Tutorial: Working with PacBio's CCS BAM and SMRT Tools

PacBio Data Hands-on

Khi Pin, Chua 19/01/2022

• Using Conda environment
• What tools do we have?
• FASTQ and FASTA file
• What’s in a PacBio HiFi bam file?
• Anything else in a sequence BAM file?
• Aligned BAM file
• SMRT Link without GUI and pbcromwell
  • Installing SMRT Link command line tools
  • Reproducible and easy pipeline with pbcromwell

Using Conda environment

• Anaconda is a package used to manage software packages and their dependencies.
• Anaconda “pull” packages from “repositories” and automatically find out what are the softwares or libraries needed to make sure the software you want to use can work.
  • Instead of installing 10 packages that’s required before you can use pbmm2 for example, conda install -c bioconda pbmm2 will take care of that for you (using bioconda as the main package repository)
• In addition, sometimes different softwares can conflict with each other. E.g. software 1 requires libraryX version 1.1 but software 2 requires libraryX version 1.2. Conda solves this problem by creating “virtual environment” so you can have software 1 in its own “container” that contains library X version 1.1 and software 2 in another “container” that contains library X version 1.2. As a result, they will not conflict with each other.
• You can create an environment called ENVX with conda create -n ENVX. In this workshop, we’ve created 2 environment that you will use. One is called isoseqtoy and another one called SQANTI3.env.
• Tips conda install can sometimes take a long time to resolve dependencies. Check out mamba: https://github.com/mamba-org/mamba that can speed up the process (by a large margin most of the time!)

What tools do we have?

• pbmm2, lima, isoseq3 and samtools are command line tools that can be installed via Anaconda
• We’ve already installed these for you (You can try to install it on your own HPC after the workshop!).
• You can go into the isoseqtoy environment using the command conda activate isoseqtoy.

conda activate isoseqtoy
# Check the versions of the softwares
pbmm2 --version
lima --version
isoseq3 --version
samtools --version

## Could not find conda environment: isoseqtoy
## You can list all discoverable environments with `conda info --envs`.
## 
## pbmm2 1.7.0 (commit 1.7.0)
## lima 2.2.0 (commit v2.2.0)
## isoseq3 3.4.0 (commit v3.4.0)
## samtools 1.14
## Using htslib 1.14
## Copyright (C) 2021 Genome Research Ltd.
## 
## Samtools compilation details:
##     Features:       build=configure curses=yes 
##     CC:             gcc
##     CPPFLAGS:       
##     CFLAGS:         -Wall -g -O2
##     LDFLAGS:        
##     HTSDIR:         htslib-1.14
##     LIBS:           
##     CURSES_LIB:     -lncursesw
## 
## HTSlib compilation details:
##     Features:       build=configure plugins=no libcurl=yes S3=yes GCS=yes libdeflate=no lzma=yes bzip2=yes htscodecs=1.1.1-1-ged325d7
##     CC:             gcc
##     CPPFLAGS:       
##     CFLAGS:         -Wall -g -O2 -fvisibility=hidden
##     LDFLAGS:        -fvisibility=hidden 
## 
## HTSlib URL scheme handlers present:
##     built-in:     preload, data, file
##     S3 Multipart Upload:  s3w, s3w+https, s3w+http
##     Amazon S3:    s3+https, s3+http, s3
##     Google Cloud Storage:     gs+http, gs+https, gs
##     libcurl:  imaps, pop3, gophers, http, smb, gopher, sftp, ftps, imap, smtp, smtps, rtsp, scp, ftp, telnet, mqtt, https, smbs, tftp, pop3s, dict
##     crypt4gh-needed:  crypt4gh
##     mem:  mem

• To go back to the previous environment (i.e. before conda activate ENV), you can type conda deactivate. To go back to the base environment, type conda activate base.

FASTQ and FASTA file

• FASTQ and FASTA files are common file format used in many sequencing platforms and universally accepted by many tools. Let’s look at a FASTA file first:

# Go into the workshop directory
cd ~/pacbio_data_cli
# The FASTQ and FASTA files are compressed using Gzip. You can use
# zcat instead of cat to look at gzipped text file. 
zcat alz.ccs.toy.fasta.gz | 
  head | 
  cut -c -120

## >m64014_190506_005857/85/ccs
## AAGCAGTGGTATCAACGCAGAGTACTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTGAGG
## AAAACCCGGTAATGATGTCGGGGTTGAGGGATAGGAGGAGAATGGGGGATAGGTGTATGA
## ACATGAGGGTGTTTTCTCGTGTGAATGAGGGTTTTATGTTGTTAATGTGGTGGGTGAGTG
## AGCCCCATTGTGTTGTGGTAAATATGTAGAGGGAGTATAGGGCTGTGACTAGTATGTTGA
## GTCCTGTAAGTAGGAGAGTGATATTTGATCAGGAGAACGTGGTTACTAGCACAGAGAGTT
## CTCCCAGTAGGTTAATAGTGGGGGGTAAGGCGAGGTTAGCGAGGCTTGCTAGAAGTCATC
## AAAAAGCTATTAGTGGGAGTAGAGTTTGAAGTCCTTGAGAGAGGATTATGATGCGACTGT
## GAGTGCGTTCGTAGTTTGAGTTTGCTAGGCAGAATAGTAATGAGGATGTAAGTCCGTGGG
## CGATTATGAGAATGACTGCGCCGGTGAAGCTTCAGGGGGTTTGGATGAGAATGGCTGTTA

• A FASTQ file is similar to FASTA, but with the information of per-base quality (encoded in phred-scale using ASCII character. See for example: https://www.drive5.com/usearch/manual/quality_score.html) and strand information (Not relevant for PacBio’s HiFi).

cd ~/pacbio_data_cli
# Now let's look at a FASTQ version
zcat alz.ccs.toy.fastq.gz | 
  head -8 | 
  cut -c -120

## @m64014_190506_005857/85/ccs
## AAGCAGTGGTATCAACGCAGAGTACTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTGAGGAAAACCCGGTAATGATGTCGGGGTTGAGGGATAGGAGGAGAATGGGGGATAGGTGTATGA
## +
## ~~~~~~~~~~~~~~~~~~~~~~~~~%~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
## @m64014_190506_005857/2592/ccs
## AAGCAGTGGTATCAACGCAGAGTACTTTTTTTTTTTTTTTTTTTTTTTTTTTTTGAATTCCATCAGATTTACTATACGGAACATCAGTAGTGACAGATTGCACTTCTTACTTAATAACAG
## +
## ~~~~~~~~~~~~~~~~~~~~~~~~~+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

What’s in a PacBio HiFi bam file?

• SAM stands for “Sequence Alignment Format/Map” which is a format used to store sequencing data.
• BAM is a binary-compressed version of SAM file so it has a much lower file-size.
• PacBio’s BAM file is fully compatible with the SAM specification: https://samtools.github.io/hts-specs/SAMv1.pdf
• samtools is an industry-standard tool to view/manipulate BAM/SAM formats. For example, you can look at the alignment using samtools view (works with both SAM and BAM format)
• Output from samtools view are tab-delimited, meaning each column is separated by tab and can be treated like a “tsv” file.
• Let’s use some of the command line knowledges we’ve gained from the previous course:
  • | is the pipe operator used to chain multiple commands together.
  • head is used to read just the first record of the BAM.
  • tr is used to change “tabs” (represented by “\t”) into new line (represented by “\n”) so we can see each column on a separate line.
  • awk is a very powerful tool for text manipulation. Here, we use it to add “Column X” in front of each of the column of the sequence alignment
  • PacBio sequences are long! We use cut -c -100 to trim the output to just 100 characters so it’s easier to view

# Here's an example CCS BAM file
samtools view alz.ccs.toy.bam | 
  head -1 | 
  tr '\t' '\n' | 
  awk 'str_line="Column-"FNR":"{print str_line,$0}' OFS=$'\t' |
  cut -c -100

## Column-1:    m64014_190506_005857/85/ccs
## Column-2:    4
## Column-3:    *
## Column-4:    0
## Column-5:    255
## Column-6:    *
## Column-7:    *
## Column-8:    0
## Column-9:    0
## Column-10:   AAGCAGTGGTATCAACGCAGAGTACTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTGAGGAAAACCCGGTAATGATGTCGGGGTTGAGG
## Column-11:   ~~~~~~~~~~~~~~~~~~~~~~~~~%~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
## Column-12:   RG:Z:7ae86b2d
## Column-13:   ec:f:29.8258
## Column-14:   np:i:29
## Column-15:   rq:f:0.999842
## Column-16:   sn:B:f,15.6053,22.4039,5.90035,10.4158
## Column-17:   zm:i:85

• Column 2-9 are usually meant for storing alignment information. However, PacBio’s BAM files from the instrument do not have any alignment. Hence, any values in these columns **before alignment* are just “placeholders” meant to comply with the SAM format.
• Question: Why does PacBio uses BAM format instead of just FASTQ/FASTA?
• For CCS BAM file, two important columns are column 14 and 15. np indicates the number of full passes used to generate the CCS read, and rq represents the average per-base QV score for the read. Here, this read has an accuracy of 0.999842. QV score can be calculated as:  − 10 * log₁₀(1−Accurac**y)
• Tricks In bash, we can use the bc tool to carry out math operation (Pipe the equation you want to evaluate to bc -l). Here for example, this read is QV38:

# To let log10, divide the natural log of your value by the natural log of 10
echo '-10*l(1 - 0.999842)/l(10)' | bc -l

## 38.01342913045577376801

• PacBio provides a web page documenting any PacBio-specific extension to the standard SAM format (e.g. the ip and pw tags for kinetics): https://pacbiofileformats.readthedocs.io/en/10.0/BAM.html

Anything else in a sequence BAM file?

• Try samtools view -H alz.ccs.toy.bam
• Question: Can you find out what “-H” means? (Hint: How to get help for a command line tool?)

samtools view -H alz.ccs.toy.bam 

## @HD  VN:1.5  SO:unknown  pb:3.0.1
## @RG  ID:7ae86b2d PL:PACBIO   DS:READTYPE=CCS;BINDINGKIT=101-717-300;SEQUENCINGKIT=101-644-500;BASECALLERVERSION=5.0.0;FRAMERATEHZ=100.000000 PU:m64014_190506_005857 PM:SEQUELII CM:S/P3-C1/5.0-8M
## @PG  ID:ccs-4.2.0    PN:ccs  VN:4.2.0    DS:Generate circular consensus sequences (ccs) from subreads.   CL:ccs ccs 1perc.bam 1perc.ccs.bam --log-level INFO --min-rq 0.9
## @PG  ID:samtools PN:samtools PP:ccs-4.2.0    VN:1.14 CL:samtools view -s 0.1 -bh isoseq3/alz.ccs.bam
## @PG  ID:samtools.1   PN:samtools PP:samtools VN:1.14 CL:samtools view -H alz.ccs.toy.bam

• The “-H” parameter outputs just the header of a BAM/SAM file. A header contains information such as the sequencing platform, chemistry version, sample names, and even commands used to generate the BAM/SAM file.
• Some PacBio’s tools rely on the header to run. E.g. Modern version of CCS will not be able to run if the chemistry is too old (E.g. RS II).
• Can you find out what platform this example dataset was sequenced on and what was the version of CCS used?

Aligned BAM file

• Let’s try doing your first reference genome alignment! Type the following command (It should take only around 2 mins):

# The "\" here is to allow us to split the command
# into multiple lines to make the command looks "cleaner" 
pbmm2 align hg38.mmi alz.ccs.toy.bam alz.ccs.toy.aligned.bam \
  --preset ISOSEQ --sort -j 4 --log-level INFO \
  --log-file pbmm2_c4.log

• Question: Can you look at the content of the first read and observe any difference?

samtools view alz.ccs.toy.aligned.bam | 
  head -1 | 
  tr '\t' '\n' | 
  awk 'str_line="Column-"FNR":"{print str_line,$0}' OFS=$'\t' |
  cut -c -100

## Column-1:    m64014_190506_005857/130744625/ccs
## Column-2:    0
## Column-3:    chr1
## Column-4:    184918
## Column-5:    5
## Column-6:    56S34=1X19=1X61=1X8=1X19=1X31=1X15=1X8=1X4=1X5=1X42=1X45=1X129=140N46=1X23=757N48=1X104=65
## Column-7:    *
## Column-8:    0
## Column-9:    15612
## Column-10:   AAGCAGTGGTATCAACGCAGAGTACTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTCGGTTTCTGCTCAGTTCTTTATTGATTGGTGTGC
## Column-11:   ~~~~~~~~~~~~~~~~~~~~~~~~~3~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
## Column-12:   RG:Z:7ae86b2d
## Column-13:   ec:f:38.3301
## Column-14:   np:i:37
## Column-15:   rq:f:0.999991
## Column-16:   sn:B:f,14.5022,20.4547,5.73951,9.6271
## Column-17:   zm:i:130744625
## Column-18:   mg:f:98.1636

• Question: Which one is the “CIGAR” string and can you look for the definition of what the CIGAR string here means?
• Question: Can you tell which position in the reference genome is this alignment?
• One cool tool in samtools is that you can view the alignment on the command line (substitute “chr1:185300” with your alignment, if it’s different):

samtools tview -d T alz.ccs.toy.aligned.bam -p chr1:185300 --reference hg38.fa.gz

##  185301    185311    185321    185331    185341    185351    185361             
## CAAAGGCTCCTCCGGGCCCCTCACCAGCCCCAGGTCCTTTCCCAGAGATGCCTGGAGGGAAAAGGCTGAGTGAGGGTGGT
## ..................................................KK...K...KKKK..K..K...K.......
## ..................................................>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>

• Press ? in samtools tview to look for help. You can press q to exit the view. Use the arrow keys to move around the alignment.
• The first row is the reference sequence, the second row is the “consensus sequence” from the alignments. From third row onwards these are the alignments mapping to this region.
• Tricks: We’ve heard about awk being awesome, why do you want to know about it? Try:

# What does this do? Swap 14 to 15, what do you need to change?
samtools view alz.ccs.toy.bam | awk '{gsub("np:i:","",$14); total+=$14;count++} END {print total/count}'

## 24.2683

SMRT Link without GUI and pbcromwell

Installing SMRT Link command line tools

• In many HPC, you often don’t have the permission to run a service at the background for the graphical user interface (GUI) version of SMRT Link.
• SMRT Link provides a “--smrttools-only” option during installation to install SMRT Link on just the command line. Execute the following:

# Remove the installation if it already exists
rm -rf ~/softwares/SMRTLink-10.2
# Install SMRT Link, "--rootdir" specifies the installation directory
~/Downloads/smrtlink_10.2.0.133434.run --rootdir ~/softwares/SMRTLink-10.2 --smrttools-only

• The installation will install SMRT Link command line tools at “~/softwares/SMRTLink-10.2”.
• The tools from SMRT Link installation are meant to be stable for SMRT Link, so the version may be different from what’s available on Bioconda.
• Most of the tools in SMRT Link will be located at “~/softwares/SMRTLink-10.2/smrtcmds/bin”. For example, you can run pbmm2 by typing (Compare the version to that of the beginning using conda):

# Go to base environment first to avoid package conflict
conda activate base
~/softwares/SMRTLink-10.2/smrtcmds/bin/pbmm2 --version

## pbmm2 1.8.0 (commit v1.7.0-9-g3c16a4d)

Reproducible and easy pipeline with pbcromwell

• Cromwell is a “workflow language” (https://github.com/broadinstitute/cromwell) that is used in SMRT Link to design and run bioinformatics pipelines. In bioinformatics, you often have many steps that you will run again and again. A pipeline puts together those steps and make it easy for you to rerun (thus reproducible) the steps easily.
• pbcromwell is a tool that can be used to run SMRT Link pipeline on the command line without going through the GUI. With the “--smrttools-only” SMRT Link installation, you can run the full pipelines just like how you can with the GUI!
• There are many other useful tools that do not require installing a GUI. For example, one of the most common requests are to generate plots and summary metrics similar to what you see in SMRT Link. This can be done via runqc-reports tool provided by SMRT Tools.
• Let’s try this while I explain step by step:

~/softwares/SMRTLink-10.2/smrtcmds/bin/pbindex alz.ccs.toy.bam

~/softwares/SMRTLink-10.2/smrtcmds/bin/dataset create --type ConsensusReadSet \
  alz.ccs.toy.consensusreadset.xml alz.ccs.toy.bam
  
~/softwares/SMRTLink-10.2/smrtcmds/bin/runqc-reports alz.ccs.toy.consensusreadset.xml
  
cp ~/workshop_data/isoseq3/isoseq_primers.fasta .

~/softwares/SMRTLink-10.2/smrtcmds/bin/dataset create --type BarcodeSet \
  isoseq_primers.barcodeset.xml isoseq_primers.fasta
  
~/softwares/SMRTLink-10.2/smrtcmds/bin/pbcromwell --help
# By default pbcromwell runs locally. If you have a HPC you can configure
# Cromwell to use the job scheduler on your HPC such as SGE/Slurm etc
~/softwares/SMRTLink-10.2/smrtcmds/bin/pbcromwell configure
~/softwares/SMRTLink-10.2/smrtcmds/bin/pbcromwell show-workflows
~/softwares/SMRTLink-10.2/smrtcmds/bin/pbcromwell show-workflow-details pb_isoseq3

~/softwares/SMRTLink-10.2/smrtcmds/bin/pbcromwell run pb_isoseq3 -e alz.ccs.toy.consensusreadset.xml \
  -e isoseq_primers.barcodeset.xml \
  --task-option filter_min_qv=10 \
  --config cromwell.conf --nproc 4

• It should take a few mins for the analysis to finish. You should see a folder named cromwell_out ( can be changed using --output-dir parameter). Inside this folder, the outputs folder contains the results of the pipeline.
• The .json files typically contains the important numbers from the pipeline. For example, you can look at the file barcode_isoseq3.report.json by using less. A fantastic tool to work with .json file is jq (already installed for you) and you can format the file into a table similar to what you see on the GUI:

cat cromwell_out/outputs/barcode_isoseq3.report.json | 
  jq -r '.attributes | (["Type","Value"] | (., map(length*"-"))), (.[] | [.name, .value]) | @tsv' | 
  column -t -s$'\t'

## Type                                                         Value
## ----                                                         -----
## Reads                                                        42224
## Reads with 5' and 3' Primers                                 37809
## Non-Concatamer Reads with 5' and 3' Primers                  37627
## Non-Concatamer Reads with 5' and 3' Primers and Poly-A Tail  37542
## Mean Length of Full-Length Non-Concatamer Reads              2933
## Unique Primers                                               1
## Mean Reads per Primer                                        37809
## Max. Reads per Primer                                        37809
## Min. Reads per Primer                                        37809
## Reads without Primers                                        4415
## Percent Bases in Reads with Primers                          0.8972253037887876
## Percent Reads with Primers                                   0.8954386131110269

• The runqc-reports tool will generate a summary statistics for CCS in a file called “ccs.report.json”. Again, you can use the awesome jq to look at the stats in table format:

cat ccs.report.json | 
  jq -r '.attributes | (["Type","Value"] | (., map(length*"-"))), (.[] | [.name, .value]) | @tsv' | 
  column -t -s$'\t'

• If the jq command is too hard to remember, PacBio’s json is not hard to read directly using the old trusty less.

• In the cromwell_out/cromwell-executions folder, all the intermediate results and outputs are stored in separate folder for different stages of the pipelines. For example, if you want to look at lima step:

# Cromwell stores each "job" using a unique ID everytime you run a new job. 
# The wildcard "*" here is the unique ID that will be different from others
ls -lhtr cromwell_out/cromwell-executions/pb_isoseq3/*/call-lima_isoseq/execution

## total 89M
## -rw-rw-r-- 1 kpin kpin 8.0K Jan 11 21:46 script
## -rw-rw-r-- 1 kpin kpin    0 Jan 11 21:46 stderr.background
## -rw-rw-r-- 1 kpin kpin  286 Jan 11 21:46 script.submit
## -rw-rw-r-- 1 kpin kpin  651 Jan 11 21:46 script.background
## -rw-rw-r-- 1 kpin kpin    6 Jan 11 21:46 stdout.background
## -rw-rw-r-- 1 kpin kpin    0 Jan 11 21:46 stdout
## -rw-rw-r-- 1 kpin kpin    0 Jan 11 21:46 stderr
## -rw-rw-r-- 1 kpin kpin   98 Jan 11 21:46 fl_transcripts.lima.guess.txt
## -rw-rw-r-- 1 kpin kpin 7.5M Jan 11 21:46 fl_transcripts.lima.report
## -rw-rw-r-- 1 kpin kpin 5.5M Jan 11 21:46 fl_transcripts.lima.clips
## -rw-rw-r-- 1 kpin kpin  76M Jan 11 21:46 fl_transcripts.5p--3p.bam
## -rw-rw-r-- 1 kpin kpin 433K Jan 11 21:46 fl_transcripts.5p--3p.bam.pbi
## -rw-rw-r-- 1 kpin kpin  909 Jan 11 21:46 fl_transcripts.lima.summary.txt
## -rw-rw-r-- 1 kpin kpin   88 Jan 11 21:46 fl_transcripts.lima.counts
## -rw-rw-r-- 1 kpin kpin  585 Jan 11 21:46 fl_transcripts.json
## -rw-rw-r-- 2 kpin kpin 3.4K Jan 11 21:46 fl_transcripts.5p--3p.consensusreadset.xml
## -rw-rw-r-- 1 kpin kpin    2 Jan 11 21:46 rc
## drwxrwxr-x 2 kpin kpin 4.0K Jan 11 21:46 glob-2fafc865f103dbf71884e943029cd0fb
## -rw-rw-r-- 1 kpin kpin   43 Jan 11 21:46 glob-2fafc865f103dbf71884e943029cd0fb.list

• If you want to understand how the pipeline runs the individual step, there’s a script file in the execution folder and you can find the detailed command used to generate the data.
• For example, if I want to see how SMRT Link pipeline runs lima:

# The grep command looks for the lima command and print 8 lines after the match (-A8)
grep -A8 '^lima' \
  cromwell_out/cromwell-executions/pb_isoseq3/*/call-lima_isoseq/execution/script

## lima \
##   -j 32 \
##   --isoseq \
##   --peek-guess \
##   --ignore-biosamples \
##   --alarms alarms.json \
##   cromwell_out/cromwell-executions/pb_isoseq3/c1b548a2-58bb-4962-b61a-324cd5f2eee5/call-lima_isoseq/inputs/233360854/filtered.consensusreadset.xml \
##   cromwell_out/cromwell-executions/pb_isoseq3/c1b548a2-58bb-4962-b61a-324cd5f2eee5/call-lima_isoseq/inputs/-1912619708/isoseq_primers.barcodeset.xml \
##   fl_transcripts.json

• Finally, one additional advantage of running the full pipeline is that SMRT Link generates some useful QC plots that you can find by:

# The "-L" option tells "find" to search in symlinks, too
# "! -name "*thumb*" will remove all the files that has "thumb" in the filenames,
# Those are the thumbnails used in SMRT Link web interface but is not useful for us
# on the command line
find -L ./cromwell_out -name '*.png' ! -name '*thumb*'

• Downside of all these? There’s no nice web pages to click and navigate on.
• For even more advanced users, you can customize the pipeline by looking into the WDL workflow, which is out of the scope for our workshop.