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Gene Expression, V(D)J, & Feature Barcode Analysis with Cell Ranger multi (5' Immune Profiling Kit)

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Single Cell Gene Expression
Single Cell Immune Profiling
Single Cell Gene Expression Flex
New in Cell Ranger v7.0: Intronic reads are counted by default for whole transcriptome gene expression data. For more information, see our recommendation on including introns for gene expression analysis page.
After June 30, 2023, new Cell Ranger releases will no longer support Targeted Gene Expression analysis.

The 5' Chromium Next GEM Single Cell Immune Profiling Solution with Feature Barcode technology enables simultaneous profiling of the V(D)J repertoire, cell surface protein, antigen, and gene expression (GEX) data. The cellranger multi pipeline analyzes these multiple library types together, enabling more consistent cell calling between the V(D)J and gene expression data.

The cellranger multi pipeline takes a config CSV with paths to FASTQ files from cellranger mkfastq, bcl2fastq, or BCL Convert for any combination of 5' Gene Expression, Feature Barcode (cell surface protein, antibody/antigen, or CRISPR), and V(D)J libraries from a single GEM well. It performs alignment, filtering, barcode counting, and UMI counting on the Gene Expression and/or Feature Barcode libraries. It also performs sequence assembly and paired clonotype calling on the V(D)J libraries. Additionally, the cell calls provided by the gene expression data are used to improve the cell calls from the V(D)J data. Visit the multi tutorial page for self-guided and video tutorials on running cellranger multi.

The 5' Chromium Next GEM Immune Profiling Solution does not support cell multiplexing, and Cell Ranger does not support demultiplexing 5' libraries.

Pipeline recommendation depends on the combination of input libraries. In general, cellranger multi is the recommended pipeline for analyzing a combination of Gene Expression and V(D)J libraries (with or without Feature Barcode libraries) sequenced from the same sample. This table summarizes a few popular library combinations and their corresponding pipeline recommendations:

Library combinationmultiOther pipelines
Antigen (BEAM)Not allowedNone
GEX + VDJRecommendedcount and vdj
GEX + VDJ + AntibodyRecommendedcount and vdj
GEX + VDJ + Antibody + CRISPRRecommendedcount and vdj
GEX + VDJ + Antibody + Antigen (BEAM)RecommendedNone
GEX + Antigen (BEAM)Not allowedNone

The cellranger multi pipeline improves cell calls in the V(D)J dataset by discarding any cells that were not also called in the corresponding 5' Gene Expression dataset. By assigning cells that are called in the V(D)J results but not in the 5' Gene Expression results as background GEMs in the V(D)J data, cellranger multi mitigates any overcalling issues that may arise in V(D)J data. This improved cell calling is only possible when both 5' Gene Expression and V(D)J libraries were sequenced from the same sample. As shown in the image below, final V(D)J cell calls (intersection area) exclude cells that were only called by the vdj pipeline (yellow region).

The 5' Gene Expression cell calls are not affected by the cellranger multi pipeline. The Gene Expression library is representative of the entire pool of poly-adenylated mRNA transcripts captured within each GEM. VDJ-T or VDJ-B transcripts in the Gene Expression library are then selectively amplified to create the V(D)J library. Therefore, the Gene Expression library has more power to detect GEMs containing cells compared to the V(D)J library. If the cellranger multi pipeline is run with both 5' Gene Expression and V(D)J data, barcodes that are not called cells in the 5' Gene Expression data are deleted from the V(D)J cell set.

The cellranger multi pipeline takes a config CSV file as input. The config CSV contains paths to FASTQ files for any combination of V(D)J, Gene Expression, and/or Feature Barcode libraries. To generate FASTQ files, follow the instructions for running cellranger mkfastq.

To simultaneously generate single cell feature counts, V(D)J sequences, and annotations for a single library, run cellranger multi with the following arguments:

--idA unique run ID string: e.g. sample345 that is also the output folder name. Cannot be more than 64 characters.
--csvPath to multi config CSV file enumerating input libraries and analysis parameters.

The multi config CSV contains both the library definitions and experiment configuration variables. It is composed of up to four sections: [gene-expression], [feature], [vdj], [antigen-specificity] and [libraries].

The [gene-expression], [feature], [vdj], and [antigen-specificity] sections have at most two columns and are responsible for configuring their respective portions of the experiment. The [libraries] section specifies where input FASTQ files may be found.

Go to the Cell Ranger Multi Config CSV page for a complete list of options for each section.

Example multi config CSVs can be downloaded from public datasets. Cell Ranger v7.1 and later also provides the option to download a multi config CSV template via the command line.

Example formats for a few product configurations are below.

Starting in Cell Ranger 7.0, the expected number of cells can either be auto-estimated or specified with expect-cells (e.g., to replicate a previous analysis). If needed, automated cell calling can be overridden with the --force-cells option. See Gene Expression algorithm page for details

After determining the input arguments, run cellranger multi. Remember to customize the code with your sample id and csv file path:

mkdir /home/jdoe/runs cd /home/jdoe/runs cellranger multi --id=sample345 --csv=/home/jdoe/sample345.csv

Following a series of checks to validate input arguments, cellranger multi pipeline stages will begin to run:

Martian Runtime - v4.0.8 Running preflight checks (please wait)... ...

By default, cellranger will use all of the cores available on your system to execute pipeline stages. You can specify a different number of cores to use with the --localcores option; for example, --localcores=16 will limit cellranger to using up to sixteen cores at once. Similarly, --localmem will restrict the amount of memory (in GB) used by cellranger.

The pipeline will create a new folder named with the run ID you specified using the --id argument (e.g. /home/jdoe/runs/sample345) for its output. If this folder already exists, cellranger will assume it is an existing pipestance and attempt to resume running it. If you wish to re-start the run, delete the output folder (sample345/ in this example) and rerun the pipeline.

A successful cellranger multi run should conclude with a message similar to this:

Waiting 6 seconds for UI to do final refresh. Pipestance completed successfully! yyyy-mm-dd hh:mm:ss Shutting down. Saving pipestance info to "tiny/tiny.mri.tgz"

To learn more about the output files generated, refer to the Outputs for multi section.

Cell Ranger multi v7.0.0 and later allows users to analyze T cell libraries enriched for gamma (TRG) and delta (TRD) chains. 10x Genomics does not provide reagents or primers for TRG/D chain enrichment. Since this workflow is not fully supported, the Cell Ranger pipeline has not been extensively tested for TRG/D libraries, and the algorithm's performance cannot be guaranteed.

To analyze TRG/D libraries, set feature_types to VDJ-T-GD in the [libraries] section of the multi config CSV. Auto-detection does not work for TRG/D chains. If set to auto-detection, TRG/D libraries are treated as VDJ-T libraries enriched for alpha-beta chains, and the gamma-delta chains are filtered out. The pipeline runs to completion, but zero barcodes are assigned to cells.

Refer to the example multi config CSV for additional configuration guidance. Outputs from a successful gamma-delta run are located in the vdj_t_gd folder.

The cellranger vdj pipeline cannot process FASTQs from TRG/D enriched libraries.

10x Genomics does not support the use of cellranger aggr to aggregate the outputs of TRG/D enriched libraries.

Visit the Antigen Capture page for specific information on how to run Cell Ranger multi to analyze your Antigen Capture/BEAM libraries.

In the [libraries] section of the multi config CSV, setting feature_types to VDJ enables auto-detection of the chain type.

  • Auto-detection only works for VDJ-B libraries and VDJ-T libraries with alpha-beta chains.

  • Auto-detection only works when all V(D)J FASTQs are the same chain type. For example, auto-detection with feature_types set to VDJ fails when both VDJ-T and VDJ-B FASTQ sets are included.

  • If the chain for one V(D)J FASTQ set is specified, chains for all existing V(D)J FASTQ sets must be specified. Valid specifications include, VDJ, VDJ-T, VDJ-B, or VDJ-T-GD, and the combinations:

    • VDJ-T & VDJ-B
    • VDJ-T-GD & VDJ-B
    • VDJ-T & VDJ-T-GD & VDJ-B
  • Auto-detection does not work for TRG/D (gamma-delta) chains. If set to auto-detection (VDJ), gamma-delta libraries are treated as VDJ-T, and gamma-delta chains are filtered out. The pipeline runs to completion, but zero barcodes are assigned to cells. For TRG/D chains, set feature_types to VDJ-T-GD.

Auto-detection is enabled for Antigen Capture (BEAM) libraries. Use feature_types = Antigen Capture for both TCR and BCR Antigen Capture libraries.

Generate a multi config CSV template by running cellranger multi-template, see usage here.

Here are the example multi config CSVs for a few commonly used library combinations. Make sure to replace /path/to with the actual full path to your data, and edit any text in red according to the experiment's sample/library/file names. TRG/D and Antigen Capture config examples are located on their respective pages.

See example dataset

A self-directed tutorial is available

[vdj] reference,/path/to/vdj_reference [libraries] fastq_id,fastqs,feature_types VDJ_B_fastqs_id,/path/to/vdj_B_fastqs,VDJ-B

See example dataset

A self-directed tutorial is available

[gene-expression] reference,/path/to/transcriptome [vdj] reference,/path/to/vdj_reference [libraries] fastq_id,fastqs,feature_types GEX_fastqs_id,/path/to/GEX_fastqs,Gene Expression VDJ_B_fastqs_id,/path/to/vdj_B_fastqs,VDJ-B ```
[gene-expression] reference,/path/to/transcriptome [vdj] reference,/path/to/vdj_reference [feature] reference,/path/to/feature_ref.csv [libraries] fastq_id,fastqs,lanes,feature_types GEX_fastqs_id,/path/to/GEX1_fastqs,1,Gene Expression GEX_fastqs_id,/path/to/GEX2_fastqs,2,Gene Expression GEX_fastqs_id,/path/to/GEX3_fastqs,3,Gene Expression VDJ_B_fastqs_id,/path/to/vdj_B1_fastqs,1,VDJ-B VDJ_B_fastqs_id,/path/to/vdj_B2_fastqs,2,VDJ-B VDJ_B_fastqs_id,/path/to/vdj_B3_fastqs,4,VDJ-B

See example dataset

[gene-expression] reference,/path/to/transcriptome [vdj] reference,/path/to/vdj_reference [feature] reference,/path/to/feature_ref.csv [libraries] fastq_id,fastqs,lanes,feature_types GEX_fastqs_id,/path/to/GEX_fastqs,1|2,Gene Expression VDJ_B_fastqs_id,/path/to/vdj_B_fastqs,1|2,VDJ-B VDJ_T_fastqs_id,/path/to/vdj_T_fastqs,1|2,VDJ-T FB_fastqs_id,/path/to/FB_fastqs,1|2,Antibody Capture CRISPR_fastqs_id,/path/to/CRISPR_fastqs,1|2,CRISPR Guide Capture

This template also applies to V(D)J + FB (without GEX) libraries. The [gene-expression] reference section is required. However, the GEX FASTQ specification under the [libraries] section must be removed for the VDJ+FB library combinations.

The cellranger multi pipeline supports downsampling the reads by specifying a rate between 0 and 1 independently for each library. It also allows trimming the reads to a fixed length, which is not supported in the cellranger vdj pipeline.

The option to run denovo without V(D)J reference (--denovo) is not supported in cellranger multi. This option is available in cellranger vdj.

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