--- name: bio-workflows-multiome-pipeline description: End-to-end multiome workflow for joint scRNA-seq + scATAC-seq analysis. Covers data loading, separate modality processing, and WNN integration with Seurat/Signac. Use when analyzing joint scRNA+scATAC data. tool_type: r primary_tool: Seurat workflow: true depends_on: - single-cell/data-io - single-cell/preprocessing - single-cell/clustering - single-cell/multimodal-integration - single-cell/scatac-analysis - atac-seq/single-cell-atac - atac-seq/co-accessibility - atac-seq/motif-deviation qc_checkpoints: - after_loading: "Both modalities detected per cell" - after_rna_qc: "RNA quality filters passed" - after_atac_qc: "TSS enrichment >2, nucleosome signal <4" - after_wnn: "Joint embedding separates cell types" --- ## Version Compatibility Reference examples tested with: ggplot2 3.5+ Before using code patterns, verify installed versions match. If versions differ: - R: `packageVersion('')` then `?function_name` to verify parameters If code throws ImportError, AttributeError, or TypeError, introspect the installed package and adapt the example to match the actual API rather than retrying. # Multiome Pipeline **"Analyze my 10X Multiome data jointly"** -> Orchestrate Cell Ranger ARC processing, Seurat/Signac scRNA+scATAC integration via WNN, chromatin accessibility peak calling, motif enrichment, and gene regulatory network inference. Complete workflow for 10X Multiome (joint scRNA + scATAC) analysis using Seurat and Signac. ## Workflow Overview ``` 10X Multiome data | v [1. Load Data] ---------> Read RNA + ATAC | v [2. RNA Processing] ----> Standard scRNA workflow | v [3. ATAC Processing] ---> Peak calling, LSI | v [4. WNN Integration] ---> Weighted nearest neighbors | v [5. Joint Analysis] ----> Clustering, markers | v [6. Linked Features] ---> Gene-peak links | v Integrated multiome object ``` ## Step 1: Load Multiome Data ```r library(Seurat) library(Signac) library(EnsDb.Hsapiens.v86) library(ggplot2) # Load RNA rna_counts <- Read10X_h5('filtered_feature_bc_matrix.h5') # For multiome, this returns a list with 'Gene Expression' and 'Peaks' # Create Seurat object with RNA seurat_obj <- CreateSeuratObject( counts = rna_counts$`Gene Expression`, assay = 'RNA' ) # Load ATAC atac_counts <- rna_counts$Peaks # Or from fragments file frags <- CreateFragmentObject('atac_fragments.tsv.gz', cells = colnames(seurat_obj)) # Create ChromatinAssay atac_assay <- CreateChromatinAssay( counts = atac_counts, sep = c(':', '-'), fragments = frags, annotation = GetGRangesFromEnsDb(ensdb = EnsDb.Hsapiens.v86) ) seurat_obj[['ATAC']] <- atac_assay ``` ## Step 2: RNA Quality Control and Processing ```r # QC metrics seurat_obj[['percent.mt']] <- PercentageFeatureSet(seurat_obj, pattern = '^MT-') # Filter seurat_obj <- subset(seurat_obj, nCount_RNA > 1000 & nCount_RNA < 25000 & percent.mt < 20 ) # Normalize RNA seurat_obj <- SCTransform(seurat_obj, assay = 'RNA', verbose = FALSE) # PCA seurat_obj <- RunPCA(seurat_obj, assay = 'SCT', verbose = FALSE) ``` ## Step 3: ATAC Quality Control and Processing ```r # ATAC QC metrics DefaultAssay(seurat_obj) <- 'ATAC' seurat_obj <- NucleosomeSignal(seurat_obj) seurat_obj <- TSSEnrichment(seurat_obj) # Visualize VlnPlot(seurat_obj, features = c('nCount_ATAC', 'TSS.enrichment', 'nucleosome_signal'), pt.size = 0, ncol = 3) # Filter ATAC seurat_obj <- subset(seurat_obj, nCount_ATAC > 1000 & nCount_ATAC < 100000 & TSS.enrichment > 2 & nucleosome_signal < 4 ) # Normalize ATAC (TF-IDF + SVD = LSI) seurat_obj <- RunTFIDF(seurat_obj) seurat_obj <- FindTopFeatures(seurat_obj, min.cutoff = 'q0') seurat_obj <- RunSVD(seurat_obj) # Check LSI components (first often correlates with depth) DepthCor(seurat_obj) ``` ## Step 4: Weighted Nearest Neighbors (WNN) ```r # Build WNN graph using both modalities seurat_obj <- FindMultiModalNeighbors( seurat_obj, reduction.list = list('pca', 'lsi'), dims.list = list(1:30, 2:30), # Skip LSI component 1 if depth-correlated modality.weight.name = 'RNA.weight' ) # UMAP on WNN graph seurat_obj <- RunUMAP(seurat_obj, nn.name = 'weighted.nn', reduction.name = 'wnn.umap', reduction.key = 'wnnUMAP_') # Cluster on WNN seurat_obj <- FindClusters(seurat_obj, graph.name = 'wsnn', algorithm = 3, resolution = 0.5, verbose = FALSE) ``` ## Step 5: Visualization and Markers ```r # Compare modality-specific and joint embeddings p1 <- DimPlot(seurat_obj, reduction = 'pca', label = TRUE) + ggtitle('RNA PCA') p2 <- DimPlot(seurat_obj, reduction = 'lsi', label = TRUE) + ggtitle('ATAC LSI') p3 <- DimPlot(seurat_obj, reduction = 'wnn.umap', label = TRUE) + ggtitle('WNN UMAP') p1 + p2 + p3 # Modality weights per cell VlnPlot(seurat_obj, features = 'RNA.weight', group.by = 'seurat_clusters', pt.size = 0) # Find markers (RNA) DefaultAssay(seurat_obj) <- 'SCT' rna_markers <- FindAllMarkers(seurat_obj, only.pos = TRUE, min.pct = 0.25) # Find markers (ATAC - differentially accessible peaks) DefaultAssay(seurat_obj) <- 'ATAC' atac_markers <- FindAllMarkers(seurat_obj, only.pos = TRUE, min.pct = 0.05, test.use = 'LR', latent.vars = 'nCount_ATAC') ``` ## Step 6: Gene-Peak Linkage ```r # Link peaks to genes DefaultAssay(seurat_obj) <- 'ATAC' seurat_obj <- RegionStats(seurat_obj, genome = BSgenome.Hsapiens.UCSC.hg38) seurat_obj <- LinkPeaks( seurat_obj, peak.assay = 'ATAC', expression.assay = 'SCT', genes.use = c('CD8A', 'CD4', 'MS4A1', 'CD14') # Example genes ) # Visualize links CoveragePlot(seurat_obj, region = 'CD8A', features = 'CD8A', expression.assay = 'SCT', extend.upstream = 10000, extend.downstream = 10000) ``` ## Complete Workflow Script ```r library(Seurat) library(Signac) library(EnsDb.Hsapiens.v86) library(BSgenome.Hsapiens.UCSC.hg38) library(ggplot2) # Configuration data_dir <- 'multiome_output' output_dir <- 'multiome_results' dir.create(output_dir, showWarnings = FALSE) # === Load Data === cat('Loading data...\n') counts <- Read10X_h5(file.path(data_dir, 'filtered_feature_bc_matrix.h5')) frags <- file.path(data_dir, 'atac_fragments.tsv.gz') seurat_obj <- CreateSeuratObject(counts = counts$`Gene Expression`, assay = 'RNA') seurat_obj[['ATAC']] <- CreateChromatinAssay( counts = counts$Peaks, sep = c(':', '-'), fragments = frags, annotation = GetGRangesFromEnsDb(ensdb = EnsDb.Hsapiens.v86) ) cat('Cells:', ncol(seurat_obj), '\n') # === RNA QC === cat('RNA QC...\n') seurat_obj[['percent.mt']] <- PercentageFeatureSet(seurat_obj, pattern = '^MT-') seurat_obj <- subset(seurat_obj, nCount_RNA > 1000 & nCount_RNA < 25000 & percent.mt < 20) # === ATAC QC === cat('ATAC QC...\n') DefaultAssay(seurat_obj) <- 'ATAC' seurat_obj <- NucleosomeSignal(seurat_obj) seurat_obj <- TSSEnrichment(seurat_obj) seurat_obj <- subset(seurat_obj, nCount_ATAC > 1000 & TSS.enrichment > 2 & nucleosome_signal < 4) cat('After QC:', ncol(seurat_obj), 'cells\n') # === Process RNA === cat('Processing RNA...\n') DefaultAssay(seurat_obj) <- 'RNA' seurat_obj <- SCTransform(seurat_obj, verbose = FALSE) seurat_obj <- RunPCA(seurat_obj, verbose = FALSE) # === Process ATAC === cat('Processing ATAC...\n') DefaultAssay(seurat_obj) <- 'ATAC' seurat_obj <- RunTFIDF(seurat_obj) seurat_obj <- FindTopFeatures(seurat_obj, min.cutoff = 'q0') seurat_obj <- RunSVD(seurat_obj) # === WNN Integration === cat('WNN integration...\n') seurat_obj <- FindMultiModalNeighbors(seurat_obj, reduction.list = list('pca', 'lsi'), dims.list = list(1:30, 2:30), modality.weight.name = 'RNA.weight' ) seurat_obj <- RunUMAP(seurat_obj, nn.name = 'weighted.nn', reduction.name = 'wnn.umap', reduction.key = 'wnnUMAP_') seurat_obj <- FindClusters(seurat_obj, graph.name = 'wsnn', resolution = 0.5, verbose = FALSE) # === Save === saveRDS(seurat_obj, file.path(output_dir, 'multiome_analyzed.rds')) # === Plots === pdf(file.path(output_dir, 'wnn_umap.pdf'), width = 10, height = 8) DimPlot(seurat_obj, reduction = 'wnn.umap', label = TRUE) dev.off() cat('Results saved to:', output_dir, '\n') cat('Clusters:', length(unique(seurat_obj$seurat_clusters)), '\n') ``` ## Related Skills - single-cell/data-io - Loading 10X data - single-cell/preprocessing - QC and normalization - single-cell/multimodal-integration - WNN details - single-cell/scatac-analysis - ATAC-specific processing - atac-seq/single-cell-atac - Signac / ArchR / SnapATAC2 ecosystem decision; AMULET; cellranger-arc - atac-seq/co-accessibility - Cicero / ArchR getCoAccessibility for cis-regulatory inference - atac-seq/enhancer-gene-linking - ABC / ENCODE-rE2G for enhancer-gene mapping - atac-seq/motif-deviation - chromVAR for per-cell TF motif activity - atac-seq/footprinting - scprinter for sc footprinting