamicPlot(
srt = pancreas_sub, lineages = c("Lineage1", "Lineage2"), group.by = "SubCellType",
features = c("Plk1", "Hes1", "Neurod2", "Ghrl", "Gcg", "Ins2"),
compare_lineages = TRUE, compare_features = FALSE
)
```
```{r FeatureStatPlot, fig.height=6, fig.width=13}
FeatureStatPlot(
srt = pancreas_sub, group.by = "SubCellType", bg.by = "CellType",
stat.by = c("Sox9", "Neurod2", "Isl1", "Rbp4"), add_box = TRUE,
comparisons = list(
c("Ductal", "Ngn3 low EP"),
c("Ngn3 high EP", "Pre-endocrine"),
c("Alpha", "Beta")
)
)
```
### Interactive data visualization with SCExplorer
```{r SCExplorer}
PrepareSCExplorer(list(mouse_pancreas = pancreas_sub, human_pancreas = panc8_sub), base_dir = "./SCExplorer")
app <- RunSCExplorer(base_dir = "./SCExplorer")
list.files("./SCExplorer") # This directory can be used as site directory for Shiny Server.
if (interactive()) {
shiny::runApp(app)
}
```
![SCExplorer1](man/figures/SCExplorer-1.png) ![SCExplorer2](man/figures/SCExplorer-2.png)
### Other visualization examples
[**CellDimPlot**](https://zhanghao-njmu.github.io/SCP/reference/CellDimPlot.html)![Example1](man/figures/Example-1.jpg) [**CellStatPlot**](https://zhanghao-njmu.github.io/SCP/reference/CellStatPlot.html)![Example2](man/figures/Example-2.jpg) [**FeatureStatPlot**](https://zhanghao-njmu.github.io/SCP/reference/FeatureStatPlot.html)![Example3](man/figures/Example-3.jpg) [**GroupHeatmap**](https://zhanghao-njmu.github.io/SCP/reference/GroupHeatmap.html)![Example3](man/figures/Example-4.jpg)
You can also find more examples in the documentation of the function: [Integration_SCP](https://zhanghao-njmu.github.io/SCP/reference/Integration_SCP.html), [RunKNNMap](https://zhanghao-njmu.github.io/SCP/reference/RunKNNMap.html), [RunMonocle3](https://zhanghao-njmu.github.io/SCP/reference/RunMonocle3.html), [RunPalantir](https://zhanghao-njmu.github.io/SCP/reference/RunPalantir.html), etc.