Contents

1 Introduction: PCAWG signatures

In May 2018 a new and extended set of mutational signatures was published as a preprint by the Pan-Cancer Analysis of Whole Genomes (PCAWG) consortium (Alexandrov et al. 2020). In the following, we refer to that set of signatures as the PCAWG signatures. The underlying data is the largest available cohort of sequenced (Whole Genome Sequencing (WGS) and Whole Exome Sequencing (WES)) cancer samples to date and represents a substantial increase in statistical power as compared to (Alexandrov, Nik-Zainal, Wedge, Aparicio, et al. 2013) and (Alexandrov, Nik-Zainal, Wedge, Campbell, et al. 2013). On this data set, de novo mutational signature discovery analysis was performed with two different algorithms of the Non-negative Matrix Factorization (NMF) family of algorithms, SigPorfiler and SignatureAnalyzer (Bayesian NMF). In total 65 SNV mutational signatures (abbreciated SBS for single base substitution) were found, 49 of which were called validated, either because of good consensus between the two calling algorithms or because of presence in an orthogonal sequencing technology. In addition to the SNV or SBS mutational signatures, that analysis for the first time had sufficient statistical power to also extract 17 Indel (ID) signatures, based on a classification of Indels into 83 features, and Doublet Base Signatures (DBS) based on somatic di-nucleotide exchanges. In this vignette, we present an example analysis with the new PCAWG Indel signatures. The setup and line of arguments is analogous to the first vignette. However, YAPSA doesn’t provide functions for DBS signatures as mutation counts are often not sufficient for a deconvolution analysis.

As for the COSMIC SNV mutational signatures, the patterns for both the SNV and Indel PCAWG mutational signatures are stored in the software package and can be loaded into the workspace as follows:

data(sigs_pcawg)

For a precise description of all the data loaded by the above command, please refer to 2. Signature-specific cutoffs

2 Classification of Indels

A prerequisite for an analysis of Indel mutational signatures is a consistent classification system of Indels. This is non-trivial and critically depends on the choice of features, which have to include whether a given Indel is actually an insertion or a deletion, the size of the Indel,as well as the motif context in order to assess whether micro-homologies are present. In the classification proposed by the PCAWG consortium there are 83 features in total, which form five major groups:

  1. Deletions of 1 bp C/(G) or T/(A) in a repetitive context. Taking into account the motif context of the deletion, the mutational event is further classified into categories of 1, 2, 3, 4, 5 or larger or equal to 6 identical nucleotide(s).
  2. Insertions of 1 bp C/(G) or T/(A) in a repetitive context. Taking into account the motif context of the deletion, the mutational event is further classified into categories of 0, 1, 2, 3, 4, or larger or equal to 5 identical nucleotide(s).
  3. Deletions of 2 bp, 3 bp, 4 bp or more or equal to 5 bp in a repetitive context. Each deletion is classified in a context of 1, 2, 3, 4, 5 or larger or equal to 6 times the same motif.
  4. Insertions of 2 bp, 3 bp, 4 bp or more or equal to 5 bps in a repetitive context. Each deletion is classified in a context of 0, 1, 2, 3, 4 or larger or equal to 5 times the same motif.
  5. Deletions of 2 bp, 3 bp, 4 bp or more or equal to 5 bp in a partially repetitive context with microhomology at the breakpoints. This partially repetitive context is defined by motif length of minus 1 bp, 2 bp, 3 bp, 4 bps or more or equal to 5 bp, located before and after the break-points of the deletion.

Indel classifications in the range of 1 - 5 bp are assigned to individual categories, while all variants larger than 5bp are considered as one category. Of note, microhomology is defined by partial sequence similarity between the motif of the respective Indel and the immediate neighbouring sequence context. In the following, we illustrate the microhomology classification with an example. We take a deletion of the motif ATGCGA, being more than 5 bp in length with microhomology, i.e., partially repetitive context of 4 bp at the breakpoint junction with the motifs ATGC upstream and GCGA downstream of the deletion. The annotated feature category is then MH_5+_4bp.

In YAPSA, the function plotExchangeSpectra_indel() can be used to plot the nucleotide exchange spectra of samples and/or signatures. The representation is analogous to the function plotExchangeSpectra() for SNV mutational signatures, while the colors and feature annotation is taken from (Alexandrov et al. 2020).

plotExchangeSpectra_indel(PCAWG_SP_ID_sigs_df[,c(3,6)])
: Nucleotide exchange spectra of the Indel signatures ID3, associated 
        with tobacco smoking, and ID6, related to deficiencies in homologous 
        recombination repair.

Figure 1: : Nucleotide exchange spectra of the Indel signatures ID3, associated
with tobacco smoking, and ID6, related to deficiencies in homologous recombination repair.

3 PCAWG Indel signatures

The publication (Alexandrov et al. 2020) reports signatures decomposed with an NMF approach (SigProfiler) and a Bayesian NMF approach (SignatureAnalyser). It is worth noting that YAPSA only has mutational signatures decomposed with SigProfiler integrated so far, of which the validated signatures are also found with SignatureAnalyser. Signatures only decomposed with SignatureAnalyzer are not part of YAPSA. Signature ID15 was excluded as none of the samples had a contribution to this signature. For seven of the Indel signatures, underlying mutational processes were asserted. Indel Signatures ID1 and ID2 can be found across all entities, while others such as ID13 is associated with UV light exposure and is found exclusively in melanoma (cf. Alexandrov et al. (2020)).

current_caption <- paste0("Information on Indel mutational signatures.")
if(!exists("repress_tables"))
  kable(PCAWG_SP_ID_sigInd_df, row.names=FALSE, caption=current_caption)

Table 1: Information on Indel mutational signatures.
sig index colour process
ID1 1 chartreuse4 Replication slippage, sometimes defective DNA mismatch repair
ID2 2 orange Replication slippage, sometimes defective DNA mismatch repair
ID3 3 lightblue Tobacco smoking
ID4 4 orchid2 unknown
ID5 5 darkmagenta unknown
ID6 6 goldenrod4 DBS repair by non-homologous end joining; defective HR repair
ID7 7 lawngreen Defective DNA mismatch repair
ID8 8 darkcyan DBS repair by non-homologous end joining
ID9 9 olivedrab3 unknown
ID10 10 darkseagreen3 unknown
ID11 11 darkslategray4 unknown
ID12 12 red3 unknown
ID13 13 yellow2 Ultraviolet light exposure
ID14 14 dodgerblue1 unknown
ID16 15 pink unknown
ID17 16 mediumblue unknown

4 Example data: Genome of the Netherlands

In order to demonstrate the functionalities of the Indel signature analysis with YAPSA, a publicly available data set was chosen, the Genome of the Netherlands (https://www.nlgenome.nl/menu/main/app-go-nl/?page_id=9) release5. The data set is not related to cancer and instead contains germline variation in the genomes of the Dutch population. Hence no biological interpretation or conclusion of this analysis with respect to mutational processes should be made, it is of sole technical and demonstrative purpose.

5 Supervised Indel signature analysis

5.1 Loading example data

We first load the example data, which is stored in the software package YAPSA. The file \(\texttt{GenomeOfNl_raw.rda}\) has been filtered to only contain Indel variant calls.

data(GenomeOfNl_raw)
GenomeOfNl_raw <- GenomeOfNl_raw[, c(1,2,4,5)]

Optional columns are being removed from the loaded data, which results in a vcf-like (analogous to the variant calling format) dataframe with 591 variants. The binary file above was created with the following R code:

load_data_new <- FALSE
if(load_data_new){
  data <- data.frame(matrix(ncol = 8, nrow = 0))
  for(index in seq_along(1:22)){
              print(index)
              temp <- tempfile()
              file_path <- paste0("https://molgenis26.gcc.rug.nl/
                                  downloads/gonl_public/variants/release5/
                                  gonl.chr",
                                  index, ".snps_indels.r5.vcf.gz")
              download.file(file_path, temp)
       
              data <- rbind(data, read.table(gzfile(temp, paste0("gonl.chr",
                                                    index,
                                                    ".snps_indels.r5.vcf")),
                                             header=FALSE, sep="\t", 
                                             stringsAsFactors = FALSE))
              data <- data[grep("INDEL", data$V8),]
              unlink(temp)
            
  }
  colnames(data) <- c("CHROM", "POS", "ID", "REF", "ALT", "QUAL", 
                      "FILTER","INFO")

  GenomeOfNl_raw <- data[, c(1,2,4,5)]
}

The obtained dataframe will later be used it in order to build a mutational catalog for supervised analysis of mutational signatures with PCAWG Indel signatures.

Table 2: Head of VCF file
containing the GoNL INDEL data
CHROM POS REF ALT
32 2 12320 AAT A
53 2 13613 AG A
92 2 17012 TAAAG T
94 2 17128 T TG
95 2 17142 G GA
96 2 17151 TCAC T

5.2 Data Preprocessing

GenomeOfNl_raw does not contain any patient identifier information. For the purpose of demonstrating the use of YAPSA Indel signature analysis, such an information on patient identity is necessary. To do so, 15 synthetic patient identifiers (PIDs) were generated and 50 +/- 20 Indels per PID were randomly sampled from the data frame GenomeOfNl_raw.

seed = 2
set.seed(seed)
number_of_indels <- sample(c(30:70), 15,  replace = TRUE)

index=0
seed=3
set.seed(seed)
vcf_like_indel_lists <- lapply(number_of_indels, function(size){
  df_per_PID <- GenomeOfNl_raw[sample(nrow(GenomeOfNl_raw), size, 
                                      replace = FALSE), ]
  index <<- index+1
  df_per_PID$PID <- rep(paste0("PID_", index), length(size))
  df_PIDs <- df_per_PID[order(df_per_PID$CHROM),]
  return(df_PIDs)
  })

vcf_like_indel_df <- do.call(rbind.data.frame, vcf_like_indel_lists)
kable(head(vcf_like_indel_df), caption="Head of the vcf_like_df
      containing the subsampled GoNL Indel data")
Table 3: Head of the vcf_like_df
containing the subsampled GoNL Indel data
CHROM POS REF ALT PID
743 2 102906 G GTA PID_1
234 2 31995 ATG A PID_1
258 2 35063 C CTTTTTG PID_1
634 2 89249 CACAA C PID_1
1574 3 119388 CTT C PID_1
1437 3 106298 AT A PID_1

Using the artificial vcf_like_df created above as input, the function create_indel_mutation_catalogue_from_df() then builds a mutational catalog \(V^{INDEL}\) containing the absolute feature counts (\(n\)) for each patient. This functions is equivalent to the function create_mutation_catalogue_from_df() for SNV data. Besides the input of type vcf_like_df, the function create_indel_mutation_catalogue_from_df() also requires the Indel signatures (PCAWG_SP_ID_sigs_df) loaded previously into the workspace. The function create_create_indel_mutation_catalogue_from_df() is a wrapper of several other functions:

  1. attribute_sequence_contex_indel() the function annotates to the vcf_like_df a sequence context of 10 bp down- and 60 bp upstream of every Indel variant. Additionally, the information whether the variant is an insertion or deletion and the length of the Indel is annotated to every Indel mutation.
  2. attribution_of_indels() attributes each variant to one of the 83 classes of features
  3. create_indel_mut_cat_from_df() carries out the counting in order to obtain a mutational catalog with the dimensions \(n \times m\).

Please note that this pre-processing step takes longer than all other functions in YAPSA and may be time limiting.

vcf_like_indel_trans_df <- translate_to_hg19(vcf_like_indel_df,"CHROM")
mutational_cataloge_indel_df <- create_indel_mutation_catalogue_from_df(
  in_dat = vcf_like_indel_trans_df,
  in_signature_df = PCAWG_SP_ID_sigs_df)
## [1] "Indel sequence context attribution of total  670  indels. This could take a while..."
## [1] "INDEL classification of total  670  INDELs This could take a while..."
kable(head(mutational_cataloge_indel_df[,1:5]))
PID_1 PID_2 PID_3 PID_4 PID_5
DEL_C_1_0 2 3 3 0 1
DEL_C_1_1 2 0 2 1 1
DEL_C_1_2 2 1 1 0 1
DEL_C_1_3 0 0 1 0 1
DEL_C_1_4 1 1 1 0 0
DEL_C_1_5+ 1 1 0 1 0

5.3 LCD Analysis

The core function of YAPSA is the function LCD and its derived functions, which perform supervised mutational signature analysis. Here we describe how this class of functions has been extended in order to make this supervised signature analysis available to Indel mutational signatures. As previously described for SNV mutational signatures, the deconvolution is based on a non-negative least squares (NNLS) algorithm. In order to reduce false positive calls, signature-specific cutoffs were introduced in YAPSA. Signature-specific cutoffs are applied after a first decomposition with NNLS, and only signatures with computed contributions higher than their signature-specific cutoff are used in a second decomposition which then yields the exposure values. Signature-specific cutoffs take the different detectability of signatures into account, reflected by a lower signature-specific cutoff for signatures with a distinct pattern and a higher signature-specific cutoff for signatures with broader patterns.

Of note, mutational processes have been asserted to fractions of both the sets of SNV and Indel mutational signatures. There are overlaps between the asserted mutational processes, as some of them can indeed leave imprints on both the SNV and Indel mutational landscapes. Combining the information extracted with an analysis of mutational signatures from the different types of mutation may thus increase discriminatory power.

As described here, signature-specific cutoffs were trained in a modified ROC analysis with the package ROCR (Sing et al. 2005) using the results of the unsupervised discovery analysis as training data. As for the SNV mutational signatures, signature-specific cutoffs are stored in dataframes within the software package and can be loaded into the workspace:

data(cutoffs_pcawg)

As described in 2. Signature-specific cutoffs, the modified ROC analyses are parametrized by defining cost terms for punishing false-negative (\(cost_{FN}\)) and false-positive (\(cost_{FP}\)) findings separately, but the shape and minima of the cost functions depend only on the ratio between the cost for a false-negative finding divided by the cost for a false positive finding, the \(cost_{factor}\) (\(cost_{factor} = cost_{FN}/cost_{FP}\)). Therefore, there is one set of optimal signature-specific cutoffs per chosen value of \(cost_{factor}\).

Optimal signature-specific cutoffs are stored in data frames within the software package and can be loaded into the workspace as shown above. In these data frames every row corresponds to a different value of \(cost_{factor}\). For Indel signatures the optimal cost factor was identified to be 3, thus the third line in cutoffPCAWG_ID_WGS_Pid_df can be chosen for analysis.

current_catalogue_df <- mutational_cataloge_indel_df 
current_sig_df <- PCAWG_SP_ID_sigs_df
current_cutoff_pid_vector <- cutoffPCAWG_ID_WGS_Pid_df[3,]
current_sigInd_df <- PCAWG_SP_ID_sigInd_df

current_LCDlistsList <- LCD_complex_cutoff_combined(
  current_catalogue_df,
  current_sig_df,
  in_cutoff_vector = current_cutoff_pid_vector,
  in_filename = NULL,
  in_method = "abs",
  in_sig_ind_df = current_sigInd_df)

current_consensus_LCDlist <- current_LCDlistsList$consensus
if(!exists("repress_tables")) 
  as.character(current_consensus_LCDlist$out_sig_ind_df$sig)
##  [1] "ID1"  "ID2"  "ID3"  "ID4"  "ID5"  "ID6"  "ID8"  "ID9"  "ID12" "ID14"
## [11] "ID17"

5.4 Visualization

The exposures, i.e., the contributions of the different signatures to the mutational catalog of every sample, can be visualized with the function exposures_barplot(). All the functionalities which are available for SNV mutational signatures, such as the annotation of subgroups (cf.  1. Usage of YAPSA) are also available for the Indel mutational signatures.

exposures_barplot(current_LCDlistsList$perPID$exposures,
                  current_LCDlistsList$perPID$out_sig_ind_df)
:Exposures to Indel mutational signatures in the artificial data created 
        by sampling GoNL variants. Exposures were obtained from
        a decomposition with PCAWG Indel signatures as well as their signature
        specific-cutoffs (cutoffPCAWG_ID_WGS_Pid_df).

Figure 2: :Exposures to Indel mutational signatures in the artificial data created
by sampling GoNL variants. Exposures were obtained from a decomposition with PCAWG Indel signatures as well as their signature specific-cutoffs (cutoffPCAWG_ID_WGS_Pid_df).

6 Confidence Intervals

In order to assess trustworthiness of the computed exposures, YAPSA provides the calculation of confidence intervals (CIs). Analogously to CIs for SNV mutational signatures, the CIs for Indel mutational signatures are computed using the concept of profile likelihood.

confidence_intervals_ID <- confidence_indel_only_calulation(
  in_current_indel_df = current_catalogue_df)
## [1] "PCAWGValidID_abs"
plot(confidence_intervals_ID$p_complete_PCAWG_ID)
Confidence interval calculation for exposures to Indel mutational 
        signatures

Figure 3: Confidence interval calculation for exposures to Indel mutational
signatures

Note: With confidence_indel_only_calulation() only for INDELs the confidence intervals are calculated. To calculate the confidence intervals for SNVs and INDELs please use the function confidence_indel_calulation() and supply the mutational catalogs of both SNV and INDEL counts.

References

Alexandrov, LB, J Kim, NJ Haradhvala, MN Huang, AW Ng, A Boot, KR Covington, et al. 2020. “The Repertoire of Mutational Signatures in Human Cancer.” Nature. Nature.

Alexandrov, LB, S Nik-Zainal, DC Wedge, SA Aparicio, S Behjati, AV Biankin, GR Bignell, et al. 2013. “Signatures of Mutational Processes in Cancer.” Nature. Nature Publishing Group.

Alexandrov, LB, S Nik-Zainal, DC Wedge, PJ Campbell, and MR Stratton. 2013. “Deciphering Signatures of Mutational Processes Operative in Human Cancer.” Cell Reports.

Sing, Tobias, Oliver Sander, Niko Beerenwinkel, and Thomas Lengauer. 2005. “ROCR: Visualizing Classifier Performance in R.” Bioinfomatics.