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<!-- README.md is generated from README.Rmd. Please edit that file --> <!-- badges: start --> <!-- badges: end --><a href='https://CRAN.R-project.org/package=dsb/'><img src='man/figures/sticker2.png' align="right" width="150" /></a> dsb: a method for normalizing and denoising antibody derived tag data from CITE-seq, ASAP-seq, TEA-seq and related assays.
The dsb R package is available on CRAN: latest dsb
release
To install in R use install.packages('dsb')
<br>
Mulè, Martins, and Tsang, Nature Communications (2022) describes our deconvolution of ADT noise sources and development of dsb. <br>
Vignettes:
- Using dsb in an end to end CITE-seq workflow including multimodal clustering in Seurat
- How the dsb method works
- Normalizing ADTs if empty drops are not available
- Python users: use dsb in Python with scverse software muon
- FAQ etc. <br>
Recent Publications Check out recent publications that used dsb for ADT normalization.
In the first “end to end” vignette, we demonstrate basic CITE-seq analysis starting from UMI count alignment output files from Cell Ranger though note that dsb is compatible with any alignment tool (see using other alignment tools). We load unfiltered UMI data containing cells and empty droplets, perform QC on cells and background droplets, normalize with dsb, and demonstrate protein-based clustering and multimodal RNA+Protein joint clustering using dsb normalized values with Seurat’s Weighted Nearest Neighbor method.
Background and motivation <a name="background_motivation"></a>
Protein data derived from sequencing antibody derived tags (ADTs) in CITE-seq and other related assays has substantial background noise. Our paper outlines experiments and analysis designed to dissect sources of noise in ADT data we used to developed our method. We found all experiments measuring ADTs capture protein-specific background noise because ADT reads in empty / background drops (outnumbering cell-containing droplets > 10-fold in all experiments) were highly concordant with ADT levels in unstained spike-in cells. We therefore utilize background droplets which capture the ambient component of protein background noise to correct values in cells. We also remove technical cell-to-cell variations by defining each cell’s dsb “technical component”, a conservative adjustment factor derived by combining isotype control levels with each cell’s specific background level fitted with a single cell model.
Installation and quick overview <a name="installation"></a>
The method is carried out in a single step with a call to the
DSBNormalizeProtein()
function.
cells_citeseq_mtx
- a raw ADT count matrix empty_drop_citeseq_mtx
-
a raw ADT count matrix from non-cell containing empty / background
droplets.
denoise.counts = TRUE
- implement step II to define and remove the
‘technical component’ of each cell’s protein library.
use.isotype.control = TRUE
- include isotype controls in the modeled
dsb technical component.
# install.packages('dsb')
library(dsb)
adt_norm = DSBNormalizeProtein(
cell_protein_matrix = cells_citeseq_mtx,
empty_drop_matrix = empty_drop_citeseq_mtx,
denoise.counts = TRUE,
use.isotype.control = TRUE,
isotype.control.name.vec = rownames(cells_citeseq_mtx)[67:70]
)
<img src="man/figures/multimodal_heatmap.png" />
Please see the main vignette on CRAN for more details. <br>
Selected publications using dsb <a name="pubications"></a>
Publications from other investigators <br> Izzo et al. Nature 2024 <br> Arieta et al. Cell 2023 <br> Magen et al. Nature Medicine 2023 <br> COMBAT consortium Cell 2021 <br> Jardine et al. Nature 2021 <br> Mimitou et al. Nature Biotechnology 2021 <br>
Publications from the Tsang lab <br> Mulè et al. Immunity 2024 <br> Sparks et al. Nature 2023 <br> Liu et al. Cell 2021 <br> Kotliarov et al. Nature Medicine 2020 <br>
using other alignment algorithms <a name="otheraligners"></a>
dsb was developed prior to 10X Genomics supporting CITE-seq or hashing data and we routinely use other alignment pipelines.
A note on alignment and how to use dsb with Cell Ranger is detailed in the main vignette. Cells and empty droplets are used by default by dsb.
<img src="man/figures/readme_cheatsheet.png" />To use dsb properly with CITE-seq-Count you need to align background.
One way to do this is to set the -cells
argument to ~ 200000. That
will align the top 200000 barcodes in terms of ADT library size, making
sure you capture the background. Please refer to CITE-seq-count
documentation
CITE-seq-Count -R1 TAGS_R1.fastq.gz -R2 TAGS_R2.fastq.gz \
-t TAG_LIST.csv -cbf X1 -cbl X2 -umif Y1 -umil Y2 \
-cells 200000 -o OUTFOLDER
If you already aligned your mRNA with Cell Ranger or something else but wish to use a different tool like kallisto or Cite-seq-count for ADT alignment, you can provide the latter with whitelist of cell barcodes to align. A simple way to do this is to extract all barcodes with at least k mRNA where we set k to a tiny number to retain cells and cells capturing ambient ADT reads:
library(Seurat)
umi = Read10X(data.dir = 'data/raw_feature_bc_matrix/')
k = 3
barcode.whitelist =
rownames(
CreateSeuratObject(counts = umi,
min.features = k, # retain all barcodes with at least k raw mRNA
min.cells = 800, # this just speeds up the function by removing genes.
)@meta.data
)
write.table(barcode.whitelist,
file =paste0(your_save_path,"barcode.whitelist.tsv"),
sep = '\t', quote = FALSE, col.names = FALSE, row.names = FALSE)
With the example dataset in the vignette this retains about 150,000 barcodes.
Now you can provide that as an argument to -wl
in CITE-seq-count to
align the ADTs and then proceed with the dsb analysis example.
CITE-seq-Count -R1 TAGS_R1.fastq.gz -R2 TAGS_R2.fastq.gz \
-t TAG_LIST.csv -cbf X1 -cbl X2 -umif Y1 -umil Y2 \
-wl path_to_barcode.whitelist.tsv -o OUTFOLDER
This whitelist can also be provided to Kallisto.
kallisto bustools
documentation
kb count -i index_file -g gtf_file.t2g -x 10xv3 \
-t n_cores -w path_to_barcode.whitelist.tsv -o output_dir \
input.R1.fastq.gz input.R2.fastq.gz
Next one can similarly define cells and background droplets empirically with protein and mRNA based thresholding as outlined in the main tutorial.
A note on Cell Ranger –expect-cells <a name="cellranger"></a>
Note whether or not you use dsb, if you want to define cells using the
filtered_feature_bc_matrix
file, you should make sure to properly set
the Cell Ranger --expect-cells
argument roughly equal to the estimated
cell recovery per lane based on number of cells you loaded in the
experiment. see the note from 10X about
this.
The default value of 3000 is relatively low for modern experiments. Note
cells and empty droplets can also be defined directly from the
raw_feature_bc_matrix
using any method, including simple protein and
mRNA library size based thresholding because this contains all droplets.
Topics covered in other vignettes on CRAN: Integrating dsb with Bioconductor, integrating dsb with python/Scanpy, Using dsb with data lacking isotype controls, integrating dsb with sample multiplexing experiments, using dsb on data with multiple batches, advanced usage - using a different scale / standardization based on empty droplet levels, returning internal stats used by dsb, outlier clipping with the quantile.clipping argument, other FAQ.