scRepertoire 2.3.1
scRepertoire is designed to take filter contig outputs from the 10x Genomics Cell Ranger pipeline, process that data to assign clonotype based on two TCR or Ig chains and analyze the clonotype dynamics. The latter can be separated into 1) clonotype-only analysis functions, such as unique clonotypes or clonal space quantification, and 2) interaction with mRNA expression data using Seurat or SingleCellExperiment packages.
suppressMessages(library(scRepertoire))
scRepertoire functions using the filtered_contig_annotations.csv output from the 10x Genomics Cell Ranger. This file is located in the ./outs/ directory of the VDJ alignment folder. To generate a list of contigs to use for scRepertoire:
S1 <- read.csv(".../Sample1/outs/filtered_contig_annotations.csv")
S2 <- read.csv(".../Sample2/outs/filtered_contig_annotations.csv")
S3 <- read.csv(".../Sample3/outs/filtered_contig_annotations.csv")
S4 <- read.csv(".../Sample4/outs/filtered_contig_annotations.csv")
contig_list <- list(S1, S2, S3, S4)
Beyond the default 10x Genomic Cell Ranger pipeline outputs, scRepertoire supports the following single-cell formats:
loadContigs()
can be given a directory where the sequencing experiments are located and it will recursively load and process the contig data based on the file names. Alternatively, loadContigs()
can be given a list of data frames and process the contig data
#Directory example
contig.output <- c("~/Documents/MyExperiment")
contig.list <- loadContigs(input = contig.output,
format = "TRUST4")
#List of data frames example
S1 <- read.csv("~/Documents/MyExperiment/Sample1/outs/barcode_results.csv")
S2 <- read.csv("~/Documents/MyExperiment/Sample2/outs/barcode_results.csv")
S3 <- read.csv("~/Documents/MyExperiment/Sample3/outs/barcode_results.csv")
S4 <- read.csv("~/Documents/MyExperiment/Sample4/outs/barcode_results.csv")
contig_list <- list(S1, S2, S3, S4)
contig.list <- loadContigs(input = contig.output,
format = "WAT3R")
It is now easy to create the contig list from a multiplexed experiment by first generating a single-cell RNA object (either Seurat or Single Cell Experiment), loading the filtered contig file and then using createHTOContigList()
. This function will return a list separated by the group.by variable(s).
This function depends on the match of barcodes between the single-cell object and contigs. If there is a prefix or different suffix added to the barcode, this will result in no contigs recovered. Currently, it is recommended you do this step before the integration, as integration workflows commonly alter the barcodes. There is a multi.run variable that can be used on the integrated object. However, it assumes you have modified the barcodes with the Seurat pipeline (automatic addition of _# to end), and your contig list is in the same order.
contigs <- read.csv(".../outs/filtered_contig_annotations.csv")
contig.list <- createHTOContigList(contigs,
Seurat.Obj,
group.by = "HTO_maxID")
scRepertoire comes with a data set from T cells derived from four patients with acute respiratory distress to demonstrate the functionality of the R package. More information on the data set can be found in the corresponding manuscript. The samples consist of paired peripheral-blood (B) and bronchoalveolar lavage (L), effectively creating 8 distinct runs for T cell receptor (TCR) enrichment. We can preview the elements in the list by using the head function and looking at the first contig annotation.
The built-in example data is derived from the 10x Cell Ranger pipeline, so it is ready to go for downstream processing and analysis.
data("contig_list") #the data built into scRepertoire
head(contig_list[[1]])
## barcode is_cell contig_id high_confidence length
## 1 AAACCTGAGTACGACG-1 True AAACCTGAGTACGACG-1_contig_1 True 500
## 2 AAACCTGAGTACGACG-1 True AAACCTGAGTACGACG-1_contig_2 True 478
## 4 AAACCTGCAACACGCC-1 True AAACCTGCAACACGCC-1_contig_1 True 506
## 5 AAACCTGCAACACGCC-1 True AAACCTGCAACACGCC-1_contig_2 True 470
## 6 AAACCTGCAGGCGATA-1 True AAACCTGCAGGCGATA-1_contig_1 True 558
## 7 AAACCTGCAGGCGATA-1 True AAACCTGCAGGCGATA-1_contig_2 True 505
## chain v_gene d_gene j_gene c_gene full_length productive
## 1 TRA TRAV25 None TRAJ20 TRAC True True
## 2 TRB TRBV5-1 None TRBJ2-7 TRBC2 True True
## 4 TRA TRAV38-2/DV8 None TRAJ52 TRAC True True
## 5 TRB TRBV10-3 None TRBJ2-2 TRBC2 True True
## 6 TRA TRAV12-1 None TRAJ9 TRAC True True
## 7 TRB TRBV9 None TRBJ2-2 TRBC2 True True
## cdr3 cdr3_nt
## 1 CGCSNDYKLSF TGTGGGTGTTCTAACGACTACAAGCTCAGCTTT
## 2 CASSLTDRTYEQYF TGCGCCAGCAGCTTGACCGACAGGACCTACGAGCAGTACTTC
## 4 CAYRSAQAGGTSYGKLTF TGTGCTTATAGGAGCGCGCAGGCTGGTGGTACTAGCTATGGAAAGCTGACATTT
## 5 CAISEQGKGELFF TGTGCCATCAGTGAACAGGGGAAAGGGGAGCTGTTTTTT
## 6 CVVSDNTGGFKTIF TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT
## 7 CASSVRRERANTGELFF TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## reads umis raw_clonotype_id raw_consensus_id
## 1 8344 4 clonotype123 clonotype123_consensus_2
## 2 65390 38 clonotype123 clonotype123_consensus_1
## 4 18372 8 clonotype124 clonotype124_consensus_1
## 5 34054 9 clonotype124 clonotype124_consensus_2
## 6 5018 2 clonotype1 clonotype1_consensus_2
## 7 25110 11 clonotype1 clonotype1_consensus_1
input.data
loadContigs()
.samples and ID
removeNA
removeMulti
filterMulti
The output of combineTCR()
will be a list of contig data frames that will be reduced to the reads associated with a single cell barcode. It will also combine the multiple reads into clone calls by either the nucleotide sequence (CTnt), amino acid sequence (CTaa), the VDJC gene sequence (CTgene), or the combination of the nucleotide and gene sequence (CTstrict).
combined.TCR <- combineTCR(contig_list,
samples = c("P17B", "P17L", "P18B", "P18L",
"P19B","P19L", "P20B", "P20L"),
removeNA = FALSE,
removeMulti = FALSE,
filterMulti = FALSE)
head(combined.TCR[[1]])
## barcode sample TCR1 cdr3_aa1
## 1 P17B_AAACCTGAGTACGACG-1 P17B TRAV25.TRAJ20.TRAC CGCSNDYKLSF
## 3 P17B_AAACCTGCAACACGCC-1 P17B TRAV38-2/DV8.TRAJ52.TRAC CAYRSAQAGGTSYGKLTF
## 5 P17B_AAACCTGCAGGCGATA-1 P17B TRAV12-1.TRAJ9.TRAC CVVSDNTGGFKTIF
## 7 P17B_AAACCTGCATGAGCGA-1 P17B TRAV12-1.TRAJ9.TRAC CVVSDNTGGFKTIF
## 9 P17B_AAACGGGAGAGCCCAA-1 P17B TRAV20.TRAJ8.TRAC CAVRGEGFQKLVF
## 10 P17B_AAACGGGAGCGTTTAC-1 P17B TRAV12-1.TRAJ9.TRAC CVVSDNTGGFKTIF
## cdr3_nt1
## 1 TGTGGGTGTTCTAACGACTACAAGCTCAGCTTT
## 3 TGTGCTTATAGGAGCGCGCAGGCTGGTGGTACTAGCTATGGAAAGCTGACATTT
## 5 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT
## 7 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT
## 9 TGTGCTGTGCGAGGAGAAGGCTTTCAGAAACTTGTATTT
## 10 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT
## TCR2 cdr3_aa2
## 1 TRBV5-1.None.TRBJ2-7.TRBC2 CASSLTDRTYEQYF
## 3 TRBV10-3.None.TRBJ2-2.TRBC2 CAISEQGKGELFF
## 5 TRBV9.None.TRBJ2-2.TRBC2 CASSVRRERANTGELFF
## 7 TRBV9.None.TRBJ2-2.TRBC2 CASSVRRERANTGELFF
## 9 <NA> <NA>
## 10 TRBV9.None.TRBJ2-2.TRBC2 CASSVRRERANTGELFF
## cdr3_nt2
## 1 TGCGCCAGCAGCTTGACCGACAGGACCTACGAGCAGTACTTC
## 3 TGTGCCATCAGTGAACAGGGGAAAGGGGAGCTGTTTTTT
## 5 TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 7 TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 9 <NA>
## 10 TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## CTgene
## 1 TRAV25.TRAJ20.TRAC_TRBV5-1.None.TRBJ2-7.TRBC2
## 3 TRAV38-2/DV8.TRAJ52.TRAC_TRBV10-3.None.TRBJ2-2.TRBC2
## 5 TRAV12-1.TRAJ9.TRAC_TRBV9.None.TRBJ2-2.TRBC2
## 7 TRAV12-1.TRAJ9.TRAC_TRBV9.None.TRBJ2-2.TRBC2
## 9 TRAV20.TRAJ8.TRAC_NA
## 10 TRAV12-1.TRAJ9.TRAC_TRBV9.None.TRBJ2-2.TRBC2
## CTnt
## 1 TGTGGGTGTTCTAACGACTACAAGCTCAGCTTT_TGCGCCAGCAGCTTGACCGACAGGACCTACGAGCAGTACTTC
## 3 TGTGCTTATAGGAGCGCGCAGGCTGGTGGTACTAGCTATGGAAAGCTGACATTT_TGTGCCATCAGTGAACAGGGGAAAGGGGAGCTGTTTTTT
## 5 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 7 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 9 TGTGCTGTGCGAGGAGAAGGCTTTCAGAAACTTGTATTT_NA
## 10 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## CTaa
## 1 CGCSNDYKLSF_CASSLTDRTYEQYF
## 3 CAYRSAQAGGTSYGKLTF_CAISEQGKGELFF
## 5 CVVSDNTGGFKTIF_CASSVRRERANTGELFF
## 7 CVVSDNTGGFKTIF_CASSVRRERANTGELFF
## 9 CAVRGEGFQKLVF_NA
## 10 CVVSDNTGGFKTIF_CASSVRRERANTGELFF
## CTstrict
## 1 TRAV25.TRAJ20.TRAC;TGTGGGTGTTCTAACGACTACAAGCTCAGCTTT_TRBV5-1.None.TRBJ2-7.TRBC2;TGCGCCAGCAGCTTGACCGACAGGACCTACGAGCAGTACTTC
## 3 TRAV38-2/DV8.TRAJ52.TRAC;TGTGCTTATAGGAGCGCGCAGGCTGGTGGTACTAGCTATGGAAAGCTGACATTT_TRBV10-3.None.TRBJ2-2.TRBC2;TGTGCCATCAGTGAACAGGGGAAAGGGGAGCTGTTTTTT
## 5 TRAV12-1.TRAJ9.TRAC;TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TRBV9.None.TRBJ2-2.TRBC2;TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 7 TRAV12-1.TRAJ9.TRAC;TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TRBV9.None.TRBJ2-2.TRBC2;TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 9 TRAV20.TRAJ8.TRAC;TGTGCTGTGCGAGGAGAAGGCTTTCAGAAACTTGTATTT_NA;NA
## 10 TRAV12-1.TRAJ9.TRAC;TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TRBV9.None.TRBJ2-2.TRBC2;TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
combineBCR()
is analogous to combineTCR()
with 2 major changes: 1) Each barcode can only have a maximum of 2 sequences, if greater exists, the 2 with the highest reads are selected; 2) The strict definition of a clone is based on the normalized Levenshtein edit distance of CDR3 nucleotide sequences and V-gene usage. For more information on this approach, please see the respective citation. This definition allows for the grouping of BCRs derived from the same progenitor that have undergone mutation as part of somatic hypermutation and affinity maturation.
threshold
The level of similarity in sequences to group together. Default is 0.85.
\[ \text{threshold}(s, t) = 1-\frac{\text{Levenshtein}(s, t)}{\frac{\text{length}(s) + \text{length}(t)}{2}} \]
call.related.clones
Calculate the normalized edit distance (TRUE) or skip the calculation (FALSE). Skipping the edit distance calculation may save time, especially in the context of large data sets, but is not recommended.
BCR.contigs <- read.csv("https://www.borch.dev/uploads/contigs/b_contigs.csv")
combined.BCR <- combineBCR(BCR.contigs,
samples = "P1",
threshold = 0.85)
head(combined.BCR[[1]])
## barcode sample IGH
## 1 P1_CGAACATTCCCTTGTG-1 P1 <NA>
## 2 P1_CCTTCGAAGACGCTTT-1 P1 <NA>
## 3 P1_CAGCTAACAGCTTAAC-1 P1 <NA>
## 4 P1_CCCAATCAGAGGGCTT-1 P1 IGHV1-69-2.IGHD5-12.IGHJ6.IGHG1
## 5 P1_TACAGTGGTAAGGGCT-1 P1 IGHV1-18.IGHD3-10.IGHJ5.IGHA1
## 6 P1_GACAGAGGTTGGTAAA-1 P1 IGHV1-18.IGHD3-10.IGHJ5.IGHA1
## cdr3_aa1
## 1 <NA>
## 2 <NA>
## 3 <NA>
## 4 CASGGLVAIRHYYYYGMDVW
## 5 CARVTYHHGSGSLVGGWFDPW
## 6 CARVTYHHGSGSLVGGWFDPW
## cdr3_nt1
## 1 <NA>
## 2 <NA>
## 3 <NA>
## 4 TGTGCGAGCGGGGGATTAGTGGCTATTAGGCACTACTACTACTACGGTATGGACGTCTGG
## 5 TGTGCGAGAGTGACATATCACCATGGTTCGGGGAGCCTTGTCGGGGGCTGGTTCGACCCCTGG
## 6 TGTGCGAGAGTGACATATCACCATGGTTCGGGGAGCCTTGTCGGGGGCTGGTTCGACCCCTGG
## IGLC cdr3_aa2 cdr3_nt2
## 1 IGLV2-14.IGLJ6.IGLC2 CNSKGAGGTAVF TGCAACTCAAAAGGAGCCGGAGGCACTGCGGTTTTC
## 2 IGLV2-14.IGLJ6.IGLC2 CNSKGAGGTAVF TGCAACTCAAAAGGAGCCGGAGGCACTGCGGTTTTC
## 3 IGLV2-14.IGLJ2.IGLC2 CNSYTTSGTLWVF TGCAACTCATACACAACCAGCGGCACTCTCTGGGTATTC
## 4 IGLV2-14.IGLJ2.IGLC2 CNSYTSSSTLVF TGCAACTCATATACAAGCAGCAGCACTCTGGTCTTC
## 5 IGLV2-14.IGLJ1.IGLC1 CNSYTSFGTSVF TGCAACTCATATACAAGCTTCGGCACCTCGGTCTTC
## 6 IGLV2-14.IGLJ1.IGLC1 CNSYTSFGTSVF TGCAACTCATATACAAGCTTCGGCACCTCGGTCTTC
## CTgene
## 1 NA_IGLV2-14.IGLJ6.IGLC2
## 2 NA_IGLV2-14.IGLJ6.IGLC2
## 3 NA_IGLV2-14.IGLJ2.IGLC2
## 4 IGHV1-69-2.IGHD5-12.IGHJ6.IGHG1_IGLV2-14.IGLJ2.IGLC2
## 5 IGHV1-18.IGHD3-10.IGHJ5.IGHA1_IGLV2-14.IGLJ1.IGLC1
## 6 IGHV1-18.IGHD3-10.IGHJ5.IGHA1_IGLV2-14.IGLJ1.IGLC1
## CTnt
## 1 NA_TGCAACTCAAAAGGAGCCGGAGGCACTGCGGTTTTC
## 2 NA_TGCAACTCAAAAGGAGCCGGAGGCACTGCGGTTTTC
## 3 NA_TGCAACTCATACACAACCAGCGGCACTCTCTGGGTATTC
## 4 TGTGCGAGCGGGGGATTAGTGGCTATTAGGCACTACTACTACTACGGTATGGACGTCTGG_TGCAACTCATATACAAGCAGCAGCACTCTGGTCTTC
## 5 TGTGCGAGAGTGACATATCACCATGGTTCGGGGAGCCTTGTCGGGGGCTGGTTCGACCCCTGG_TGCAACTCATATACAAGCTTCGGCACCTCGGTCTTC
## 6 TGTGCGAGAGTGACATATCACCATGGTTCGGGGAGCCTTGTCGGGGGCTGGTTCGACCCCTGG_TGCAACTCATATACAAGCTTCGGCACCTCGGTCTTC
## CTaa
## 1 NA_CNSKGAGGTAVF
## 2 NA_CNSKGAGGTAVF
## 3 NA_CNSYTTSGTLWVF
## 4 CASGGLVAIRHYYYYGMDVW_CNSYTSSSTLVF
## 5 CARVTYHHGSGSLVGGWFDPW_CNSYTSFGTSVF
## 6 CARVTYHHGSGSLVGGWFDPW_CNSYTSFGTSVF
## CTstrict
## 1 NA.NA_IGLC.549.IGLV2-14
## 2 NA.NA_IGLC.549.IGLV2-14
## 3 NA.NA_IGLC.535.IGLV2-14
## 4 IGH.481.IGHV1-69-2_IGLC:Cluster.56.IGLV2-14
## 5 IGH.781.IGHV1-18_IGLC:Cluster.56.IGLV2-14
## 6 IGH.781.IGHV1-18_IGLC:Cluster.56.IGLV2-14
What if there are more variables to add than just sample and ID? We can add them by using the addVariable()
function. All we need is the variable.name of the variable you’d like to add and the specific character or numeric values (variables). As an example, here we add the Type in which the samples were processed and sequenced.
combined.TCR <- addVariable(combined.TCR,
variable.name = "Type",
variables = rep(c("B", "L"), 4))
head(combined.TCR[[1]])
## barcode sample TCR1 cdr3_aa1
## 1 P17B_AAACCTGAGTACGACG-1 P17B TRAV25.TRAJ20.TRAC CGCSNDYKLSF
## 3 P17B_AAACCTGCAACACGCC-1 P17B TRAV38-2/DV8.TRAJ52.TRAC CAYRSAQAGGTSYGKLTF
## 5 P17B_AAACCTGCAGGCGATA-1 P17B TRAV12-1.TRAJ9.TRAC CVVSDNTGGFKTIF
## 7 P17B_AAACCTGCATGAGCGA-1 P17B TRAV12-1.TRAJ9.TRAC CVVSDNTGGFKTIF
## 9 P17B_AAACGGGAGAGCCCAA-1 P17B TRAV20.TRAJ8.TRAC CAVRGEGFQKLVF
## 10 P17B_AAACGGGAGCGTTTAC-1 P17B TRAV12-1.TRAJ9.TRAC CVVSDNTGGFKTIF
## cdr3_nt1
## 1 TGTGGGTGTTCTAACGACTACAAGCTCAGCTTT
## 3 TGTGCTTATAGGAGCGCGCAGGCTGGTGGTACTAGCTATGGAAAGCTGACATTT
## 5 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT
## 7 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT
## 9 TGTGCTGTGCGAGGAGAAGGCTTTCAGAAACTTGTATTT
## 10 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT
## TCR2 cdr3_aa2
## 1 TRBV5-1.None.TRBJ2-7.TRBC2 CASSLTDRTYEQYF
## 3 TRBV10-3.None.TRBJ2-2.TRBC2 CAISEQGKGELFF
## 5 TRBV9.None.TRBJ2-2.TRBC2 CASSVRRERANTGELFF
## 7 TRBV9.None.TRBJ2-2.TRBC2 CASSVRRERANTGELFF
## 9 <NA> <NA>
## 10 TRBV9.None.TRBJ2-2.TRBC2 CASSVRRERANTGELFF
## cdr3_nt2
## 1 TGCGCCAGCAGCTTGACCGACAGGACCTACGAGCAGTACTTC
## 3 TGTGCCATCAGTGAACAGGGGAAAGGGGAGCTGTTTTTT
## 5 TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 7 TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 9 <NA>
## 10 TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## CTgene
## 1 TRAV25.TRAJ20.TRAC_TRBV5-1.None.TRBJ2-7.TRBC2
## 3 TRAV38-2/DV8.TRAJ52.TRAC_TRBV10-3.None.TRBJ2-2.TRBC2
## 5 TRAV12-1.TRAJ9.TRAC_TRBV9.None.TRBJ2-2.TRBC2
## 7 TRAV12-1.TRAJ9.TRAC_TRBV9.None.TRBJ2-2.TRBC2
## 9 TRAV20.TRAJ8.TRAC_NA
## 10 TRAV12-1.TRAJ9.TRAC_TRBV9.None.TRBJ2-2.TRBC2
## CTnt
## 1 TGTGGGTGTTCTAACGACTACAAGCTCAGCTTT_TGCGCCAGCAGCTTGACCGACAGGACCTACGAGCAGTACTTC
## 3 TGTGCTTATAGGAGCGCGCAGGCTGGTGGTACTAGCTATGGAAAGCTGACATTT_TGTGCCATCAGTGAACAGGGGAAAGGGGAGCTGTTTTTT
## 5 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 7 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 9 TGTGCTGTGCGAGGAGAAGGCTTTCAGAAACTTGTATTT_NA
## 10 TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## CTaa
## 1 CGCSNDYKLSF_CASSLTDRTYEQYF
## 3 CAYRSAQAGGTSYGKLTF_CAISEQGKGELFF
## 5 CVVSDNTGGFKTIF_CASSVRRERANTGELFF
## 7 CVVSDNTGGFKTIF_CASSVRRERANTGELFF
## 9 CAVRGEGFQKLVF_NA
## 10 CVVSDNTGGFKTIF_CASSVRRERANTGELFF
## CTstrict
## 1 TRAV25.TRAJ20.TRAC;TGTGGGTGTTCTAACGACTACAAGCTCAGCTTT_TRBV5-1.None.TRBJ2-7.TRBC2;TGCGCCAGCAGCTTGACCGACAGGACCTACGAGCAGTACTTC
## 3 TRAV38-2/DV8.TRAJ52.TRAC;TGTGCTTATAGGAGCGCGCAGGCTGGTGGTACTAGCTATGGAAAGCTGACATTT_TRBV10-3.None.TRBJ2-2.TRBC2;TGTGCCATCAGTGAACAGGGGAAAGGGGAGCTGTTTTTT
## 5 TRAV12-1.TRAJ9.TRAC;TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TRBV9.None.TRBJ2-2.TRBC2;TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 7 TRAV12-1.TRAJ9.TRAC;TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TRBV9.None.TRBJ2-2.TRBC2;TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## 9 TRAV20.TRAJ8.TRAC;TGTGCTGTGCGAGGAGAAGGCTTTCAGAAACTTGTATTT_NA;NA
## 10 TRAV12-1.TRAJ9.TRAC;TGTGTGGTCTCCGATAATACTGGAGGCTTCAAAACTATCTTT_TRBV9.None.TRBJ2-2.TRBC2;TGTGCCAGCAGCGTAAGGAGGGAAAGGGCGAACACCGGGGAGCTGTTTTTT
## Type
## 1 B
## 3 B
## 5 B
## 7 B
## 9 B
## 10 B
Likewise, we can remove specific list elements after combineTCR()
using the subsetClones()
function. In order to subset, we need to identify the vector we would like to use for subsetting (name) and the variable values to subset (variables). Below, we isolate just the 2 sequencing results from P18L and P18B.
subset1 <- subsetClones(combined.TCR,
name = "sample",
variables = c("P18L", "P18B"))
head(subset1[[1]])
## barcode sample TCR1 cdr3_aa1
## 1 P18B_AAACCTGAGGCTCAGA-1 P18B TRAV26-1.TRAJ37.TRAC CIVRGGSSNTGKLIF
## 3 P18B_AAACCTGCATGACATC-1 P18B TRAV3.TRAJ20.TRAC CAVQRSNDYKLSF
## 5 P18B_AAACCTGGTATGCTTG-1 P18B TRAV26-1.TRAJ53.TRAC CIGSSGGSNYKLTF
## 8 P18B_AAACGGGCAGATGGGT-1 P18B <NA> <NA>
## 9 P18B_AAACGGGTCTTACCGC-1 P18B TRAV20.TRAJ9.TRAC CAVQAKRYTGGFKTIF
## 12 P18B_AAAGATGAGTTACGGG-1 P18B TRAV8-3.TRAJ8.TRAC CAVGGDTGFQKLVF
## cdr3_nt1
## 1 TGCATCGTCAGGGGCGGCTCTAGCAACACAGGCAAACTAATCTTT
## 3 TGTGCTGTGCAACGTTCTAACGACTACAAGCTCAGCTTT
## 5 TGCATCGGCTCAAGTGGAGGTAGCAACTATAAACTGACATTT
## 8 <NA>
## 9 TGTGCTGTGCAGGCCAAGCGGTATACTGGAGGCTTCAAAACTATCTTT
## 12 TGTGCTGTGGGTGGTGACACAGGCTTTCAGAAACTTGTATTT
## TCR2
## 1 TRBV6-1.None.TRBJ2-3.TRBC2
## 3 TRBV3-1.None.TRBJ2-3.TRBC2
## 5 TRBV4-1.None.TRBJ2-2.TRBC2;TRBV19.None.TRBJ1-5.TRBC1
## 8 TRBV5-1.None.TRBJ1-2.TRBC1
## 9 TRBV5-1.None.TRBJ1-1.TRBC1;TRBV7-9.None.TRBJ2-2.TRBC2
## 12 TRBV12-4.None.TRBJ1-1.TRBC1
## cdr3_aa2
## 1 CASIGRSFGRDTQYF
## 3 CASSPPRGGFTDTQYF
## 5 CASSQGGQGGRELFF;CASSYAVGRQPQHF
## 8 CASSLRETNYGYTF
## 9 CASSLGTGTGVEAFF;CAIDPGLLTGELFF
## 12 CASRNSQATEAFF
## cdr3_nt2
## 1 TGTGCCAGTATCGGGAGGTCCTTTGGCCGAGATACGCAGTATTTT
## 3 TGTGCCAGCAGCCCCCCCCGCGGCGGATTCACAGATACGCAGTATTTT
## 5 TGCGCCAGCAGCCAAGGTGGACAGGGCGGAAGGGAGCTGTTTTTT;TGTGCCAGTAGCTACGCGGTGGGGAGGCAGCCCCAGCATTTT
## 8 TGCGCCAGCAGCTTGAGGGAAACCAACTATGGCTACACCTTC
## 9 TGCGCCAGCAGCTTGGGAACGGGGACAGGGGTTGAAGCTTTCTTT;TGTGCCATCGATCCGGGACTACTCACCGGGGAGCTGTTTTTT
## 12 TGTGCCAGCAGAAACTCCCAAGCCACTGAAGCTTTCTTT
## CTgene
## 1 TRAV26-1.TRAJ37.TRAC_TRBV6-1.None.TRBJ2-3.TRBC2
## 3 TRAV3.TRAJ20.TRAC_TRBV3-1.None.TRBJ2-3.TRBC2
## 5 TRAV26-1.TRAJ53.TRAC_TRBV4-1.None.TRBJ2-2.TRBC2;TRBV19.None.TRBJ1-5.TRBC1
## 8 NA_TRBV5-1.None.TRBJ1-2.TRBC1
## 9 TRAV20.TRAJ9.TRAC_TRBV5-1.None.TRBJ1-1.TRBC1;TRBV7-9.None.TRBJ2-2.TRBC2
## 12 TRAV8-3.TRAJ8.TRAC_TRBV12-4.None.TRBJ1-1.TRBC1
## CTnt
## 1 TGCATCGTCAGGGGCGGCTCTAGCAACACAGGCAAACTAATCTTT_TGTGCCAGTATCGGGAGGTCCTTTGGCCGAGATACGCAGTATTTT
## 3 TGTGCTGTGCAACGTTCTAACGACTACAAGCTCAGCTTT_TGTGCCAGCAGCCCCCCCCGCGGCGGATTCACAGATACGCAGTATTTT
## 5 TGCATCGGCTCAAGTGGAGGTAGCAACTATAAACTGACATTT_TGCGCCAGCAGCCAAGGTGGACAGGGCGGAAGGGAGCTGTTTTTT;TGTGCCAGTAGCTACGCGGTGGGGAGGCAGCCCCAGCATTTT
## 8 NA_TGCGCCAGCAGCTTGAGGGAAACCAACTATGGCTACACCTTC
## 9 TGTGCTGTGCAGGCCAAGCGGTATACTGGAGGCTTCAAAACTATCTTT_TGCGCCAGCAGCTTGGGAACGGGGACAGGGGTTGAAGCTTTCTTT;TGTGCCATCGATCCGGGACTACTCACCGGGGAGCTGTTTTTT
## 12 TGTGCTGTGGGTGGTGACACAGGCTTTCAGAAACTTGTATTT_TGTGCCAGCAGAAACTCCCAAGCCACTGAAGCTTTCTTT
## CTaa
## 1 CIVRGGSSNTGKLIF_CASIGRSFGRDTQYF
## 3 CAVQRSNDYKLSF_CASSPPRGGFTDTQYF
## 5 CIGSSGGSNYKLTF_CASSQGGQGGRELFF;CASSYAVGRQPQHF
## 8 NA_CASSLRETNYGYTF
## 9 CAVQAKRYTGGFKTIF_CASSLGTGTGVEAFF;CAIDPGLLTGELFF
## 12 CAVGGDTGFQKLVF_CASRNSQATEAFF
## CTstrict
## 1 TRAV26-1.TRAJ37.TRAC;TGCATCGTCAGGGGCGGCTCTAGCAACACAGGCAAACTAATCTTT_TRBV6-1.None.TRBJ2-3.TRBC2;TGTGCCAGTATCGGGAGGTCCTTTGGCCGAGATACGCAGTATTTT
## 3 TRAV3.TRAJ20.TRAC;TGTGCTGTGCAACGTTCTAACGACTACAAGCTCAGCTTT_TRBV3-1.None.TRBJ2-3.TRBC2;TGTGCCAGCAGCCCCCCCCGCGGCGGATTCACAGATACGCAGTATTTT
## 5 TRAV26-1.TRAJ53.TRAC;TGCATCGGCTCAAGTGGAGGTAGCAACTATAAACTGACATTT_TRBV4-1.None.TRBJ2-2.TRBC2;TRBV19.None.TRBJ1-5.TRBC1;TGCGCCAGCAGCCAAGGTGGACAGGGCGGAAGGGAGCTGTTTTTT;TGTGCCAGTAGCTACGCGGTGGGGAGGCAGCCCCAGCATTTT
## 8 NA;NA_TRBV5-1.None.TRBJ1-2.TRBC1;TGCGCCAGCAGCTTGAGGGAAACCAACTATGGCTACACCTTC
## 9 TRAV20.TRAJ9.TRAC;TGTGCTGTGCAGGCCAAGCGGTATACTGGAGGCTTCAAAACTATCTTT_TRBV5-1.None.TRBJ1-1.TRBC1;TRBV7-9.None.TRBJ2-2.TRBC2;TGCGCCAGCAGCTTGGGAACGGGGACAGGGGTTGAAGCTTTCTTT;TGTGCCATCGATCCGGGACTACTCACCGGGGAGCTGTTTTTT
## 12 TRAV8-3.TRAJ8.TRAC;TGTGCTGTGGGTGGTGACACAGGCTTTCAGAAACTTGTATTT_TRBV12-4.None.TRBJ1-1.TRBC1;TGTGCCAGCAGAAACTCCCAAGCCACTGAAGCTTTCTTT
## Type
## 1 B
## 3 B
## 5 B
## 8 B
## 9 B
## 12 B
Alternatively, we can also just select the list elements after combineTCR()
or combineBCR()
.
subset2 <- combined.TCR[c(3,4)]
head(subset2[[1]])
## barcode sample TCR1 cdr3_aa1
## 1 P18B_AAACCTGAGGCTCAGA-1 P18B TRAV26-1.TRAJ37.TRAC CIVRGGSSNTGKLIF
## 3 P18B_AAACCTGCATGACATC-1 P18B TRAV3.TRAJ20.TRAC CAVQRSNDYKLSF
## 5 P18B_AAACCTGGTATGCTTG-1 P18B TRAV26-1.TRAJ53.TRAC CIGSSGGSNYKLTF
## 8 P18B_AAACGGGCAGATGGGT-1 P18B <NA> <NA>
## 9 P18B_AAACGGGTCTTACCGC-1 P18B TRAV20.TRAJ9.TRAC CAVQAKRYTGGFKTIF
## 12 P18B_AAAGATGAGTTACGGG-1 P18B TRAV8-3.TRAJ8.TRAC CAVGGDTGFQKLVF
## cdr3_nt1
## 1 TGCATCGTCAGGGGCGGCTCTAGCAACACAGGCAAACTAATCTTT
## 3 TGTGCTGTGCAACGTTCTAACGACTACAAGCTCAGCTTT
## 5 TGCATCGGCTCAAGTGGAGGTAGCAACTATAAACTGACATTT
## 8 <NA>
## 9 TGTGCTGTGCAGGCCAAGCGGTATACTGGAGGCTTCAAAACTATCTTT
## 12 TGTGCTGTGGGTGGTGACACAGGCTTTCAGAAACTTGTATTT
## TCR2
## 1 TRBV6-1.None.TRBJ2-3.TRBC2
## 3 TRBV3-1.None.TRBJ2-3.TRBC2
## 5 TRBV4-1.None.TRBJ2-2.TRBC2;TRBV19.None.TRBJ1-5.TRBC1
## 8 TRBV5-1.None.TRBJ1-2.TRBC1
## 9 TRBV5-1.None.TRBJ1-1.TRBC1;TRBV7-9.None.TRBJ2-2.TRBC2
## 12 TRBV12-4.None.TRBJ1-1.TRBC1
## cdr3_aa2
## 1 CASIGRSFGRDTQYF
## 3 CASSPPRGGFTDTQYF
## 5 CASSQGGQGGRELFF;CASSYAVGRQPQHF
## 8 CASSLRETNYGYTF
## 9 CASSLGTGTGVEAFF;CAIDPGLLTGELFF
## 12 CASRNSQATEAFF
## cdr3_nt2
## 1 TGTGCCAGTATCGGGAGGTCCTTTGGCCGAGATACGCAGTATTTT
## 3 TGTGCCAGCAGCCCCCCCCGCGGCGGATTCACAGATACGCAGTATTTT
## 5 TGCGCCAGCAGCCAAGGTGGACAGGGCGGAAGGGAGCTGTTTTTT;TGTGCCAGTAGCTACGCGGTGGGGAGGCAGCCCCAGCATTTT
## 8 TGCGCCAGCAGCTTGAGGGAAACCAACTATGGCTACACCTTC
## 9 TGCGCCAGCAGCTTGGGAACGGGGACAGGGGTTGAAGCTTTCTTT;TGTGCCATCGATCCGGGACTACTCACCGGGGAGCTGTTTTTT
## 12 TGTGCCAGCAGAAACTCCCAAGCCACTGAAGCTTTCTTT
## CTgene
## 1 TRAV26-1.TRAJ37.TRAC_TRBV6-1.None.TRBJ2-3.TRBC2
## 3 TRAV3.TRAJ20.TRAC_TRBV3-1.None.TRBJ2-3.TRBC2
## 5 TRAV26-1.TRAJ53.TRAC_TRBV4-1.None.TRBJ2-2.TRBC2;TRBV19.None.TRBJ1-5.TRBC1
## 8 NA_TRBV5-1.None.TRBJ1-2.TRBC1
## 9 TRAV20.TRAJ9.TRAC_TRBV5-1.None.TRBJ1-1.TRBC1;TRBV7-9.None.TRBJ2-2.TRBC2
## 12 TRAV8-3.TRAJ8.TRAC_TRBV12-4.None.TRBJ1-1.TRBC1
## CTnt
## 1 TGCATCGTCAGGGGCGGCTCTAGCAACACAGGCAAACTAATCTTT_TGTGCCAGTATCGGGAGGTCCTTTGGCCGAGATACGCAGTATTTT
## 3 TGTGCTGTGCAACGTTCTAACGACTACAAGCTCAGCTTT_TGTGCCAGCAGCCCCCCCCGCGGCGGATTCACAGATACGCAGTATTTT
## 5 TGCATCGGCTCAAGTGGAGGTAGCAACTATAAACTGACATTT_TGCGCCAGCAGCCAAGGTGGACAGGGCGGAAGGGAGCTGTTTTTT;TGTGCCAGTAGCTACGCGGTGGGGAGGCAGCCCCAGCATTTT
## 8 NA_TGCGCCAGCAGCTTGAGGGAAACCAACTATGGCTACACCTTC
## 9 TGTGCTGTGCAGGCCAAGCGGTATACTGGAGGCTTCAAAACTATCTTT_TGCGCCAGCAGCTTGGGAACGGGGACAGGGGTTGAAGCTTTCTTT;TGTGCCATCGATCCGGGACTACTCACCGGGGAGCTGTTTTTT
## 12 TGTGCTGTGGGTGGTGACACAGGCTTTCAGAAACTTGTATTT_TGTGCCAGCAGAAACTCCCAAGCCACTGAAGCTTTCTTT
## CTaa
## 1 CIVRGGSSNTGKLIF_CASIGRSFGRDTQYF
## 3 CAVQRSNDYKLSF_CASSPPRGGFTDTQYF
## 5 CIGSSGGSNYKLTF_CASSQGGQGGRELFF;CASSYAVGRQPQHF
## 8 NA_CASSLRETNYGYTF
## 9 CAVQAKRYTGGFKTIF_CASSLGTGTGVEAFF;CAIDPGLLTGELFF
## 12 CAVGGDTGFQKLVF_CASRNSQATEAFF
## CTstrict
## 1 TRAV26-1.TRAJ37.TRAC;TGCATCGTCAGGGGCGGCTCTAGCAACACAGGCAAACTAATCTTT_TRBV6-1.None.TRBJ2-3.TRBC2;TGTGCCAGTATCGGGAGGTCCTTTGGCCGAGATACGCAGTATTTT
## 3 TRAV3.TRAJ20.TRAC;TGTGCTGTGCAACGTTCTAACGACTACAAGCTCAGCTTT_TRBV3-1.None.TRBJ2-3.TRBC2;TGTGCCAGCAGCCCCCCCCGCGGCGGATTCACAGATACGCAGTATTTT
## 5 TRAV26-1.TRAJ53.TRAC;TGCATCGGCTCAAGTGGAGGTAGCAACTATAAACTGACATTT_TRBV4-1.None.TRBJ2-2.TRBC2;TRBV19.None.TRBJ1-5.TRBC1;TGCGCCAGCAGCCAAGGTGGACAGGGCGGAAGGGAGCTGTTTTTT;TGTGCCAGTAGCTACGCGGTGGGGAGGCAGCCCCAGCATTTT
## 8 NA;NA_TRBV5-1.None.TRBJ1-2.TRBC1;TGCGCCAGCAGCTTGAGGGAAACCAACTATGGCTACACCTTC
## 9 TRAV20.TRAJ9.TRAC;TGTGCTGTGCAGGCCAAGCGGTATACTGGAGGCTTCAAAACTATCTTT_TRBV5-1.None.TRBJ1-1.TRBC1;TRBV7-9.None.TRBJ2-2.TRBC2;TGCGCCAGCAGCTTGGGAACGGGGACAGGGGTTGAAGCTTTCTTT;TGTGCCATCGATCCGGGACTACTCACCGGGGAGCTGTTTTTT
## 12 TRAV8-3.TRAJ8.TRAC;TGTGCTGTGGGTGGTGACACAGGCTTTCAGAAACTTGTATTT_TRBV12-4.None.TRBJ1-1.TRBC1;TGTGCCAGCAGAAACTCCCAAGCCACTGAAGCTTTCTTT
## Type
## 1 B
## 3 B
## 5 B
## 8 B
## 9 B
## 12 B
After assigning the clone by barcode, we can export the paired clonotypes using exportClones()
to save for later use or to use in other pipelines.
format
write.file
dir
directory location to save the csv
file.name
the csv file name
exportClones(combined,
write.file = TRUE,
dir = "~/Documents/MyExperiment/Sample1/"
file.name = "clones.csv"
cloneCall
* “gene” - use the VDJC genes comprising the TCR/Ig
* “nt” - use the nucleotide sequence of the CDR3 region
* “aa” - use the amino acid sequence of the CDR3 region
* “strict” - use the VDJC genes comprising the TCR + the nucleotide sequence of the CDR3 region. This is the proper definition of clonotype. For combineBCR()
strict refers to the edit distance clusters + Vgene of the Ig.
It is important to note that the clonotype is called using essentially the combination of genes or nt/aa CDR3 sequences for both loci. As of this implementation of scRepertoire, clonotype calling is not incorporating small variations within the CDR3 sequences. As such the gene approach will be the most sensitive, while the use of nt or aa is moderately so, and the most specific for clonotypes being strict. Additionally, the clonotype call is trying to incorporate both loci, i.e., both TCRA and TCRB chains and if a single cell barcode has multiple sequences identified (i.e., 2 TCRA chains expressed in one cell). Using the 10x approach, there is a subset of barcodes that only return one of the immune receptor chains. The unreturned chain is assigned an NA value.
The first function to explore the clones is clonalQuant()
to return the total or relative numbers of unique clones.
scale
chain
clonalQuant(combined.TCR,
cloneCall="strict",
chain = "both",
scale = TRUE)
Another option here is to be able to define the visualization by data classes. Here, we used the combineTCR()
list to define the Type variable as part of the naming structure. We can use the group.by to specifically use a column in the data set to organize the visualization.
clonalQuant(combined.TCR,
cloneCall="gene",
group.by = "Type",
scale = TRUE)
We can also examine the relative distribution of clones by abundance. Here clonalAbundance()
will produce a line graph with a total number of clones by the number of instances within the sample or run. Like above, we can also group.by this by vectors within the contig object using the group.by variable in the function.
clonalAbundance(combined.TCR,
cloneCall = "gene",
scale = FALSE)
clonalAbundance()
output can also be converted into a density plot, which may allow for better comparisons between different repertoire sizes, by setting scale = TRUE.
clonalAbundance(combined.TCR,
cloneCall = "gene",
scale = TRUE)
We can look at the length distribution of the CDR3 sequences by calling the lengtheContig()
function. Importantly, unlike the other basic visualizations, the cloneCall can only be “nt” or “aa”. Due to the method of calling clones as outlined above, the length should reveal a multimodal curve, this is a product of using the NA for the unreturned chain sequence and multiple chains within a single barcode.
chain
clonalLength(combined.TCR,
cloneCall="aa",
chain = "both")
clonalLength(combined.TCR,
cloneCall="aa",
chain = "TRA",
scale = TRUE)
We can also look at clones between samples and changes in dynamics by using the clonalCompare()
function.
samples
graph
top.clones
clones
highlight.clones
relabel.clones
clonalCompare(combined.TCR,
top.clones = 10,
samples = c("P17B", "P17L"),
cloneCall="aa",
graph = "alluvial")
We can also choose to highlight specific clones, such as in the case of “CVVSDNTGGFKTIF_CASSVRRERANTGELFF” and “NA_CASSVRRERANTGELFF” using the highlight.clones parameter. In addition, we can simplify the plot to label the clones as clones 1:19.
clonalCompare(combined.TCR,
top.clones = 10,
highlight.clones = c("CVVSDNTGGFKTIF_CASSVRRERANTGELFF", "NA_CASSVRRERANTGELFF"),
relabel.clones = TRUE,
samples = c("P17B", "P17L"),
cloneCall="aa",
graph = "alluvial")
Alternatively, if we only want to show specific clones, we can use the clones parameter.
clonalCompare(combined.TCR,
clones = c("CVVSDNTGGFKTIF_CASSVRRERANTGELFF", "NA_CASSVRRERANTGELFF"),
relabel.clones = TRUE,
samples = c("P17B", "P17L"),
cloneCall="aa",
graph = "alluvial")
clonalScatter()
will organize two repertoires, quantify the relative clone sizes, and produce a scatter plot comparing the two samples.
x.axis and y.axis
dot.size
graph
clonalScatter(combined.TCR,
cloneCall ="gene",
x.axis = "P18B",
y.axis = "P18L",
dot.size = "total",
graph = "proportion")
By examining the clonal space, we effectively look at the relative space occupied by clones at specific proportions. Another way to think about this would be to think of the total immune receptor sequencing run as a measuring cup. In this cup, we will fill liquids of different viscosity - or different numbers of clonal proportions. Clonal space homeostasis asks what percentage of the cup is filled by clones in distinct proportions (or liquids of different viscosity, to extend the analogy). The proportional cut points are set under the cloneSize variable in the function and can be adjusted.
cloneSize
clonalHomeostasis(combined.TCR,
cloneCall = "gene")
We can reassign the proportional cut points for cloneSize, which can drastically alter the visualization and analysis.
clonalHomeostasis(combined.TCR,
cloneCall = "gene",
cloneSize = c(Rare = 0.001, Small = 0.01, Medium = 0.1, Large = 0.3, Hyperexpanded =
1))
In addition, we can use the group.by parameter to look at the relative proportion of clones between groups - such as tissue.
combined.TCR <- addVariable(combined.TCR,
variable.name = "Type",
variables = rep(c("B", "L"), 4))
clonalHomeostasis(combined.TCR,
group.by = "Type",
cloneCall = "gene")
Like clonal space homeostasis above, clonal proportion places clones into separate bins. The key difference is that instead of looking at the relative proportion of the clone to the total, the clonalProportion()
function will rank the clones by total number and place them into bins.
The clonalSplit represents the ranking of clonotypes by copy or frequency of occurrence, meaning 1:10 are the top 10 clonotypes in each sample. The default bins are under the clonalSplit variable in the function and can be adjusted, but they are as follows at baseline.
clonalSplit
clonalProportion(combined.TCR,
cloneCall = "gene")
clonalProportion(combined.TCR,
cloneCall = "nt",
clonalSplit = c(1, 5, 10, 100, 1000, 10000))
A visualization of the relative usage of genes of the TCR or BCR, using vizGenes()
. There is some functional crossover between vizGenes()
and two functions below called percentGenes()
and percentVJ()
. But vizGenes()
is more adaptable to allow for comparisons across chains, scaling, etc.
x.axis
y.axis
plot
scale
order
vizGenes(combined.TCR,
x.axis = "TRBV",
y.axis = NULL,
plot = "barplot",
scale = TRUE)
vizGenes()
can also be used to look at the usage of genes in a single chain. For example, say we are interested in the difference in TRB V and J usage between lung and peripheral blood samples - we can easily take a look at this using the following code:
#Peripheral Blood
vizGenes(combined.TCR[c(1,3,5,7)],
x.axis = "TRBV",
y.axis = "TRBJ",
plot = "heatmap",
scale = TRUE)
#Lung
vizGenes(combined.TCR[c(2,4,6,8)],
x.axis = "TRBV",
y.axis = "TRBJ",
plot = "heatmap",
scale = TRUE)
For the P17 patient samples, what if we are interested in chain pairings, we can look at TRBV and TRAV at the same time using them as inputs to x.axis and y.axis.
vizGenes(combined.TCR[c(1,2)],
x.axis = "TRBV",
y.axis = "TRAV",
plot = "heatmap",
scale = FALSE)
Quantify the proportion of amino acids along the cdr3 sequence with percentAA()
. By default, the function will pad the sequences with NAs up to the maximum of aa.length. Sequences longer than aa.length will be removed before visualization (default aa.length = 20).
percentAA(combined.TCR,
chain = "TRB",
aa.length = 20)
We can also quantify the level of entropy/diversity across amino acid residues along the cdr3 sequence. positionalEntropy()
combines the quantification by residue of percentAA()
with the diversity calls in clonalDiversity()
. Importantly, because diversity can be affected by size of sample, similar to clonalDiversity()
, positionalEntropy()
will also downsample/bootstrap the calculation. Positions without variance will have a value reported as 0 for the purposes of comparison.
method
positionalEntropy(combined.TCR,
chain = "TRB",
aa.length = 20)
Quantify the proportion of V or J gene usage with percentGenes()
. Like percentAA()
, we select the chain of interest and then indicate the gene of interest with the gene parameter. Two major limitations of percentGenes()
are, 1) the function quantifies only V or J genes, and 2) the quantification of the genes are limited to all the V or J genes seen across the samples, not all possible V or J genes.
percentGenes(combined.TCR,
chain = "TRB",
gene = "Vgene")
We can also use the output percentGenes()
for dimensional reduction to summarise the gene usage by sample. This can be done with a simple principal component analysis (below) or even more complex reductions.
df.genes <- percentGenes(combined.TCR,
chain = "TRB",
gene = "Vgene",
exportTable = TRUE)
#Performing PCA
pc <- prcomp(df.genes)
#Getting data frame to plot from
df <- as.data.frame(cbind(pc$x[,1:2], rownames(df.genes)))
df$PC1 <- as.numeric(df$PC1)
df$PC2 <- as.numeric(df$PC2)
#Plotting
ggplot(df, aes(x = PC1, y = PC2)) +
geom_point(aes(fill =df[,3]), shape = 21, size = 5) +
guides(fill=guide_legend(title="Samples")) +
scale_fill_manual(values = hcl.colors(nrow(df), "inferno")) +
theme_classic()
Quantify the proportion of V and J gene usage with percentVJ()
. Like percentGenes()
, this function will quantify the percentage of V and J paired together across individual repertoires. The output can be visualized using a heatmap or as input for further dimensional reduction.
percentVJ(combined.TCR,
chain = "TRB")
df.genes <- percentVJ(combined.TCR,
chain = "TRB",
exportTable = TRUE)
#Performing PCA
pc <- prcomp(df.genes)
#Getting data frame to plot from
df <- as.data.frame(cbind(pc$x[,1:2], rownames(df.genes)))
df$PC1 <- as.numeric(df$PC1)
df$PC2 <- as.numeric(df$PC2)
#Plotting
ggplot(df, aes(x = PC1, y = PC2)) +
geom_point(aes(fill =df[,3]), shape = 21, size = 5) +
guides(fill=guide_legend(title="Samples")) +
scale_fill_manual(values = hcl.colors(nrow(df), "inferno")) +
theme_classic()
Another quantification of the composition of the CDR3 sequence is to define motifs by sliding across the amino acid or nucleotide sequences at set intervals resulting in substrings or kmers.
motif.length
top.motifs
percentKmer(combined.TCR,
cloneCall = "aa",
chain = "TRB",
motif.length = 3,
top.motifs = 25)
percentKmer(combined.TCR,
cloneCall = "nt",
chain = "TRB",
motif.length = 3,
top.motifs = 25)
Diversity can also be measured for samples or by other variables. Diversity metrics calculated, include: “shannon”, “inv.simpson”, “norm.entropy”, “gini.simpson”, “chao1”, and “ACE”. Please see the manual for more information on each metric and the underlying calculations.
Inherent in diversity calculations is a bias for increasing diversity with increasing repertoire size. clonalDiversity()
will automatically downsample to the smallest repertoire size and perform bootstrapping to return the mean diversity estimates. If the output of diversity values are strange or minimally variable, it is likely due to a sample with small repertoire size.
n.boots
The number of calculations to perform (default = 100).
return.boots
skip.boots
Skip the bootstrapping calculations.
clonalDiversity(combined.TCR,
cloneCall = "gene",
n.boots = 20)
As a default, clonalDiversity()
will return all the metrics calculated - “shannon”, “inv.simpson”, “norm.entropy”, “gini.simpson”, “chao1”, and “ACE”. Selecting a single or a subset of these methods using the metrics parameter.
#Return only a subset of metrics
clonalDiversity(combined.TCR,
metrics = c("shannon", "ACE"),
cloneCall = "gene",
n.boots = 20)
We can also use Hill numbers to estimate the rarefaction, or estimating species richness, using the the abundance of clones across groupings. Underlying the rarefaction calculation is the use of observed receptor of abundance to compute diversity.
hill.numbers
plot.type
This function relies on the iNEXT with the accompanying manuscript. Like the other wrapping functions in scRepertoire, please cite the original work. The sample completeness curve (plot.type = 2), may not show full sample coverage due to the size/diversity of the input data.
clonalRarefaction(combined.TCR,
plot.type = 1,
hill.numbers = 0,
n.boots = 2)
clonalRarefaction(combined.TCR,
plot.type = 2,
hill.numbers = 0,
n.boots = 2)
clonalRarefaction(combined.TCR,
plot.type = 3,
hill.numbers = 0,
n.boots = 2)
clonalRarefaction(combined.TCR,
plot.type = 1,
hill.numbers = 1,
n.boots = 2)
clonalRarefaction(combined.TCR,
plot.type = 2,
hill.numbers = 1,
n.boots = 2)
clonalRarefaction(combined.TCR,
plot.type = 3,
hill.numbers = 1,
n.boots = 2)
Another method for modeling the repertoire distribution is a discrete gamma-GPD spliced threshold model, proposed by Koch et al. The spliced model models the repertoire and allows for the application of a power law distribution for larger clonal-expanded sequences and a Poisson distribution for smaller clones. After fitting the models, repertoires can be compared using Euclidean distance.
If using this function, please read/cite Koch et al. and check out the powerTCR R package.
clonalSizeDistribution(combined.TCR,
cloneCall = "aa",
method= "ward.D2")
If you are interested in measures of similarity between the samples loaded into scRepertoire, using clonalOverlap()
can assist in the visualization.
The underlying clonalOverlap()
calculation varies by the method parameter, more information on the exact calculations are available in the manual.
method
clonalOverlap(combined.TCR,
cloneCall = "strict",
method = "morisita")
clonalOverlap(combined.TCR,
cloneCall = "strict",
method = "raw")
The data in the scRepertoire package is derived from a study of acute respiratory stress disorder in the context of bacterial and COVID-19 infections. The internal single cell data (scRep_example()
) built in to scRepertoire is randomly sampled 500 cells from the fully integrated Seurat object to minimize the package size. We will use both Seurat and Single-Cell Experiment (SCE) with scater to perform further visualizations in tandem.
scRep_example <- get(data("scRep_example"))
#Making a Single-Cell Experiment object
sce <- Seurat::as.SingleCellExperiment(scRep_example)
After processing the contig data into clones via combineBCR()
or combineTCR()
, we can add the clonal information to the single-cell object using combineExpression()
.
Importantly, the major requirement for the attachment is matching contig cell barcodes and barcodes in the row names of the meta data of the Seurat or Single-Cell Experiment object. If these do not match, the attachment will fail. Based on ease, we suggest making changes to the single-cell object barcodes.
Part of combineExpression()
is calculating the clonal frequency and proportion, placing each clone into groups called cloneSize. The default cloneSize argument uses the following bins: c(Rare = 1e-4, Small = 0.001, Medium = 0.01, Large = 0.1, Hyperexpanded = 1), which can be modified to include more/less bins or different names.
Clonal frequency and proportion is dependent on the repertoires being compared, which we can modify the calculation using the group.by parameter, such as grouping by the Patient variable from above. If group.by is not set, combineExpression()
will calculate clonal frequency, proportion, and cloneSize as a function of individual sequencing runs. In addition, cloneSize can use the frequency of clones when proportion = FALSE.
We can look at the default cloneSize groupings using the Single-Cell Experiment object we just created above with using group.by set to the sample variable used in combineTCR()
:
sce <- combineExpression(combined.TCR,
sce,
cloneCall="gene",
group.by = "sample",
proportion = TRUE)
#Define color palette
colorblind_vector <- hcl.colors(n=7, palette = "inferno", fixup = TRUE)
plotUMAP(sce, colour_by = "cloneSize") +
scale_color_manual(values=rev(colorblind_vector[c(1,3,5,7)]))
Alternatively, if we want cloneSize to be based on the frequency of the clone, we can set proportion = FALSE and we will need to change the cloneSize bins to integers. If we have not inspected our clone data, setting the upper limit of the clonal frequency might be difficult - combineExpression()
will automatically adjust the upper limit to fit the distribution of the frequencies. To demonstrate this, check out the Seurat object below:
scRep_example <- combineExpression(combined.TCR,
scRep_example,
cloneCall="gene",
group.by = "sample",
proportion = FALSE,
cloneSize=c(Single=1, Small=5, Medium=20, Large=100, Hyperexpanded=500))
Seurat::DimPlot(scRep_example, group.by = "cloneSize") +
scale_color_manual(values=rev(colorblind_vector[c(1,3,4,5,7)]))
If we have TCR/BCR enrichment or want to add info for gamma-delta and alpha-beta T cells, we can make a single list and use combineExpression()
.
Major note if there are duplicate barcodes (if a cell has both Ig and TCR), the immune receptor information will not be added. It might be worth checking cluster identities and removing incongruent barcodes in the products of combineTCR()
and combineBCR()
.
As an anecdote, the testing data we used to improve this function had 5-6% of barcode overlap.
#This is an example of the process, which will not be evaluated during knit
TCR <- combineTCR(...)
BCR <- combineBCR(...)
list.receptors <- c(TCR, BCR)
seurat <- combineExpression(list.receptors,
seurat,
cloneCall="gene",
proportion = TRUE)
Using the dimensional reduction graphs as a reference, we can also generate an overlay of the position of clonally-expanded cells using clonalOverlay()
.
reduction
cut.category
cutpoint
bins
clonalOverlay()
can be used to look across all cells or faceted by a meta data variable using facet.by. The overall dimensional reduction will be maintained as we facet, while the contour plots will adjust based on the facet.by variable. The coloring of the dot plot is based on the active identity of the single-cell object.
This visualization was authored by Dr. Francesco Mazziotta and inspired by Drs. Carmona and Andreatta and their work with ProjectTIL, which is a great pipeline to annotated T cell subtypes.
#Adding patient information
scRep_example$Patient <- substr(scRep_example$orig.ident, 1,3)
clonalOverlay(scRep_example,
reduction = "umap",
cutpoint = 1,
bins = 10,
facet.by = "Patient") +
guides(color = "none")
Similar to clonalOverlay()
, we can look at the network interaction of clones shared between clusters along the single-cell dimensional reduction using clonalNetwork()
. This function shows the relative proportion of clones from the starting node, with the ending node indicated by the arrow.
Filtering for clones can be accomplished using 3 methods:
filter.clones
filter.identity
filter.proportion
filter.graph
#ggraph needs to be loaded due to issues with ggplot
library(ggraph)
#No Identity filter
clonalNetwork(scRep_example,
reduction = "umap",
group.by = "seurat_clusters",
filter.clones = NULL,
filter.identity = NULL,
cloneCall = "aa")
We can look at the clonal relationships relative to a single cluster using the filter.identity parameter.
#Examining Cluster 3 only
clonalNetwork(scRep_example,
reduction = "umap",
group.by = "seurat_clusters",
filter.identity = 3,
cloneCall = "aa")
We can also use exportClones parameter to quickly get clones that are shared across multiple identity groups, along with the total number of clones in the data set.
shared.clones <- clonalNetwork(scRep_example,
reduction = "umap",
group.by = "seurat_clusters",
cloneCall = "aa",
exportClones = TRUE)
head(shared.clones)
## # A tibble: 6 × 2
## clone sum
## <chr> <int>
## 1 CVVSDNTGGFKTIF_CASSVRRERANTGELFF 11
## 2 CAELNQAGTALIF_CASSQAPFSTSGELFF 3
## 3 CASLSGSARQLTF_CASSSTVAGEQYF 3
## 4 CALSGSRDDKIIF_NA 2
## 5 CARKVRDSSYKLIF_CASSDSGYNEQFF 2
## 6 CASLSGSARQLTF_CASSPTVAGEQFF 2
We can also look at the clones by calling specific sequences in the highlightclones()
below. In order to highlight the clones, we first need to use the cloneCall, the type of sequence we will be using, and then the specific sequences themselves using sequence. Below, we can see the steps to highlight the most prominent sequences CAERGSGGSYIPTF_CASSDPSGRQGPRWDTQYF, and CARKVRDSSYKLIF_CASSDSGYNEQFF.
scRep_example <- highlightClones(scRep_example,
cloneCall= "aa",
sequence = c("CAERGSGGSYIPTF_CASSDPSGRQGPRWDTQYF",
"CARKVRDSSYKLIF_CASSDSGYNEQFF"))
Seurat::DimPlot(scRep_example, group.by = "highlight") +
ggplot2::theme(plot.title = element_blank())
We can also look at the count of cells by cluster assigned into specific frequency ranges by using the clonalOccupy()
function and selecting the x.axis to display cluster or other variables in the meta data of the single cell object.
proportion
label
clonalOccupy(scRep_example,
x.axis = "seurat_clusters")
clonalOccupy(scRep_example,
x.axis = "ident",
proportion = TRUE,
label = FALSE)
After the metadata has been modified, we can look at clones across multiple categories using the alluvialClones()
function. We are able to use the plots to examine the interchange of categorical variables. Because this function will produce a graph with each clone arranged by called stratification, this will take some time depending on the size of the repertoire.
To understand the basic concepts of this graphing method and the ggalluvial R package, we recommend reading this post.
#Adding type information
scRep_example$Type <- substr(scRep_example$orig.ident, 4,4)
alluvialClones(scRep_example,
cloneCall = "aa",
y.axes = c("Patient", "ident", "Type"),
color = c("CVVSDNTGGFKTIF_CASSVRRERANTGELFF", "NA_CASSVRRERANTGELFF")) +
scale_fill_manual(values = c("grey", colorblind_vector[3]))
alluvialClones(scRep_example,
cloneCall = "gene",
y.axes = c("Patient", "ident", "Type"),
color = "ident")
Like alluvial graphs, we can also visualize the interconnection of clusters using the chord diagrams from the circlize R package.
The first step is getting the data frame output to feed into the chordDiagram()
function in circlize, which can be done using getCirclize()
.
This will calculate the relative number of clones shared based on the group.by variable using the product of combineExpression()
. It is important to note getCirclize()
will create a matrix the size of the group.by variable and then simplify into instructions to be read by the circlize R package. The output is the total number of unique and shared clones by the group.by variable.
library(circlize)
library(scales)
circles <- getCirclize(scRep_example,
group.by = "seurat_clusters")
#Just assigning the normal colors to each cluster
grid.cols <- hue_pal()(length(unique(scRep_example$seurat_clusters)))
names(grid.cols) <- unique(scRep_example$seurat_clusters)
#Graphing the chord diagram
chordDiagram(circles, self.link = 1, grid.col = grid.cols)
This can also be used if we want to explore just the lung-specific T cells by just subsetting the single-cell object. For the sake of this vignette, we can also look at setting proportion = TRUE to get a scaled output.
subset <- subset(scRep_example, Type == "L")
circles <- getCirclize(subset, group.by = "ident", proportion = TRUE)
grid.cols <- scales::hue_pal()(length(unique(subset@active.ident)))
names(grid.cols) <- levels(subset@active.ident)
chordDiagram(circles,
self.link = 1,
grid.col = grid.cols,
directional = 1,
direction.type = "arrows",
link.arr.type = "big.arrow")
From the excellent work by Lei Zhang, et al., the authors introduce new methods for looking at clones by cellular origins and cluster identification. Their STARTRAC software has been adapted to work with scRepertoire and please read and cite their excellent work.
In order to use the StartracDiversity()
function, you will need to include the product of the combinedExpression()
function. The second requirement is a column header in the meta data of the Seurat object that has tissue of origin. In the example data, type corresponds to the column “Type”, which includes the “P” and “T” classifiers. The indices can be subsetted for a specific patient or examined overall using the by variable. Importantly, the function uses only the strict definition of a clone of the VDJC genes and the CDR3 nucleotide sequence.
The indices output includes:
StartracDiversity(scRep_example,
type = "Type",
group.by = "Patient")
A new metric proposed by Massimo et al, clonalBias()
, like STARTRAC is a clonal metric that seeks to quantify how individual clones are skewed towards a specific cellular compartment or cluster.
split.by
group.by
min.expand
clonalBias(scRep_example,
cloneCall = "aa",
split.by = "Patient",
group.by = "seurat_clusters",
n.boots = 10,
min.expand =0)
The nucleotide or amino acid sequences of the chains can be used to cluster clonotypes by examining the edit distance of the sequences. This approach is underlying the combineBCR()
function but now can be applied to the B or T cell receptors at the level of nucleotides (sequence = “nt”) or amino acids (sequence = “aa”). It will add a cluster to the end of each list element by generating a network connected by the similarity in sequence. This network is directed by the threshold variable, where 0.85 is the normalized mean edit distance.
Edit-distance based clusters will have the following format:
Cluster denotes if the cluster was called using the normalized Levenshtein distance, which takes the edit distance calculated between 2 sequences and divides that by the mean of the sequence lengths. Unconnected sequences will have NA values.
sub_combined <- clonalCluster(combined.TCR[[2]],
chain = "TRA",
sequence = "aa",
threshold = 0.85,
group.by = NULL)
head(sub_combined[,c(1,2,13)])
## barcode sample Type
## 1 P17L_AAACCTGAGGTGTTAA-1 P17L L
## 2 P17L_AAACCTGCACGTTGGC-1 P17L L
## 3 P17L_AAACCTGGTACGACCC-1 P17L L
## 4 P17L_AAACCTGGTTCGCTAA-1 P17L L
## 5 P17L_AAACCTGTCAGCACAT-1 P17L L
## 6 P17L_AAACCTGTCCGGCACA-1 P17L L
If performed over the number of samples, such as the list elements, group.by can used to calculate only the clusters on the setting of patient sample (group.by = “Patient”) or tissue type (group.by = “Type”). This will add the selected group to the beginning of the cluster designation. We can also call clonalCluster()
directly on a Single-Cell Object.
#Define color palette
colorblind_vector <- hcl.colors(n=7, palette = "inferno", fixup = TRUE)
scRep_example <- clonalCluster(scRep_example,
chain = "TRA",
sequence = "aa",
threshold = 0.85,
group.by = "Patient")
Seurat::DimPlot(scRep_example, group.by = "TRA_cluster") +
scale_color_manual(values = hcl.colors(n=length(unique(scRep_example@meta.data[,"TRA_cluster"])), "inferno")) +
Seurat::NoLegend() +
theme(plot.title = element_blank())
Using clonalCluster()
, we can also return an igraph object of all the related sequences using exportGraph = TRUE. The returned igraph object contains only the sequences that have at least one connection with another sequence. The igraph can then be directly visualized (below) or used for downstream analysis (see the igraph website).
#Clustering Patient 19 samples
igraph.object <- clonalCluster(combined.TCR[c(5,6)],
chain = "TRB",
sequence = "aa",
group.by = "sample",
threshold = 0.85,
exportGraph = TRUE)
#Setting color scheme
col_legend <- factor(igraph::V(igraph.object)$group)
col_samples <- hcl.colors(3,"inferno")[as.numeric(col_legend)]
color.legend <- factor(unique(igraph::V(igraph.object)$group))
#Plotting
plot(
igraph.object,
vertex.size = sqrt(igraph::V(igraph.object)$size),
vertex.label = NA,
edge.arrow.size = .25,
vertex.color = col_samples
)
legend("topleft", legend = levels(color.legend), pch = 16, col = unique(col_samples), bty = "n")
This has been a general overview of the capabilities of scRepertoire from the initial processing and visualization to attach to the mRNA expression values in a single-cell object. If you have any questions, comments, or suggestions, please visit the GitHub repository.
sessionInfo()
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