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The OBITools3 version of the [wolf tutorial](https://pythonhosted.org/OBITools/wolves.html) made for the first OBITools.
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### 1. Import the sequencing data in a DMS
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Download this archive containing the reads and the ngs file:
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[wolf_tutorial.tar.gz](/uploads/9b86f67ad05815ddee14526640d81137/wolf_tutorial.tar.gz)
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And unzip it:
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tar -zxvf wolf_tutorial.tar.gz
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1. Import the first set of reads, with :
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obi import --quality-solexa wolf_tutorial/wolf_F.fastq wolf/reads1
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`--quality-solexa` is the appropriate fastq quality option because it's an old dataset, `wolf_tutorial/wolf_F.fastq` is the path to the file to import, `wolf` is the path to the DMS that will be automatically created, and `reads1` is the name of the view into which the file will be imported.
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2. Import the second set of reads:
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obi import --quality-solexa wolf_tutorial/wolf_R.fastq wolf/reads2
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3. Import the [ngsfilter file](https://pythonhosted.org/OBITools/scripts/ngsfilter.html) describing the primers and tags used for each sample:
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obi import --ngsfilter wolf_tutorial/wolf_diet_ngsfilter.txt wolf/ngsfile
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4. Check what is in the DMS:
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obi ls wolf
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The option -l displays more details:
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obi ls -l wolf
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You can also check just one view:
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obi ls wolf/reads1
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Or one column:
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obi ls wolf/ngsfile/sample
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To print the sequences, use the less command:
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obi less wolf/reads1
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### 2. Recover the full sequences from the partial forward and reverse reads
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obi alignpairedend -R wolf/reads2 wolf/reads1 wolf/aligned_reads
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### 3. Remove unaligned sequence records
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obi grep -a mode:alignment wolf/aligned_reads wolf/good_sequences
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### 4. Assign each sequence record to the corresponding sample/marker combination
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obi ngsfilter -t wolf/ngsfile -u wolf/unidentified_sequences wolf/good_sequences wolf/identified_sequences
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Note: Unlike the OBITools1, the OBITools3 make it possible to run ngsfilter before aligning the paired-end reads, BUT it is not recommended to do so for usual data, as ngsfilter will not be able to detect and cut out partially sequenced primers.
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### 5. Dereplicate reads into unique sequences
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obi uniq -m sample wolf/identified_sequences wolf/dereplicated_sequences
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### 6. Denoise the sequence dataset
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1. First let's clean the useless metadata and keep only the `COUNT` and `merged_sample` (count by sample) tags:
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obi annotate -k COUNT -k MERGED_sample wolf/dereplicated_sequences wolf/cleaned_metadata_sequences
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2. Keep only the sequences having a count greater or equal to 10 and a length shorter than 80 bp:
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obi grep -p "len(sequence)>=80 and sequence['COUNT']>=10" wolf/cleaned_metadata_sequences wolf/denoised_sequences
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3. Clean the sequences from PCR/sequencing errors (sequence variants):
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obi clean -s MERGED_sample -r 0.05 -H wolf/denoised_sequences wolf/cleaned_sequences
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### 7. Taxonomic assignment of the sequences
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#### Build a reference database
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Building the reference database is costly in time and disk space so you can simply download this already built one:
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[v05_refs.fasta.gz](/uploads/fe71e2e103014d70a1bf9307e377ce2b/v05_refs.fasta.gz)
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With the associated taxdump:
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[taxdump.tar.gz](https://drive.google.com/file/d/1lMV5PWg122ZmhQtx0iq5m5iUKvVBZMUC/view?usp=sharing)
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And import them (note that you could import them in another DMS):
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obi import v05_refs.fasta.gz wolf/v05_refs
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obi import --taxdump taxdump.tar.gz wolf/taxonomy/my_tax
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You can then resume at the next part "**Clean the database**".
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Otherwise, to build the database yourself from the start:
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1. Download the sequences (except human and environmental samples):
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mkdir EMBL
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cd EMBL
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wget -nH --cut-dirs=5 -A rel_std_*.dat.gz -R rel_std_hum_*.dat.gz,rel_std_env_*.dat.gz -m ftp://ftp.ebi.ac.uk/pub/databases/embl/release/std/
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cd ..
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2. Import the sequences in the DMS:
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obi import --embl EMBL wolf/embl_refs
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For EMBL files, you can give the path to a directory with several EMBL files.
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**Note:** The reference database can be built in another DMS.
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3. Download the taxonomy:
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wget ftp://ftp.ncbi.nlm.nih.gov/pub/taxonomy/taxdump.tar.gz
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4. Import the taxonomy in the DMS:
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obi import --taxdump taxdump.tar.gz wolf/taxonomy/my_tax
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5. Use ecoPCR to simulate an *in silico* PCR with the V05 primers:
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obi ecopcr -e 3 -l 50 -L 150 -F TTAGATACCCCACTATGC -R TAGAACAGGCTCCTCTAG --taxonomy wolf/taxonomy/my_tax wolf/embl_refs wolf/v05_refs
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#### Clean the database
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1. Filter sequences so that they have a good taxonomic description at the species, genus, and family levels:
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obi grep --require-rank=species --require-rank=genus --require-rank=family --taxonomy wolf/taxonomy/my_tax wolf/v05_refs wolf/v05_refs_clean
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2. Dereplicate identical sequences:
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obi uniq --taxonomy wolf/taxonomy/my_tax wolf/v05_refs_clean wolf/v05_refs_uniq
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3. Ensure that the dereplicated sequences have a taxid at the family level:
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obi grep --require-rank=family --taxonomy wolf/taxonomy/my_tax wolf/v05_refs_uniq wolf/v05_refs_uniq_clean
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4. Build the reference database specifically used by the OBITools3 to make ecotag efficient:
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obi build_ref_db -t 0.97 --taxonomy wolf/taxonomy/my_tax wolf/v05_refs_uniq_clean wolf/v05_db_97
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#### Assign each sequence to a taxon
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Once the reference database is built, taxonomic assignment can be done using the `ecotag` command:
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obi ecotag -m 0.97 --taxonomy wolf/taxonomy/my_tax -R wolf/v05_db_97 wolf/cleaned_sequences wolf/assigned_sequences
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### 8. After the taxonomic assignment
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#### Take a look at the results
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For example:
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obi stats -c SCIENTIFIC_NAME wolf/assigned_sequences
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#### Align the sequences
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obi align -t 0.95 wolf/assigned_sequences wolf/aligned_assigned_sequences
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#### Check the history of everything that was done
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The default history is in bash:
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obi history wolf
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The most visual way to look at the pipeline is:
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obi history -d wolf > wolf.dot
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obi history -d wolf/cleaned_sequences > wolf_one_view.dot
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To look at the graph produced, open the dot file:
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dot -Tx11 wolf.dot
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or convert the dot file to a png image file:
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dot -Tpng wolf.dot -o wolf.png
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open wolf.png &
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You will get something like this:
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#### Export the results
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Export in fasta format:
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obi export --fasta-output wolf/assigned_sequences -o wolf_results.fasta
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or:
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obi export --fasta-output wolf/assigned_sequences > wolf_results.fasta
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Export in csv-like format:
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obi export --tab-output wolf/aligned_assigned_sequences > wolf_results.csv
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### Contact
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<celine.mercier@metabarcoding.org> |
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\ No newline at end of file |
