...
- Become comfortable with the basic steps of indexing a reference genome, mapping reads, and converting output to
SAM/BAM
format for downstream analysis. - Use bowtie2 to map reads from an E. coli Illumina data set to a reference genome and compare the output.
Theory
Please see the Introduction the Introduction to mapping presentation on presentation on the course outline for more details of the theory behind read mapping algorithms and critical considerations for using these tools and references correctly.
...
While you could consult last year's tutorial for installing bowtie2 via the module system, this year's course will be using the conda system to install it. The bowtie2 home page can be found here, and if you needed to download the program itself, version 2.4.4 could be downloaded here.
Tutorial: E. coli genome re-sequencing data
...
The easiest way to run the tutorial is to copy this entire directory into a new folder called "GVA_bowtie2_mapping" on your $SCRATCH space and then run all of the commands from inside that directory. See if you can figure out how to do that. When you're in the right place, you should get output like this from the ls
command.
Code Block |
---|
tacc(GVA2021) tacc:/scratch/<#>/<UserName>/GVA_bowtie2_mapping$ ls
NC_012967.1.gbk SRR030257_1.fastq SRR030257_2.fastq SRR030257_2.fastq.gz
|
...
Warning |
---|
title | Beware the cat command when working with NGS data |
---|
|
NGS data can be quite large, a single lane of an Illumina Hi-Seq run generates 2 files each with 100s of millions of lines. Printing all of that can take an enormous amount of time and will likely crash your terminal long before it finishes. If you find yourself in a seemingly endless scroll of sequence (or anything else for that matter) remember control+c will kill whatever command you just executed. If hitting control+c several times doesn't work, control +z will stop the process, you then need to kill the process using kill %1 if control+z doesn't work, you may be best off closing the window, opening a new window, logging back in, and picking up where you left off. Note that for the purpose of this class, you should make sure to restart an idev session. |
Remember, from the introduction tutorial, there are multiple ways to look at our sequencing files without using cat:
...
Occasionally you might download a sequence or have it emailed to you by a collaborator in one format, and then the program that you want to use demands that it be in another format. Why do they have to be so picky? Everybody has own favorite formats and/or those that they are the most familiar with but humans can typically pick the information they need out of comparable formats. Programs can only be written to assume a single type of format (or allow you to specify a format if the author is particularly generous), and can only find things in single locations based on that format.
The bp_seqconvert.pl
script is a common script written in Bioperl that is a helpful utility for converting between many common sequence formats. On TACC, the Bioperl modules are installed, but the helper script isn't. So, we've put it in a place that you can run it from for your convenience. However, remember that any time that you use the script you must have the bioperl module loaded. As it is fairly rare that you need to convert sequence files between different format, bioperl is actually not listed as one of the modules on your .bashrc file in your $HOME directory that you set up yesterday. Additionally it gives an opportunity to have you working with the module system. If you find yourself needing to do lots of sequence conversions, you may want to add a 'module load bioperl/1.007002' line to your .bashrc file.
Run the script without any arguments to get the help message:
Code Block |
---|
module load gcc
module load bioperl
bp_seqconvert.pl
|
Convert a gbk reference to a embl reference
Convert the Genbank file NC_012967.1.gbk
to EMBL
format, and name this new file NC_012967.1.embl
.
Code Block |
---|
language | bash |
---|
title | Try reading through the program help when you run the bp_seqconvert.pl without any options to see the syntax required |
---|
collapse | true |
---|
|
bp_seqconvert.pl --from genbank --to embl < NC_012967.1.gbk > NC_012967.1.embl
head -n 100 NC_012967.1.embl
|
Info |
---|
It is somewhat frustrating or confusing that this command does not give us any output saying it was successful. The fact that you get your prompt back is often the only sign the computer has finished doing something. Last year some students were getting the following error message when they execute this command even though the new file seems to be generated correctly. As I am not able to reconstruct the error, please send a message or say something on zoom if you do encounter it so I know it is still present Code Block |
---|
Use of uninitialized value in substitution (s///) at /opt/apps/bioperl/1.6.901/Bio/SeqIO/embl.pm line 777, <STDIN> line 164674.
Use of uninitialized value in concatenation (.) or string at /opt/apps/bioperl/1.6.901/Bio/SeqIO/embl.pm line 779, <STDIN> line 164674. |
|
Expand |
---|
title | Does EMBL format have sequence features (like genes) annotated? The answer is near the top of the file but not within the first 10 lines. DO NOT check with the cat command. |
---|
|
Code Block |
---|
language | bash |
---|
title | Using the head to check the first 100 lines |
---|
| head -n 100 NC_012967.1.embl
|
Code Block |
---|
language | bash |
---|
title | Using the less command |
---|
| less NC_012967.1.embl
|
Code Block |
---|
language | bash |
---|
title | Using the more command |
---|
| more NC_012967.1.embl
|
remember that you can quit the less and more views with the q key. |
Converting from fastq to fasta format
Sometimes you only want to work with a subset of a full data file to check for overall trends, or to try out a new piece of code. Convert only the first 10,000 lines of SRR030257_1.fastq
to FASTA
format.
Code Block |
---|
language | bash |
---|
title | Remember you can use the "|" character to have the output of head feed directly into the bp_seqconvert.pl script. |
---|
|
head -n 10000 SRR030257_1.fastq | bp_seqconvert.pl --from fastq --to fasta > SRR030257_1.fasta
|
Expand |
---|
title | What information was lost by this conversion? Use the head command to look at the top of both the .fastq and .fasta file |
---|
|
Code Block |
---|
| head SRR030257_1.fastq
head SRR030257_1.fasta |
The line of ASCII characters was lost. Remember, those are your "base quality scores". Many mappers will use the base quality scores to improve how the reads are aligned by not placing as much emphasis on poor bases. |
Mapping with bowtie2
Bowtie2 is a complete rewrite of an older program bowtie. In terms of configurability, sensitivity, and speed it is useful for a wide range of projects. After years of teaching bwa mapping along with bowtie2, bowtie2 alone is now taught as I never recommend anyone use bwa, and based on positive feedback we continue with this set up. For some more details about how read mappers work see the bonus presentation about read mapping details and file formats on the course home page, and if you find a compelling reason to use bwa (or any other read mapper) rather than bowtie2 after the course is over, I'd love to hear from you.
Create a fresh output directory named bowtie2. We are going to create a specific output directory for the bowtie2 mapper within the directory that has the input files so that you can compare the results of other mappers if you choose to do the other tutorials.
Code Block |
---|
language | bash |
---|
title | Commands for making a directory named bowtie2 |
---|
collapse | true |
---|
|
mkdir bowtie2 |
First you need to convert the reference file from GenBank to FASTA using what you learned above. Name the new output file NC_012967.1.fasta
and put it in the same directory as NC_012967.1.gbk
.
Code Block |
---|
language | bash |
---|
title | Use the information you you learned above working with the bp_seqconvert.pl script to convert the entire .gbk file into a .fa file |
---|
collapse | true |
---|
|
bp_seqconvert.pl --from genbank --to fasta < NC_012967.1.gbk > NC_012967.1.fasta
|
Next, we want to make sure the bowtie2 module is loaded (we use module spider
to get the current name, which may not be bowtie/2.3.4
if you re-run this tutorial later):
Expand |
---|
title | Click here for a hint without the answer and some links back to where you would have learned this previously |
---|
|
Remember in our earlier tutorial we discussed the use of lonestar's module commands "spider" and "load" to install new functionality and "list", "keyword", and "avail" to find different modules. Code Block |
---|
language | bash |
---|
title | click here for the best answer |
---|
collapse | true |
---|
| module list bowtie |
|
Code Block |
---|
language | bash |
---|
title | Unexpected output |
---|
|
# Currently Loaded Modules Matching: bowtie
# None found.
# Inactive Modules Matching: bowtie
# 1) bowtie/2.3.4 |
Further, when we try to load bowtie/2.3.4 we get an error message.
Code Block |
---|
|
Lmod has detected the following error: These module(s) or extension(s) exist but cannot be loaded as requested: "bowtie/2.3.4"
Try: "module spider bowtie/2.3.4" to see how to load the module(s). |
See if you can figure out how to load bowtie using the information above.
Code Block |
---|
language | bash |
---|
title | Click here for answer |
---|
collapse | true |
---|
|
module load intel/18.0.2
module load bowtie/2.3.4 |
Expand |
---|
title | You may be wondering how bowtie was inactivated. |
---|
|
When we loaded the bioperl module we first loaded the gcc compiler which unloaded several other modules (such as bowtie) which require the intel compiler to function. If you now try to load bioperl you'll see that it loads without requiring the gcc compiler. This was done deliberately to introduce you to another quirk of the module system. Hopefully the error messages were informative enough to help you work through how to get the modules to work. Despite these quirks, this is still far easier to deal with than issues that can arise when installing other programs on tacc or your personal computer. |
Expand |
---|
title | OPTIONAL -- How to check what version of bowtie2 was loaded? |
---|
|
Here are a few of the possibilities that will work. Code Block |
---|
language | bash |
---|
title | In this case all of these methods will work, that may not be true of all programs |
---|
| module list
bowtie2 --version
which bowtie2 |
Many programs have --version or -v options that can be passed to them to specifically print the version of the program and sometimes information about what papers the authors would like you to cite if you use the program. which can be very useful for making sure you are running the executable that you think you are running, especially if you install your own programs. In particular make sure that the path matches up to what you expect. The most common situations arise from wanting to run a simplistically named script in your $HOME directory conflicting with something of the same name in the $BI directories or TACC modules.
|
For many read mappers, the first step is quite often indexing the reference file regardless of what mapping program is used. Put the output of this command into the bowtie
directory we created a minute ago. The command you need is:
Try typing this alone in the terminal and figuring out what to do from the help show just from typing the command by itself.
Expand |
---|
title | If you're stuck click here for an explanation of what arguments the command does need |
---|
|
The command requires 2 arguments. The first argument is the reference FASTA. The second argument is the "base" file name to use for the created index files. It will create a bunch of files beginning bowtie/NC_012967.1*. |
Code Block |
---|
language | bash |
---|
title | Click here to check your work, or for the answer if needed |
---|
collapse | true |
---|
|
bowtie2-build NC_012967.1.fasta bowtie2/NC_012967.1
|
Take a look at your output directory using ls bowtie2
to see what new files have appeared. These files are binary files, so looking at them with head
or tail isn't instructive and can cause issues with your terminal. If you insist on looking at them (or accidentally do so before you read this) and your terminal begins behaving oddly, simply close it and log back into lonestar with a new terminal, and start a new idev session.
Info |
---|
title | you may be wondering why creating an index is a common first step for many different mapping programs. |
---|
|
Like an index for a book (in the olden days before Kindles and Nooks), creating an index for a computer database allows quick access to any "record" given a short "key". In the case of mapping programs, creating an index for a reference sequence allows it to more rapidly place a read on that sequence at a location where it knows at least a piece of the read matches perfectly or with only a few mismatches. By jumping right to these spots in the genome, rather than trying to fully align the read to every place in the genome, it saves a ton of time. Indexing is a separate step in running most mapping programs because it can take a LONG time if you are indexing a very large genome (like our own overly complicated human genome). Furthermore, you only need to index a genome sequence once, no matter how many samples you want to map. Keeping it as a separate step means that you can skip it later when you want to align a new sample to the same reference sequence. |
Finally, it's time to map the reads!
Code Block |
---|
language | bash |
---|
title | Again, try reading the help for the bowtie2 command to figure out how to run the command yourself. Remember these are paired-end reads. |
---|
collapse | true |
---|
|
bowtie2
|
Warning |
---|
|
This command can take a while (~5 minutes) and is extremely taxing. This is longer than we want to run a job on the head node (especially when all of us are doing it at once). In fact, in previous years, TACC has noticed the spike in usage when multiple students forgot to make sure they were on idev nodes and complained pretty forcefully to us about it. Let's not have this be one of those years. Use the showq -u command to make sure you are on an idev node. If you are not sure if you are on an idev node, speak up on zoom and I'll show(q) -u what you are looking for. Yes, your instructor likes bad puns. My apologies. If you are not on an idev node, and need help to relaunch it, click over to the idev tutorial. |
Code Block |
---|
language | bash |
---|
title | Solution |
---|
collapse | true |
---|
|
bowtie2 -t -x bowtie2/NC_012967.1 -1 SRR030257_1.fastq -2 SRR030257_2.fastq -S bowtie2/SRR030257.sam # the -t command is not required for the mapping, but it can be particularly informative when you begin comparing different mappers |
Your final output file is in SAM format. It's just a text file, so you can peek at it and see what it's like inside. Two warnings though:
- SAM files can be enormously humongous text files (potentially >1 gigabytes). Attempting to open the entire file at once can cause your computer to lock up or your text editor to crash. You are generally safer only looking at a portion at a time using linux commands like
head
or grep
or more or using a viewer like IGV, which we will cover in a later tutorial. - SAM files have some rather complicated information encoded as text, like a binary encoded FLAGS field and CIGAR strings. We'll take a look at some of these later, if we have time, or they are covered in the bonus presentation about read mapping and file formats which you can find on the home page.
Still, you should recognize some of the information on a line in a SAM file from the input FASTQ, and some of the other information is relatively straightforward to understand, like the position where the read mapped. Give this a try:
Code Block |
---|
head bowtie2/SRR030257.sam |
Expand |
---|
title | What do you think the 4th and 8th columns mean(click for answer)? |
---|
|
If you thought the answer was the mapping coordinates of the read pairs you were right! |
More reading about SAM files
Multithreaded execution
We have actually massively under-utilized Lonestar in this example. We ran the command using only a single processor (a single "thread") rather than the 48 we have available. For programs that support multithreaded execution (and most mappers do because they are obsessed with speed) we could have sped things up by using all 48 processors for the bowtie process.
Expand |
---|
title | See if you can figure out how to re-run this using all 48 processors. Click here for a hint |
---|
|
You need to use the -p , for "processors" option. Since we had 48processors available to our job. Code Block |
---|
language | bash |
---|
title | click here to check your answer |
---|
collapse | true |
---|
| bowtie2 -t -p 48 -x bowtie2/NC_012967.1 -1 SRR030257_1.fastq -2 SRR030257_2.fastq -S bowtie2/SRR030257.sam
|
Try it out and compare the speed of execution by looking at the log files. Expand |
---|
title | How much faster was it using all 48 processors? |
---|
| 1 processor took a little over 5 minutes, 48 processors took ~ 15 seconds. Can you think of any reasons why it was ~ 16x faster rather than 48x faster? Expand |
---|
| Anytime you use multiprocessing correctly things will go faster, but even if a program can divide the input perfectly among all available processors, and combine the outputs back together perfectly, there is "overhead" in dividing things up and recombining them. These are the types of considerations you may have to make with your data: When is it better to give more processors to a single sample? How fast do I actually need the data to come back? |
|
|
If you want to launch many processes as part of one job, so that they are distributed one per node and use the maximum number of processors available, then you need to think about the "wayness" of how you request nodes on Lonestar (we'll go over this more on this on Friday), or make better use of running commands in the background using the & symbol at the end of the command lineWhile you could write your own sequence converter, hopefully it jumps out at you that this is something someone else must have done before. In situations like this, you can often spend a few minutes on google finding a stackoverlow question/answer that deals with something like this. Some will be in reference to how to code such things, but the particularly useful ones will be the ones that point to a program or repository where someone has already done this for you.
In this case the bp_seqconvert.pl perl script is included as part of the bioperl module package. Rather than attempt to find it as part of a conda package, or in some other repository we will use the module version. If needing this script in the future outside of TACC, https://metacpan.org/dist/BioPerl/view/bin/bp_seqconvert.
Code Block |
---|
language | bash |
---|
title | Recall that we have used the which command to determine where executable files are located, and only take 2 pieces of information. |
---|
|
module load bioperl/1.007002
which -a bp_seqconvert.pl |
If you run the which command above outside of an idev session you should see 2 results. If you run from inside an idve node you get 1 result. On the head node (outside idev) 1 that points to the BioITeam near where you keep finding your data (/corral-repl/utexas/BioITeam/) part of the answer as the BioITeam. The "bin" folder specifically is full of binary or (typically small) bash/python/perl/R scripts that someone has written to help the TACC community. The other is in a folder specifically associated with the bioperl module.
Info |
---|
title | Why do you get 2 different results depending on if you are inside or outside of an idev node |
---|
|
This has to do with how compute nodes are configured. On stampede2 /corral-repl/ and all of its subdirectories are not accessible so even though the BioITeam is in your $PATH, on the compute node, the command line can't access it. This is why in later tutorials you have to log out of the idev session to copy new raw data files to work with. |
If you try to run the BioITeam version of the script from the head node /corral-repl/utexas/BioITeam/bin/bp_seqconvert.pl
, you get the following error message:
No Format |
---|
Can't locate Bio/SeqIO.pm in @INC (@INC contains: /corral-repl/utexas/BioITeam//local/share/perl5 /corral-repl/utexas/BioITeam//perl5/lib/perl5/x86_64-linux-thread-multi /corral-repl/utexas/BioITeam//perl5/lib/perl5 /corral-repl/utexas/BioITeam//perl5/lib64/perl5/auto /usr/local/lib64/perl5 /usr/local/share/perl5 /usr/lib64/perl5/vendor_perl /usr/share/perl5/vendor_perl /usr/lib64/perl5 /usr/share/perl5 .) at /corral-repl/utexas/BioITeam/bin/bp_seqconvert.pl line 8.
BEGIN failed--compilation aborted at /corral-repl/utexas/BioITeam/bin/bp_seqconvert.pl line 8. |
Info |
---|
title | Deciphering error messages |
---|
|
The above error message is pretty helpful, but much less so if you are not familiar with perl. As I doubt anyone in the class is more familiar with perl than I am, and I am not familiar with perl hardly at all, this is a great opportunity to explain how I would tackle the error message to figure out what is going on. - "compilation aborted at /corral-repl/utexas/BioITeam/bin/bp_seqconvert.pl line 8."
- The last line here actually tells us that the script did not get very far, only to line 8.
- My experience with other programing language tells me that the beginning of scripts is all about checking that the script has access to all the things it needs to do what it is intended to do, so this has me thinking some kind of package might be missing.
- "(
@INC contains: ... "- This reads like the PATH variable, but is locations I don't recognize as being in my path, suggesting this is not some external binary or other program.
- Many of the individual pathways list "lib" in one form or another. This reinforces the idea from above that some kind of package is missing.
- "Can't locate Bio/SeqIO.pm in @INC"
- "Can't locate" reads like a plain text version of something being missing, and like something generic that is not related to my system/environment (like all the listed directories), and not related to the details of the script I am trying to run (like the last line that details the name of the script we tried to envoke)
- This is what should be googled for help solving the problem.
- the google results list similar error messages associated with different repositories/programs (github issues) suggesting some kind of common underlying problem.
- The 3rd result https://www.biostars.org/p/345331/ reads like a generic problem and sure enough the answers detail needing to have the Bio library installed from cpan (perl's package management system)
|
We get this error message because on stampede2, while perl is installed, the required bioperl module is not loaded by default. Rather than having to actually install the library yourself (as we will do for several libraries in the SVDetect tutorial later today), we are lucky that TACC has a bioperl module. So, you must have the bioperl module loaded before the script will run. As it is fairly rare that you need to convert sequence files between different format, bioperl is actually not listed as one of the modules on your .bashrc file in your $HOME directory that you set up yesterday. Additionally it gives an opportunity to have you working with the module system.
After loading the bioperl library to get past the error message, run the script from the BioITeam without any arguments to get the help message:
Code Block |
---|
module load bioperl
/corral-repl/utexas/BioITeam/bin/bp_seqconvert.pl
|
If you find yourself needing to do lots of sequence conversions, and find the bp_seqconvert.pl script useful to do them, you may want to add a 'module load bioperl/1.007002' line to your .bashrc file. Recall that because the bp_seqconvert.pl script exists in 2 different locations as 2 different copies only the first one in the PATH variable will be used. Using the which -a
command you see the copy used will be the module version unless you specifically envoke the BioITeam version. In this case it does not matter as the scripts are the same.
Convert a gbk reference to a embl reference
Convert the Genbank file NC_012967.1.gbk
to EMBL
format, and name this new file NC_012967.1.embl
.
Code Block |
---|
language | bash |
---|
title | Try reading through the program help when you run the bp_seqconvert.pl without any options to see the syntax required |
---|
collapse | true |
---|
|
bp_seqconvert.pl --from genbank --to embl < NC_012967.1.gbk > NC_012967.1.embl
head -n 100 NC_012967.1.embl
|
Info |
---|
It is somewhat frustrating or confusing that this command does not give us any output saying it was successful. The fact that you get your prompt back is often the only sign the computer has finished doing something. |
Expand |
---|
title | Does EMBL format have sequence features (like genes) annotated? The answer is near the top of the file but not within the first 10 lines. DO NOT check with the cat command. |
---|
|
Code Block |
---|
language | bash |
---|
title | Using the head to check the first 100 lines |
---|
| head -n 100 NC_012967.1.embl
|
Code Block |
---|
language | bash |
---|
title | Using the less command |
---|
| less NC_012967.1.embl
|
Code Block |
---|
language | bash |
---|
title | Using the more command |
---|
| more NC_012967.1.embl
|
remember that you can quit the less and more views with the q key. |
Converting from fastq to fasta format
Sometimes you only want to work with a subset of a full data file to check for overall trends, or to try out a new piece of code. Convert only the first 10,000 lines of SRR030257_1.fastq
to FASTA
format.
Code Block |
---|
language | bash |
---|
title | Remember you can use the "|" character to have the output of head feed directly into the bp_seqconvert.pl script. |
---|
|
head -n 10000 SRR030257_1.fastq | bp_seqconvert.pl --from fastq --to fasta > SRR030257_1.fasta
|
Expand |
---|
title | What information was lost by this conversion? Use the head command to look at the top of both the .fastq and .fasta file |
---|
|
Code Block |
---|
| head SRR030257_1.fastq
head SRR030257_1.fasta |
The line of ASCII characters was lost. Remember, those are your "base quality scores". Many mappers will use the base quality scores to improve how the reads are aligned by not placing as much emphasis on poor bases. |
Mapping with bowtie2
Bowtie2 is a complete rewrite of an older program bowtie. In terms of configurability, sensitivity, and speed it is useful for a wide range of projects. After years of teaching bwa mapping along with bowtie2, bowtie2 alone is now taught as I never recommend anyone use bwa, and based on positive feedback we continue with this set up. For some more details about how read mappers work see the bonus presentation about read mapping details and file formats on the course home page, and if you find a compelling reason to use bwa (or any other read mapper) rather than bowtie2 after the course is over, I'd love to hear from you.
Create a fresh output directory named bowtie2. We are going to create a specific output directory for the bowtie2 mapper within the directory that has the input files so that you can compare the results of other mappers if you choose to do the other tutorials.
Code Block |
---|
language | bash |
---|
title | Commands for making a directory named bowtie2 |
---|
collapse | true |
---|
|
mkdir bowtie2 |
First you need to convert the reference file from GenBank to FASTA using what you learned above. Name the new output file NC_012967.1.fasta
and put it in the same directory as NC_012967.1.gbk
.
Code Block |
---|
language | bash |
---|
title | Use the information you you learned above working with the bp_seqconvert.pl script to convert the entire .gbk file into a .fa file |
---|
collapse | true |
---|
|
bp_seqconvert.pl --from genbank --to fasta < NC_012967.1.gbk > NC_012967.1.fasta
|
Bowtie2 installation
While you could consult last year's tutorial for installing bowtie2 via the module system, this year's course will be using the conda system to install it. The bowtie2 home page can be found here, and if you needed to download the program itself, version 2.4.4 could be downloaded here. Instead, we want to make sure the bowtie2 is installed via conda Like we did for fastqc and cutadapt. See if you can figure out how to install bowtie2. Note that "2" is actually part of the name, neither a typo nor a comment on the program version.
Expand |
---|
title | Click here for a hint before the answer. |
---|
|
Remember that we want to use the https://anaconda.org/ search function and end up at the bowtie2 page: https://anaconda.org/bioconda/bowtie2 Code Block |
---|
language | bash |
---|
title | Remember, you likely need to specify the channel bowtie2 is in using the -c command |
---|
collapse | true |
---|
| conda install -c bioconda bowtie2
# enter "y" to approve the installation |
|
Expand |
---|
title | OPTIONAL -- How to check what version of bowtie2 was loaded? |
---|
|
Remember yesterday we did the same thing with cutadapt. Code Block |
---|
language | bash |
---|
title | Recall many programs have a --version flag that can be used to retrieve this information, and conda has a 'list' function that takes additional optional arguments |
---|
collapse | true |
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| bowtie2 --version
conda list bowtie2 |
The above should show you now have access to version 2.3.5.1. If you have a different version listed (such as 2.3.2) make sure you are using the conda installation and not relying on the TACC module, and then get my attention for clarification. |
For many read mappers, the first step is quite often indexing the reference file regardless of what mapping program is used. Put the output of this command into the bowtie
directory we created a minute ago. The command you need is:
Try typing this alone in the terminal and figuring out what to do from the help show just from typing the command by itself.
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title | If you're stuck click here for an explanation of what arguments the command does need |
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The command requires 2 arguments. The first argument is the reference sequence in FASTA format. The second argument is the "base" file name to use for the created index files. It will create a bunch of files beginning bowtie/NC_012967.1*. |
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language | bash |
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title | Click here to check your work, or for the answer if needed |
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collapse | true |
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bowtie2-build NC_012967.1.fasta bowtie2/NC_012967.1
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Take a look at your output directory using ls bowtie2
to see what new files have appeared. These files are binary files, so looking at them with head
or tail isn't instructive and can cause issues with your terminal. If you insist on looking at them (or accidentally do so before you read this) and your terminal begins behaving oddly, simply close it and log back into stampede2 with a new terminal, and start a new idev session.
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title | you may be wondering why creating an index is a common first step for many different mapping programs. |
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Like an index for a book (in the olden days before Kindles and Nooks), creating an index for a computer database allows quick access to any "record" given a short "key". In the case of mapping programs, creating an index for a reference sequence allows it to more rapidly place a read on that sequence at a location where it knows at least a piece of the read matches perfectly or with only a few mismatches. By jumping right to these spots in the genome, rather than trying to fully align the read to every place in the genome, it saves a ton of time. Indexing is a separate step in running most mapping programs because it can take a LONG time if you are indexing a very large genome (like our own overly complicated human genome). Furthermore, you only need to index a genome sequence once, no matter how many samples you want to map. Keeping it as a separate step means that you can skip it later when you want to align a new sample to the same reference sequence. |
Finally, it's time to map the reads!
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language | bash |
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title | Again, try reading the help for the bowtie2 command to figure out how to run the command yourself. Remember these are paired-end reads. |
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bowtie2
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Warning |
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This command can take a while (~5 minutes) and is extremely taxing. This is longer than we want to run a job on the head node (especially when all of us are doing it at once). In fact, in previous years, TACC has noticed the spike in usage when multiple students forgot to make sure they were on idev nodes and complained pretty forcefully to us about it. Let's not have this be one of those years. Use the hostname or showq -u command to make sure you are on an idev node. Command | on idev node | on head node |
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hostname | lists a compute node starting with a C followed by a number before "stampede2.tacc.utexas.edu" | lists a login node plus number before "stampede2.tacc.utexas.edu" | showq -u | -bash: showq: command not found | shows you a summary of jobs you have. (very likely empty during these tutorials) |
If you are not sure if you are on an idev node or are seeing other output with one or both commands, speak up on zoom and I'll show(q) -u what you are looking for. Yes, your instructor likes bad puns. My apologies. If you are not on an idev node, and need help to relaunch it, click over to the idev tutorial. |
It is important that you use 8 processors when doing this mapping due to course time constraints.
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language | bash |
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title | Solution |
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bowtie2 -t -p 8 -x bowtie2/NC_012967.1 -1 SRR030257_1.fastq -2 SRR030257_2.fastq -S bowtie2/SRR030257.sam
# the -t command is not required for the mapping, but it can be particularly informative when you begin comparing different mappers |
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Command portion | Purpose |
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-t | Print wall clock time each step takes. | -p 8 | Use 8 processors. As discussed above and below this is selected so the command will finish in a reasonable amount of time | -x bowtie2/NC_012967.1 | listing the location and name of the index we created above with the bowtie2-build command | -1 SRR030257_1.fastq | Read 1 file name (note if not using the -1 and -2 options reads would not be mapped in paired end mode) | -2 SRR030257_2.fastq | Read 2 file name (note if not using the -1 and -2 options reads would not be mapped in paired end mode) | -S bowtie2/SRR030257.sam | Output mapped reads in sam format at given location with given name |
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Your final output file is in SAM format. It's just a text file, so you can peek at it and see what it's like inside. Two warnings though:
- SAM files can be enormously humongous text files (potentially measured in gigabytes). Attempting to open the entire file at once can cause your computer to lock up or your text editor to crash. You are generally safer only looking at a portion at a time using linux commands like
head
or grep
or more or using a viewer like IGV, which we will cover in a later tutorial. - SAM files have some rather complicated information encoded as text, like a binary encoded FLAGS field and CIGAR strings. We'll take a look at some of these later, if we have time, or they are covered in the bonus presentation about read mapping and file formats which you can find on the home page.
Still, you should recognize some of the information on a line in a SAM file from the input FASTQ, and some of the other information is relatively straightforward to understand, like the position where the read mapped. Give this a try:
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head bowtie2/SRR030257.sam |
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title | What do you think the 4th and 8th columns mean(click for answer)? |
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If you thought the answer was the mapping coordinates of the read pairs you were right! |
More reading about SAM files
Multithreaded execution
We have actually massively under-utilized stampede2 in this example by only using 8 cores. We ran the command using only 8 processors rather than the 68 we have available on our idev session. if we increase to 68 total processors and rerun the analysis, how long do you expect the command to take?
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title | Modify the previous mapping command to re-run this analysis using all 68 cores. |
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You need to increase the -p , for "processors" option from 8 to 68. Code Block |
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language | bash |
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title | click here to check your answer |
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| bowtie2 -t -p 68 -x bowtie2/NC_012967.1 -1 SRR030257_1.fastq -2 SRR030257_2.fastq -S bowtie2/SRR030257.sam
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Try it out and compare the speed of execution by looking at the times listed at the end of each command Expand |
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title | How much faster was it using all 68 processors? |
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| 8 processor took a little over 5 minutes, 68 processors took ~1 minute. Can you think of any reasons why it was ~ 5x faster rather than ~8x faster? Expand |
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| Anytime you use multiprocessing correctly things will go faster, but even if a program can divide the input perfectly among all available processors, and combine the outputs back together perfectly, there is "overhead" in dividing things up and recombining them. These are the types of considerations you may have to make with your data: When is it better to give more processors to a single sample? How fast do I actually need the data to come back?
An additional note from the stampede2 user manual is that while there are 68 cores available, and each core is capable of hyperthreading 4 x processors per core using all 272 processors is rarely the go to solution. While I am sure that this is more rigorously and appropriately tested in some other manner, I ran a test using different numbers of processors with the following results: -p option | time (min:sec) |
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272 | 1:54 | 136 | 1:13 | 68 | 0:57 | 34 | 1:14 | 17 | 2:25 | 8 | 5:12 | 4 | 9:01 | 2 | 18:13 | 1 | 35:01 |
Again while there are almost certainly better ways to benchmark this, there are 2 things of note that are illustrated here: - ~doubling the number of processors does not reduce the time in half, and while some applications may use hyperthreading on the individual cores appropriately, and assuming a program can/will actually makes things take longer.
- Working on your laptop (which likely has at most 4-8 processors available) would significantly increase the amount of time these tutorials take.
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One consequence of using multithreading that might be confusing is that the aligned reads might appear in your output SAM file in a different order than they were in the input FASTQ. This happens because small sets of reads get continuously packaged, "sent" to the different processors, and whichever set "returns" fastest is written first. You can force them to appear in the same order (at a slight cost in speed) by adding the --reorder
flag to your command, but is typically only necessary if the reads are already ordered or you intend to do some comparison between the input and output (something I have never done in my own work).
What comes after mapping?
...
In the bowtie2 example, we mapped in --local
mode. Try mapping in --end-to-end
mode (aka global mode).
- Do the BWA tutorial so you can compare their outputs (note BWA has a conda package making it even easier to try).
- Did bowtie2 or BWA map more reads?
- In our examples, we mapped in paired-end mode. Try to figure out how to map the reads in single-end mode and create this output.
- Which aligner took less time to run? Are there any options you can change that:
- Lead to a larger percentage of the reads being mapped? (increase sensitivity)
- Speed up run time without causing many fewer reads to be mapped? (increase performance)
Here is a link to help you return to the GVA 2020 2021 course schedule.