Filtering contaminant or category specific OTUs from OTU tables

This tutorial explains how to use several QIIME scripts to filter all OTUs that belong to a particular category of samples. This would be used, for example, if you ran blank control samples and want to remove any OTUs observed in these samples as likely contamination.

To accomplish this task several scripts are used to first generate an OTU table of target OTUs to remove, then filter those OTUs from the original OTU table, and finally to perform a clean-up step to remove the control samples that would now have zero sequences associated with them.

The OTU table and mapping file (generated from the QIIME tutorial data set) are available here.

Once these files are downloaded and extracted, open a terminal and change to the directory of the extracted files to begin processing.

Filtering out samples according to run

In this case, we are going to assume that multiple runs are present in an OTU table, and these are indicated in the Run_Number column in our mapping file. As our example is removal of all OTUs from samples that should be blank control samples, we can assume that contamination will be limited to a single run, so we therefore want to begin by splitting the OTU table by the Run_Number field. If there are not multiple runs to separate, this step can be skipped.

Splitting the OTU table by run

The runs are identified in the Run_Number column of the example mapping file.

Note

• #SampleID BarcodeSequence LinkerPrimerSequence Run_Number Sample_Type Description
• #Modified tutorial mapping file to show procedure to filter OTUs from particular sample categories (ie. Control samples whose sequences are likely contamination across all samples)
• PC.354 AGCACGAGCCTA YATGCTGCCTCCCGTAGGAGT 1 Control_Blank Control_mouse_I.D._354
• PC.355 AACTCGTCGATG YATGCTGCCTCCCGTAGGAGT 1 Control_Blank Control_mouse_I.D._355
• PC.356 ACAGACCACTCA YATGCTGCCTCCCGTAGGAGT 2 Control_Blank Control_mouse_I.D._356
• PC.481 ACCAGCGACTAG YATGCTGCCTCCCGTAGGAGT 2 Control_Blank Control_mouse_I.D._481
• PC.593 AGCAGCACTTGT YATGCTGCCTCCCGTAGGAGT 2 Control_Blank Control_mouse_I.D._593
• PC.607 AACTGTGCGTAC YATGCTGCCTCCCGTAGGAGT 1 Test_Sample Fasting_mouse_I.D._607
• PC.634 ACAGAGTCGGCT YATGCTGCCTCCCGTAGGAGT 1 Test_Sample Fasting_mouse_I.D._634
• PC.635 ACCGCAGAGTCA YATGCTGCCTCCCGTAGGAGT 2 Test_Sample Fasting_mouse_I.D._635
• PC.636 ACGGTGAGTGTC YATGCTGCCTCCCGTAGGAGT 2 Test_Sample Fasting_mouse_I.D._636

To create per-run OTU tables containing, use the following command:

split_otu_table.py -i otu_table.biom -m map.txt -f Run_Number -o split_otu_tables/

One can observe the initial sequences/sample in the run 1 OTU table:

print_biom_table_summary.py -i split_otu_tables/otu_table_1.biom

Note

• Num samples: 4
• Num otus: 419
• Num observations (sequences): 595.0
• Seqs/sample summary:
• Min: 147.0
• Max: 150.0
• Median: 149.0
• Mean: 148.75
• Std. dev.: 1.08972473589
• Median Absolute Deviation: 0.5
• Default even sampling depth in
• core_qiime_analyses.py (just a suggestion): 149.0
• Seqs/sample detail:
• PC.355: 147.0
• PC.354: 149.0
• PC.607: 149.0
• PC.634: 150.0

Filtering OTUs observed in the control blanks from the experimental samples

We will only examine run 1 in this example, but if you’re working with multiple runs of data you would apply this step for each run. Note that if you don’t have multiple runs, you would continue with otu_table.biom at this stage, rather than split_otu_tables/otu_table_1.biom.

Create an OTU table with the just the blank control samples:

filter_samples_from_otu_table.py -i split_otu_tables/otu_table_1.biom -o otu_table_run1_blank_samples.biom -m map.txt -s "Sample_Type:Control_Blank"

Filter out OTU ids that have zero counts, as we only want the OTUs with positive counts from the Control_Blank samples:

filter_otus_from_otu_table.py -i otu_table_run1_blank_samples.biom -o filtered_otu_table_blank_samples.biom -n 1

Then create a tab separated version of this OTU table:

convert_biom.py -b -i filtered_otu_table_blank_samples.biom -o otus_to_remove.txt

Filter out OTU ids from the run 1 OTU table that were determined to be present in the Control_Blank samples:

filter_otus_from_otu_table.py -i split_otu_tables/otu_table_1.biom -o otu_table_1_minus_contaminants.biom -e otus_to_remove.txt

The otu_table_1_minus_contaminants.biom file now has two samples with zero sequences associated with it. These can be removed to get a final OTU table:

filter_samples_from_otu_table.py -i otu_table_1_minus_contaminants.biom -o final_otu_table_1_minus_contaminants.biom -n 1

The final OTU table sequences/sample summary can be displayed now, sans OTUs from the Control_Blank samples:

print_biom_table_summary.py -i final_otu_table_1_minus_contaminants.biom

Note

• Num samples: 2
• Num otus: 313
• Num observations (sequences): 209.0
• Seqs/sample summary:
• Min: 99.0
• Max: 110.0
• Median: 104.5
• Mean: 104.5
• Std. dev.: 5.5
• Median Absolute Deviation: 5.5
• Default even sampling depth in
• core_qiime_analyses.py (just a suggestion): 99.0
• Seqs/sample detail:
• PC.607: 99.0
• PC.634: 110.0

If you apply this process to multiple runs, and then want to reassemble the final OTU tables into a single OTU table, you can use the merge_otu_tables.py command.