Table of Contents
Overview and Objectives
Once raw sequence files are generated (in FASTQ format) and quality-checked, the next step in most NGS pipelines is mapping to a reference genome. For individual sequences of interest, it is common to use a tool like BLAST to identify genes or species of origin. However, a typical example will have millions of reads, and a reference space that is frequently billions of bases, which BLAST and similar tools are not really designed to handle.
Thus, a large set of computational tools have been developed to quickly, and with sufficient (but NOT absolute) accuracy align each read to its best location, if any, in a reference. Even though many mapping tools exist, a few individual programs have a dominant "market share" of the NGS world. These programs vary widely in their design, inputs, outputs, and applications. In this section, we will primarily focus on two of the most versatile mappers: BWA and Bowtie2, the latter being part of the Tuxedo suite (e.g. Tophat2).
You have already worked with a paired-end yeast ChIP-seq dataset, which we will continue to use here. The paired end data should be located at:
We will also use two additional RNA-seq datasets, which are located at:
Set up a new directory in your scratch area called 'fastq_align', and populate it with copies the following files, derived from the locations given above:
|Paired-end Illumina, First of pair, FASTQ
|Paired-end Illumina, Second of pair, FASTQ
|Paired-end Illumina, First of pair only, FASTQ
|Single-end Illumina, FASTQ
Do a fast quality check on the two new data files like you did earlier on the yeast files, and move all files and directories that are produced from the fastQC commands into a new subdirectory called 'fastqc_out'.
Before we get to alignment, we need a genome to align to. We will use three different references here: the human genome (hg19), the yeast genome (sacCer3), and mirbase (v20). Mirbase is a collection of all known microRNAs in all species, and we will use the human subset of that database as our alignment reference. This has the advantage of being significantly smaller than the human genome, while containing all the sequences we are actually interested in.
Due to natural variation, sequencing errors, and processing issues, variation between reference sequence and sample sequence is always possible. Alignment to the human genome allows a putative "microRNA" read the opportunity to find a better alignment in a region of the genome that is not an annotated microRNA relative to the microRNA reference sequence. If this occurs, we might think that a read represents a microRNA (since it aligned in the mirbase alignment), when it is actually more likely to have come from a non-miRNA area of the genome.
These are the three reference genomes we will be using today, with some information about them (and here is information about many more genomes):
|25 (really 93)
Searching genomes, however, is hard work and takes a long time if done on an un-indexed, linear genomic sequence. So, most aligners require that references be indexed for quick access The aligners we are using each require a different index, but use the same method (the Burrows-Wheeler Transform) to get the job done. This requires taking a FASTA file as input, with each chromosome (or contig) as a separate entry, and producing some aligner-specific set of files as output. Then, those output files are used by the aligner when executing a given alignment command. Hg19 is way too big for us to index here, so we're not going to do it, and it's not included in the core_ngs_tools directory at Corral that we've been copying from. Instead, all hg19 index files are located at:
Now, we're going to grab the other two references, and we will build each index right before we use it in each set of exercise below. These two references are located at:
Now, stage the yeast and mirbase reference fasta files in your scratch area in a directory called 'references'.
With that, we're ready to get started on the first exercise.
Exercise #1: BWA - Yeast ChIP-seq
Like other tools you've worked with so far, you first need to load bwa using the module system. So, go ahead and do that now, and then enter 'bwa' with no arguments to view the help page.
As you can see, there are several commands one can use with bwa to do different things. To test out one of them, we're going to index the genome with the 'index' command. If you enter 'bwa index' with no arguments, you will see a list of the required arguments. Here, we only need to specify two things: whether to use 'bwtsw' or 'is' indexing, and the name of the fasta file. We will specify 'bwtsw' as the indexing option, and the name of the FASTA file is, obviously, sacCer3.fa. The output of this command, importantly, is a group of files that are all required together as the index. So, within the references directory, we will create another directory called "yeast", move the yeast FASTA file into that directory, and run the index commands from there:
This command should produce a set of output files that look like this:
Now, we're ready to execute the actual alignment, with the goal of producing a SAM/BAM file from the input FASTQ files and reference. We will first generate SAI files from each of the FASTQ files with the reference individually using the 'aln' command, then combine them (with the reference) into one SAM/BAM output file using the 'sampe' command. We need a directory to put the alignments when they are finished, as well as any intermediate files, so create a directory called 'alignments'. The command flow, all together, is as follows:
Notice how each file is in its proper directory, which requires us to specify the whole file path in the alignment commands.
|Best Practice Setting
Exercise #2: Bowtie2 and Local Alignment - Human microRNA-seq
Exercise #3: BWA-MEM (and Tophat2) - Human mRNA-seq