Assessing Read Quality
Overview
Teaching: 30 min
Exercises: 20 minQuestions
How can I describe the quality of my data?
Objectives
Explain how a FASTQ file encodes per-base quality scores.
Interpret a FastQC plot summarizing per-base quality across all reads.
Use
for
loops to automate operations on multiple files.
Bioinformatics workflows
When working with high-throughput sequencing data, the raw reads you get off of the sequencer will need to pass through a number of different tools in order to generate your final desired output. The execution of this set of tools in a specified order is commonly referred to as a workflow or a pipeline.
An example of the workflow we will be using for our variant calling analysis is provided below with a brief description of each step.
- Quality control - Assessing quality using FastQC
- Quality control - Trimming and/or filtering reads (if necessary)
- Align reads to reference genome
- Perform post-alignment clean-up
- Variant calling
These workflows in bioinformatics adopt a plug-and-play approach in that the output of one tool can be easily used as input to another tool without any extensive configuration. Having standards for data formats is what makes this feasible. Standards ensure that data is stored in a way that is generally accepted and agreed upon within the community. The tools that are used to analyze data at different stages of the workflow are therefore built under the assumption that the data will be provided in a specific format.
Starting with Data
Often times, the first step in a bioinformatics workflow is getting the data you want to work with onto a computer where you can work with it. If you have sequenced your own data, the sequencing center will usually provide you with a link that you can use to download your data. Today we will be working with publicly available sequencing data.
We are studying a population of Escherichia coli (designated Ara-3), which were propagated for more than 50,000 generations in a glucose-limited minimal medium. We will be working with three samples from this experiment, one from 5,000 generations, one from 15,000 generations, and one from 50,000 generations. The population changed substantially during the course of the experiment, and we will be exploring how with our variant calling workflow.
The data are paired-end, so we will download two files for each sample. We will use the European Nucleotide Archive to get our data. The ENA “provides a comprehensive record of the world’s nucleotide sequencing information, covering raw sequencing data, sequence assembly information and functional annotation.” The ENA also provides sequencing data in the fastq format, an important format for sequencing reads that we will be learning about today.
To download the data, run the commands below. It will take about 10 minutes to download the files.
mkdir -p ~/dc_workshop/data/untrimmed_fastq/
cd ~/dc_workshop/data/untrimmed_fastq
curl -O ftp://ftp.sra.ebi.ac.uk/vol1/fastq/SRR258/004/SRR2589044/SRR2589044_1.fastq.gz
curl -O ftp://ftp.sra.ebi.ac.uk/vol1/fastq/SRR258/004/SRR2589044/SRR2589044_2.fastq.gz
curl -O ftp://ftp.sra.ebi.ac.uk/vol1/fastq/SRR258/003/SRR2584863/SRR2584863_1.fastq.gz
curl -O ftp://ftp.sra.ebi.ac.uk/vol1/fastq/SRR258/003/SRR2584863/SRR2584863_2.fastq.gz
curl -O ftp://ftp.sra.ebi.ac.uk/vol1/fastq/SRR258/006/SRR2584866/SRR2584866_1.fastq.gz
curl -O ftp://ftp.sra.ebi.ac.uk/vol1/fastq/SRR258/006/SRR2584866/SRR2584866_2.fastq.gz
The data comes in a compressed format, which is why there is a .gz
at the end of the file names. This makes it faster to transfer, and allows it to take up less space on our computer. Let’s unzip one of the files so that we can look at the fastq format.
$ gunzip SRR2584863_1.fastq.gz
Quality Control
We will now assess the quality of the sequence reads contained in our fastq files.
Details on the FASTQ format
Although it looks complicated (and it is), we can understand the fastq format with a little decoding. Some rules about the format include…
Line | Description |
---|---|
1 | Always begins with ‘@’ and then information about the read |
2 | The actual DNA sequence |
3 | Always begins with a ‘+’ and sometimes the same info in line 1 |
4 | Has a string of characters which represent the quality scores; must have same number of characters as line 2 |
We can view the first complete read in one of the files our dataset by using head
to look at
the first four lines.
$ head -n 4 SRR2584863_1.fastq
@SRR2584863.1 HWI-ST957:244:H73TDADXX:1:1101:4712:2181/1
TTCACATCCTGACCATTCAGTTGAGCAAAATAGTTCTTCAGTGCCTGTTTAACCGAGTCACGCAGGGGTTTTTGGGTTACCTGATCCTGAGAGTTAACGGTAGAAACGGTCAGTACGTCAGAATTTACGCGTTGTTCGAACATAGTTCTG
+
CCCFFFFFGHHHHJIJJJJIJJJIIJJJJIIIJJGFIIIJEDDFEGGJIFHHJIJJDECCGGEGIIJFHFFFACD:BBBDDACCCCAA@@CA@C>C3>@5(8&>C:9?8+89<4(:83825C(:A#########################
Line 4 shows the quality for each nucleotide in the read. Quality is interpreted as the probability of an incorrect base call (e.g. 1 in 10) or, equivalently, the base call accuracy (e.g. 90%). To make it possible to line up each individual nucleotide with its quality score, the numerical score is converted into a code where each individual character represents the numerical quality score for an individual nucleotide. For example, in the line above, the quality score line is:
CCCFFFFFGHHHHJIJJJJIJJJIIJJJJIIIJJGFIIIJEDDFEGGJIFHHJIJJDECCGGEGIIJFHFFFACD:BBBDDACCCCAA@@CA@C>C3>@5(8&>C:9?8+89<4(:83825C(:A#########################
The numerical value assigned to each of these characters depends on the sequencing platform that generated the reads. The sequencing machine used to generate our data uses the standard Sanger quality PHRED score encoding, using by Illumina version 1.8 onwards. Each character is assigned a quality score between 0 and 40 as shown in the chart below.
Quality encoding: !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHI
| | | | |
Quality score: 0........10........20........30........40
Each quality score represents the probability that the corresponding nucleotide call is incorrect. This quality score is logarithmically based, so a quality score of 10 reflects a base call accuracy of 90%, but a quality score of 20 reflects a base call accuracy of 99%. These probability values are the results from the base calling algorithm and dependent on how much signal was captured for the base incorporation.
Looking back at our read:
@SRR2584863.1 HWI-ST957:244:H73TDADXX:1:1101:4712:2181/1
TTCACATCCTGACCATTCAGTTGAGCAAAATAGTTCTTCAGTGCCTGTTTAACCGAGTCACGCAGGGGTTTTTGGGTTACCTGATCCTGAGAGTTAACGGTAGAAACGGTCAGTACGTCAGAATTTACGCGTTGTTCGAACATAGTTCTG
+
CCCFFFFFGHHHHJIJJJJIJJJIIJJJJIIIJJGFIIIJEDDFEGGJIFHHJIJJDECCGGEGIIJFHFFFACD:BBBDDACCCCAA@@CA@C>C3>@5(8&>C:9?8+89<4(:83825C(:A#########################
we can now see that there are a range of quality score, but that the end of the sequence
very poor (#
= a quality score of 2).
Exercise
What is the last read in the
SRR2584863_1.fastq
file? How confident are you in this read?Solution
$ tail -n 4 SRR2584863_1.fastq
@SRR2584863.1553259 HWI-ST957:245:H73R4ADXX:2:2216:21048:100894/1 CTGCAATACCACGCTGATCTTTCACATGATGTAAGAAAAGTGGGATCAGCAAACCGGGTGCTGCTGTGGCTAGTTGCAGCAAACCATGCAGTGAACCCGCCTGTGCTTCGCTATAGCCGTGACTGATGAGGATCGCCGGAAGCCAGCCAA + CCCFFFFFHHHHGJJJJJJJJJHGIJJJIJJJJIJJJJIIIIJJJJJJJJJJJJJIIJJJHHHHHFFFFFEEEEEDDDDDDDDDDDDDDDDDCDEDDBDBDDBDDDDDDDDDBDEEDDDD7@BDDDDDD>AA>?B?<@BDD@BDC?BDA?
This read has more consistent quality at its end than the first read that we looked at, but still has a range of quality scores, most of them high. We will look at variations in position-based quality in just a moment.
Assessing Quality using FastQC
In real life, you won’t be assessing the quality of your reads by visually inspecting your FASTQ files. Rather, you’ll be using a software program to assess read quality and filter out poor quality reads. We’ll first use a program called FastQC to visualize the quality of our reads. Later in our workflow, we’ll use another program to filter out poor quality reads.
FastQC has a number of features which can give you a quick impression of any problems your data may have, so you can take these issues into consideration before moving forward with your analyses. Rather than looking at quality scores for each individual read, FastQC looks at quality collectively across all reads within a sample. The image below shows one FastQC-generated plot that indicates a very high quality sample:
The x-axis displays the base position in the read, and the y-axis shows quality scores. In this example, the sample contains reads that are 40 bp long. This is much shorter than the reads we are working with in our workflow. For each position, there is a box-and-whisker plot showing the distribution of quality scores for all reads at that position. The horizontal red line indicates the median quality score and the yellow box shows the 2nd to 3rd quartile range. This means that 50% of reads have a quality score that falls within the range of the yellow box at that position. The whiskers show the range to the 1st and 4th quartile.
For each position in this sample, the quality values do not drop much lower than 32. This is a high quality score. The plot background is also color-coded to identify good (green), acceptable (yellow), and bad (red) quality scores.
Now let’s take a look at a quality plot on the other end of the spectrum.
Here, we see positions within the read in which the boxes span a much wider range. Also, quality scores drop quite low into the “bad” range, particularly on the tail end of the reads. The FastQC tool produces several other diagnostic plots to assess sample quality, in addition to the one plotted above.
Running FastQC
We will now assess the quality of the reads that we downloaded. First, make sure you’re still in the untrimmed_fastq
directory
$ cd ~/dc_workshop/data/untrimmed_fastq/
Exercise
How big are the files? (Hint: Look at the options for the
ls
command to see how to show file sizes.)Solution
$ ls -l -h
-rw-rw-r-- 1 dcuser dcuser 545M Jul 6 20:27 SRR2584863_1.fastq -rw-rw-r-- 1 dcuser dcuser 183M Jul 6 20:29 SRR2584863_2.fastq.gz -rw-rw-r-- 1 dcuser dcuser 309M Jul 6 20:34 SRR2584866_1.fastq.gz -rw-rw-r-- 1 dcuser dcuser 296M Jul 6 20:37 SRR2584866_2.fastq.gz -rw-rw-r-- 1 dcuser dcuser 124M Jul 6 20:22 SRR2589044_1.fastq.gz -rw-rw-r-- 1 dcuser dcuser 128M Jul 6 20:24 SRR2589044_2.fastq.gz
There are six FASTQ files ranging from 124M (124MB) to 545M.
FastQC can accept multiple file names as input, and on both zipped and unzipped files, so we can use the *.fastq* wildcard to run FastQC on all of the FASTQ files in this directory.
$ fastqc *.fastq*
You will see an automatically updating output message telling you the progress of the analysis. It will start like this:
Started analysis of SRR2584863_1.fastq
Approx 5% complete for SRR2584863_1.fastq
Approx 10% complete for SRR2584863_1.fastq
Approx 15% complete for SRR2584863_1.fastq
Approx 20% complete for SRR2584863_1.fastq
Approx 25% complete for SRR2584863_1.fastq
Approx 30% complete for SRR2584863_1.fastq
Approx 35% complete for SRR2584863_1.fastq
Approx 40% complete for SRR2584863_1.fastq
Approx 45% complete for SRR2584863_1.fastq
In total, it should take about five minutes for FastQC to run on all six of our FASTQ files. When the analysis completes, your prompt will return. So your screen will look something like this:
Approx 80% complete for SRR2589044_2.fastq.gz
Approx 85% complete for SRR2589044_2.fastq.gz
Approx 90% complete for SRR2589044_2.fastq.gz
Approx 95% complete for SRR2589044_2.fastq.gz
Analysis complete for SRR2589044_2.fastq.gz
$
The FastQC program has created several new files within our
data/untrimmed_fastq/
directory.
$ ls
SRR2584863_1.fastq SRR2584866_1_fastqc.html SRR2589044_1_fastqc.html
SRR2584863_1_fastqc.html SRR2584866_1_fastqc.zip SRR2589044_1_fastqc.zip
SRR2584863_1_fastqc.zip SRR2584866_1.fastq.gz SRR2589044_1.fastq.gz
SRR2584863_2_fastqc.html SRR2584866_2_fastqc.html SRR2589044_2_fastqc.html
SRR2584863_2_fastqc.zip SRR2584866_2_fastqc.zip SRR2589044_2_fastqc.zip
SRR2584863_2.fastq.gz SRR2584866_2.fastq.gz SRR2589044_2.fastq.gz
For each input FASTQ file, FastQC has created a .zip
file and a
.html
file. The .zip
file extension indicates that this is
actually a compressed set of multiple output files. We’ll be working
with these output files soon. The .html
file is a stable webpage
displaying the summary report for each of our samples.
We want to keep our data files and our results files separate, so we
will move these
output files into a new directory within our results/
directory.
$ mkdir -p ~/dc_workshop/results/fastqc_untrimmed_reads
$ mv *.zip ~/dc_workshop/results/fastqc_untrimmed_reads/
$ mv *.html ~/dc_workshop/results/fastqc_untrimmed_reads/
Now we can navigate into this results directory and do some closer inspection of our output files.
$ cd ~/dc_workshop/results/fastqc_untrimmed_reads/
Viewing the FastQC results
If we were working on our local computers, we’d be able to display each of these HTML files as a webpage:
$ open SRR2584863_1_fastqc.html
However, if you try this on our AWS instance, you’ll get an error:
Couldn't get a file descriptor referring to the console
This is because the AWS instance we’re using doesn’t have any web browsers installed on it, so the remote computer doesn’t know how to open the file. We want to look at the webpage summary reports, so let’s transfer them to our local computers (i.e. your laptop).
To transfer a file from a remote server to our own machines, we will
use scp
, which we learned yesterday in the Shell Genomics lesson.
First we will make a new directory on our computer to store the HTML files we’re transfering. Let’s put it on our desktop for now. Open a new tab in your terminal program (you can use the pull down menu at the top of your screen or the Cmd+t keyboard shortcut) and type:
$ mkdir -p ~/Desktop/fastqc_html
Now we can transfer our HTML files to our local computer using scp
.
$ scp dcuser@ec2-34-238-162-94.compute-1.amazonaws.com:~/dc_workshop/results/fastqc_untrimmed_reads/*.html ~/Desktop/fastqc_html
As a reminder, the first part
of the command dcuser@ec2-34-238-162-94.compute-1.amazonaws.com
is
the address for your remote computer. Make sure you replace everything
after dcuser@
with your instance number (the one you used to log in).
The second part starts with a :
and then gives the absolute path
of the files you want to transfer from your remote computer. Don’t
forget the :
. We used a wildcard (*.html
) to indicate that we want all of
the HTML files.
The third part of the command gives the absolute path of the location
you want to put the files. This is on your local computer and is the
directory we just created ~/Desktop/fastqc_html
.
You should see a status output like this:
SRR2584863_1_fastqc.html 100% 249KB 152.3KB/s 00:01
SRR2584863_2_fastqc.html 100% 254KB 219.8KB/s 00:01
SRR2584866_1_fastqc.html 100% 254KB 271.8KB/s 00:00
SRR2584866_2_fastqc.html 100% 251KB 252.8KB/s 00:00
SRR2589044_1_fastqc.html 100% 249KB 370.1KB/s 00:00
SRR2589044_2_fastqc.html 100% 251KB 592.2KB/s 00:00
Now we can go to our new directory and open the HTML files.
$ cd ~/Desktop/fastqc_html/
$ open *.html
Your computer will open each of the HTML files in your default web browser. Depending on your settings, this might be as six separate tabs in a single window or six separate browser windows.
Exercise
Discuss your results with a neighbor. Which sample(s) looks the best in terms of per base sequence quality? Which sample(s) look the worst?
Solution
All of the reads contain usable data, but the quality decreases toward the end of the reads.
Decoding the other FastQC outputs
We’ve now looked at quite a few “Per base sequence quality” FastQC graphs, but there are nine other graphs that we haven’t talked about! Below we have provided a brief overview of interpretations for each of these plots. It’s important to keep in mind
- Per tile sequence quality: the machines that perform sequencing are divided into tiles. This plot displays patterns in base quality along these tiles. Consistently low scores are often found around the edges, but hot spots can also occur in the middle if an air bubble was introduced at some point during the run.
- Per sequence quality scores: a density plot of quality for all reads at all positions. This plot shows what quality scores are most common.
- Per base sequence content: plots the proportion of each base position over all of the reads. Typically, we expect to see each base roughly 25% of the time at each position, but this often fails at the beginning or end of the read due to quality or adapter content.
- Per sequence GC content: a density plot of average GC content in each of the reads.
- Per base N content: the percent of times that ‘N’ occurs at a position in all reads. If there is an increase at a particular position, this might indicate that something went wrong during sequencing.
- Sequence Length Distribution: the distribution of sequence lengths of all reads in the file. If the data is raw, there is often on sharp peak, however if the reads have been trimmed, there may be a distribution of shorter lengths.
- Sequence Duplication Levels: A distribution of duplicated sequences. In sequencing, we expect most reads to only occur once. If some sequences are occurring more than once, it might indicate enrichment bias (e.g. from PCR). If the samples are high coverage (or RNA-seq or amplicon), this might not be true.
- Overrepresented sequences: A list of sequences that occur more frequently than would be expected by chance.
- Adapter Content: a graph indicating where adapater sequences occur in the reads.
Working with the FastQC text output
Now that we’ve looked at our HTML reports to get a feel for the data,
let’s look more closely at the other output files. Go back to the tab
in your terminal program that is connected to your AWS instance
(the tab lab will start with dcuser@ip
) and make sure you’re in
our results subdirectory.
$ cd ~/dc_workshop/results/fastqc_untrimmed_reads/
$ ls
SRR2584863_1_fastqc.html SRR2584866_1_fastqc.html SRR2589044_1_fastqc.html
SRR2584863_1_fastqc.zip SRR2584866_1_fastqc.zip SRR2589044_1_fastqc.zip
SRR2584863_2_fastqc.html SRR2584866_2_fastqc.html SRR2589044_2_fastqc.html
SRR2584863_2_fastqc.zip SRR2584866_2_fastqc.zip SRR2589044_2_fastqc.zip
Our .zip
files are compressed files. They each contain multiple
different types of output files for a single input FASTQ file. To
view the contents of a .zip
file, we can use the program unzip
to decompress these files. Let’s try doing them all at once using a
wildcard.
$ unzip *.zip
Archive: SRR2584863_1_fastqc.zip
caution: filename not matched: SRR2584863_2_fastqc.zip
caution: filename not matched: SRR2584866_1_fastqc.zip
caution: filename not matched: SRR2584866_2_fastqc.zip
caution: filename not matched: SRR2589044_1_fastqc.zip
caution: filename not matched: SRR2589044_2_fastqc.zip
This didn’t work. We unzipped the first file and then got a warning
message for each of the other .zip
files. This is because unzip
expects to get only one zip file as input. We could go through and
unzip each file one at a time, but this is very time consuming and
error-prone. Someday you may have 500 files to unzip!
A more efficient way is to use a for
loop like we learned in the Shell Genomics lesson to iterate through all of
our .zip
files. Let’s see what that looks like and then we’ll
discuss what we’re doing with each line of our loop.
$ for filename in *.zip
> do
> unzip $filename
> done
In this example, the input is six filenames (one filename for each of our .zip
files).
Each time the loop iterates, it will assign a file name to the variable filename
and run the unzip
command.
The first time through the loop,
$filename
is SRR2584863_1_fastqc.zip
.
The interpreter runs the command unzip
on SRR2584863_1_fastqc.zip
.
For the second iteration, $filename
becomes
SRR2584863_2_fastqc.zip
. This time, the shell runs unzip
on SRR2584863_2_fastqc.zip
.
It then repeats this process for the four other .zip
files in our directory.
When we run our for
loop, you will see output that starts like this:
Archive: SRR2589044_2_fastqc.zip
creating: SRR2589044_2_fastqc/
creating: SRR2589044_2_fastqc/Icons/
creating: SRR2589044_2_fastqc/Images/
inflating: SRR2589044_2_fastqc/Icons/fastqc_icon.png
inflating: SRR2589044_2_fastqc/Icons/warning.png
inflating: SRR2589044_2_fastqc/Icons/error.png
inflating: SRR2589044_2_fastqc/Icons/tick.png
inflating: SRR2589044_2_fastqc/summary.txt
inflating: SRR2589044_2_fastqc/Images/per_base_quality.png
inflating: SRR2589044_2_fastqc/Images/per_tile_quality.png
inflating: SRR2589044_2_fastqc/Images/per_sequence_quality.png
inflating: SRR2589044_2_fastqc/Images/per_base_sequence_content.png
inflating: SRR2589044_2_fastqc/Images/per_sequence_gc_content.png
inflating: SRR2589044_2_fastqc/Images/per_base_n_content.png
inflating: SRR2589044_2_fastqc/Images/sequence_length_distribution.png
inflating: SRR2589044_2_fastqc/Images/duplication_levels.png
inflating: SRR2589044_2_fastqc/Images/adapter_content.png
inflating: SRR2589044_2_fastqc/fastqc_report.html
inflating: SRR2589044_2_fastqc/fastqc_data.txt
inflating: SRR2589044_2_fastqc/fastqc.fo
The unzip
program is decompressing the .zip
files and creating
a new directory (with subdirectories) for each of our samples, to
store all of the different output that is produced by FastQC. There
are a lot of files here. The one we’re going to focus on is the
summary.txt
file.
If you list the files in our directory now you will see:
SRR2584863_1_fastqc SRR2584866_1_fastqc SRR2589044_1_fastqc
SRR2584863_1_fastqc.html SRR2584866_1_fastqc.html SRR2589044_1_fastqc.html
SRR2584863_1_fastqc.zip SRR2584866_1_fastqc.zip SRR2589044_1_fastqc.zip
SRR2584863_2_fastqc SRR2584866_2_fastqc SRR2589044_2_fastqc
SRR2584863_2_fastqc.html SRR2584866_2_fastqc.html SRR2589044_2_fastqc.html
SRR2584863_2_fastqc.zip SRR2584866_2_fastqc.zip SRR2589044_2_fastqc.zip
The .html
files and the uncompressed .zip
files are still present,
but now we also have a new directory for each of our samples. We can
see for sure that it’s a directory if we use the -F
flag for ls
.
$ ls -F
SRR2584863_1_fastqc/ SRR2584866_1_fastqc/ SRR2589044_1_fastqc/
SRR2584863_1_fastqc.html SRR2584866_1_fastqc.html SRR2589044_1_fastqc.html
SRR2584863_1_fastqc.zip SRR2584866_1_fastqc.zip SRR2589044_1_fastqc.zip
SRR2584863_2_fastqc/ SRR2584866_2_fastqc/ SRR2589044_2_fastqc/
SRR2584863_2_fastqc.html SRR2584866_2_fastqc.html SRR2589044_2_fastqc.html
SRR2584863_2_fastqc.zip SRR2584866_2_fastqc.zip SRR2589044_2_fastqc.zip
Let’s see what files are present within one of these output directories.
$ ls -F SRR2584863_1_fastqc/
fastqc_data.txt fastqc.fo fastqc_report.html Icons/ Images/ summary.txt
Use less
to preview the summary.txt
file for this sample.
$ less SRR2584863_1_fastqc/summary.txt
PASS Basic Statistics SRR2584863_1.fastq
PASS Per base sequence quality SRR2584863_1.fastq
PASS Per tile sequence quality SRR2584863_1.fastq
PASS Per sequence quality scores SRR2584863_1.fastq
WARN Per base sequence content SRR2584863_1.fastq
WARN Per sequence GC content SRR2584863_1.fastq
PASS Per base N content SRR2584863_1.fastq
PASS Sequence Length Distribution SRR2584863_1.fastq
PASS Sequence Duplication Levels SRR2584863_1.fastq
PASS Overrepresented sequences SRR2584863_1.fastq
WARN Adapter Content SRR2584863_1.fastq
The summary file gives us a list of tests that FastQC ran, and tells
us whether this sample passed, failed, or is borderline (WARN
). Remember to quit from less
you enter q
.
Documenting Our Work
We can make a record of the results we obtained for all our samples
by concatenating all of our summary.txt
files into a single file
using the cat
command. We’ll call this full_report.txt
and move
it to ~/dc_workshop/docs
.
$ cat */summary.txt > ~/dc_workshop/docs/fastqc_summaries.txt
Exercise
Which samples failed at least one of FastQC’s quality tests? What test(s) did those samples fail?
Solution
We can get the list of all failed tests using
grep
.$ cd ~/dc_workshop/docs $ grep FAIL fastqc_summaries.txt
FAIL Per base sequence quality SRR2584863_2.fastq.gz FAIL Per tile sequence quality SRR2584863_2.fastq.gz FAIL Per base sequence content SRR2584863_2.fastq.gz FAIL Per base sequence quality SRR2584866_1.fastq.gz FAIL Per base sequence content SRR2584866_1.fastq.gz FAIL Adapter Content SRR2584866_1.fastq.gz FAIL Adapter Content SRR2584866_2.fastq.gz FAIL Adapter Content SRR2589044_1.fastq.gz FAIL Per base sequence quality SRR2589044_2.fastq.gz FAIL Per tile sequence quality SRR2589044_2.fastq.gz FAIL Per base sequence content SRR2589044_2.fastq.gz FAIL Adapter Content SRR2589044_2.fastq.gz
{: .output
Other notes – Optional
Quality Encodings Vary
Although we’ve used a particular quality encoding system to demonstrate interpretation of read quality, different sequencing machines use different encoding systems. This means that, depending on which sequencer you use to generate your data, a
#
may not be an indicator of a poor quality base call.
This mainly relates to older Solexa/Illumina data, but it’s essential that you know which sequencing platform was used to generate your data, so that you can tell your quality control program which encoding to use. If you choose the wrong encoding, you run the risk of throwing away good reads or (even worse) not throwing away bad reads!
Same Symbols, Different Meanings
Here we see
>
being used a shell prompt, whereas>
is also used to redirect output. Similarly,$
is used as a shell prompt, but, as we saw earlier, it is also used to ask the shell to get the value of a variable.If the shell prints
>
or$
then it expects you to type something, and the symbol is a prompt.If you type
>
or$
yourself, it is an instruction from you that the shell to redirect output or get the value of a variable.
Key Points
Quality encodings vary across sequencing platforms.
for
loops let you perform the same set of operations on multiple files with a single command.