Quality and contamination control in bacterial isolate using Illumina MiSeq Data

Author(s) orcid logoBérénice Batut avatar Bérénice Batutorcid logoClea Siguret avatar Clea Siguret
Reviewers Björn Grüning avatarSaskia Hiltemann avatarTeresa Müller avatarBérénice Batut avatarClea Siguret avatar
Overview
Creative Commons License: CC-BY Questions:
  • How to check the quality of MiSeq data?

  • What are the species in bacterial isolate sequencing data?

Objectives:
  • Run tools to evaluate sequencing data on quality and quantity

  • Evaluate the output of quality control tools

  • Improve the quality of sequencing data

  • Run a series of tool to identify species in bacterial isolate sequencing data

  • Visualize the species abundance

Requirements:
Time estimation: 2 hours
Level: Introductory Introductory
Supporting Materials:
Published: Jul 15, 2024
Last modification: Oct 9, 2024
License: Tutorial Content is licensed under Creative Commons Attribution 4.0 International License. The GTN Framework is licensed under MIT
purl PURL: https://gxy.io/GTN:T00446
rating Rating: 4.8 (4 recent ratings, 8 all time)
version Revision: 3

Sequencing (determining of DNA/RNA nucleotide sequence) is used all over the world for all kinds of analysis. The product of these sequencers are reads, which are sequences of detected nucleotides. Depending on the technique these have specific lengths (30-500bp) or using Oxford Nanopore Technologies sequencing have much longer variable lengths.

Comment: Illumina MiSeq sequencing

Illumina MiSeq sequencing is based on sequencing by synthesis. As the name suggests, fluorescent labels are measured for every base that bind at a specific moment at a specific place on a flow cell. These flow cells are covered with oligos (small single strand DNA strands). In the library preparation the DNA strands are cut into small DNA fragments (differs per kit/device) and specific pieces of DNA (adapters) are added, which are complementary to the oligos. Using bridge amplification large amounts of clusters of these DNA fragments are made. The reverse string is washed away, making the clusters single stranded. Fluorescent bases are added one by one, which emit a specific light for different bases when added. This is happening for whole clusters, so this light can be detected and this data is basecalled (translation from light to a nucleotide) to a nucleotide sequence (Read). For every base a quality score is determined and also saved per read. This process is repeated for the reverse strand on the same place on the flow cell, so the forward and reverse reads are from the same DNA strand. The forward and reversed reads are linked together and should always be processed together!

For more information watch this video from Illumina

Contemporary sequencing technologies are capable of generating an enormous volume of sequence reads in a single run. Nonetheless, each technology has its imperfections, leading to various types and frequencies of errors, such as miscalled nucleotides. These inaccuracies stem from the inherent technical constraints of each sequencing platform. When sequencing bacterial isolates, it is crucial to verify the quality of the data but also to check the expected species or strains are found in the data or if there is any contamination.

To illustrate the process, we take raw data of a bacterial genome (KUN1163 sample) from sequencing data produced in “Complete Genome Sequences of Eight Methicillin-Resistant Staphylococcus aureus Strains Isolated from Patients in Japan” (Hikichi et al. 2019).

Methicillin-resistant Staphylococcus aureus (MRSA) is a major pathogen causing nosocomial infections, and the clinical manifestations of MRSA range from asymptomatic colonization of the nasal mucosa to soft tissue infection to fulminant invasive disease. Here, we report the complete genome sequences of eight MRSA strains isolated from patients in Japan.

Agenda

In this tutorial, we will cover:

  1. Galaxy and data preparation
  2. Read quality control and improvement
    1. Quality control
    2. Quality improvement
  3. Identification of expected species and detection of contamination
    1. Taxonomic profiling
    2. Species identification
    3. Contamination detection
  4. Conclusion

Galaxy and data preparation

Any analysis should get its own Galaxy history. So let’s start by creating a new one and get the data (forward and reverse quality-controlled sequences) into it.

Hands-on: Prepare Galaxy and data
  1. Create a new history for this analysis

    To create a new history simply click the new-history icon at the top of the history panel:

    UI for creating new history

  2. Rename the history

    1. Click on galaxy-pencil (Edit) next to the history name (which by default is “Unnamed history”)
    2. Type the new name
    3. Click on Save
    4. To cancel renaming, click the galaxy-undo “Cancel” button

    If you do not have the galaxy-pencil (Edit) next to the history name (which can be the case if you are using an older version of Galaxy) do the following:

    1. Click on Unnamed history (or the current name of the history) (Click to rename history) at the top of your history panel
    2. Type the new name
    3. Press Enter

Now, we need to import the data: 2 FASTQ files containing the reads from the sequencer.

Hands-on: Import datasets
  1. Import the files from Zenodo or from Galaxy shared data libraries:

    https://zenodo.org/record/10669812/files/DRR187559_1.fastqsanger.bz2
    https://zenodo.org/record/10669812/files/DRR187559_2.fastqsanger.bz2
    
    • Copy the link location
    • Click galaxy-upload Upload Data at the top of the tool panel

    • Select galaxy-wf-edit Paste/Fetch Data
    • Paste the link(s) into the text field

    • Press Start

    • Close the window

    As an alternative to uploading the data from a URL or your computer, the files may also have been made available from a shared data library:

    1. Go into Data (top panel) then Data libraries
    2. Navigate to the correct folder as indicated by your instructor.
      • On most Galaxies tutorial data will be provided in a folder named GTN - Material –> Topic Name -> Tutorial Name.
    3. Select the desired files
    4. Click on Add to History galaxy-dropdown near the top and select as Datasets from the dropdown menu
    5. In the pop-up window, choose

      • “Select history”: the history you want to import the data to (or create a new one)
    6. Click on Import

  2. Rename the datasets to remove .fastqsanger.bz2 and keep only the sequence run ID (DRR187559_1 and DRR187559_2)

    • Click on the galaxy-pencil pencil icon for the dataset to edit its attributes
    • In the central panel, change the Name field to DRR187559_1
    • Click the Save button

  3. Tag both datasets #unfiltered

    Datasets can be tagged. This simplifies the tracking of datasets across the Galaxy interface. Tags can contain any combination of letters or numbers but cannot contain spaces.

    To tag a dataset:

    1. Click on the dataset to expand it
    2. Click on Add Tags galaxy-tags
    3. Add tag text. Tags starting with # will be automatically propagated to the outputs of tools using this dataset (see below).
    4. Press Enter
    5. Check that the tag appears below the dataset name

    Tags beginning with # are special!

    They are called Name tags. The unique feature of these tags is that they propagate: if a dataset is labelled with a name tag, all derivatives (children) of this dataset will automatically inherit this tag (see below). The figure below explains why this is so useful. Consider the following analysis (numbers in parenthesis correspond to dataset numbers in the figure below):

    1. a set of forward and reverse reads (datasets 1 and 2) is mapped against a reference using Bowtie2 generating dataset 3;
    2. dataset 3 is used to calculate read coverage using BedTools Genome Coverage separately for + and - strands. This generates two datasets (4 and 5 for plus and minus, respectively);
    3. datasets 4 and 5 are used as inputs to Macs2 broadCall datasets generating datasets 6 and 8;
    4. datasets 6 and 8 are intersected with coordinates of genes (dataset 9) using BedTools Intersect generating datasets 10 and 11.

    A history without name tags versus history with name tags

    Now consider that this analysis is done without name tags. This is shown on the left side of the figure. It is hard to trace which datasets contain “plus” data versus “minus” data. For example, does dataset 10 contain “plus” data or “minus” data? Probably “minus” but are you sure? In the case of a small history like the one shown here, it is possible to trace this manually but as the size of a history grows it will become very challenging.

    The right side of the figure shows exactly the same analysis, but using name tags. When the analysis was conducted datasets 4 and 5 were tagged with #plus and #minus, respectively. When they were used as inputs to Macs2 resulting datasets 6 and 8 automatically inherited them and so on… As a result it is straightforward to trace both branches (plus and minus) of this analysis.

    More information is in a dedicated #nametag tutorial.

  4. View galaxy-eye the renamed file

The datasets are both FASTQ files.

Question
  1. What are the 4 main features of each read in a FASTQ file.
  2. What does the _1 and _2 mean in your filenames?
  1. The following:

    • A @ followed by a name and sometimes information of the read
    • A nucleotide sequence
    • A + (optional followed by the name)
    • The quality score per base of nucleotide sequence (Each symbol represents a quality score, which will be explained later)
  2. Forward and reverse reads, by convention, are labelled _1 and _2, but they might also be _f/_r or _r1/_r2.

Hands-on: Choose Your Own Tutorial

This is a "Choose Your Own Tutorial" section, where you can select between multiple paths. Click one of the buttons below to select how you want to follow the tutorial

Do you want to go step-by-step or using a workflow?

In this section we will run a Galaxy workflow that performs the following tasks with the following tools:

  1. Assess the reads quality before preprocessing it using FastQC.
  2. Trimming and filtering reads by length and quality using Fastp (Chen et al. 2018).
  3. Find witch microorgasnims are present using Kraken2 (Wood and Salzberg 2014).
  4. Extract the species level with Bracken (Bayesian Reestimation of Abundance after Classification with Kraken) (Lu et al. 2017).
  5. Detect minority organisms or contamination using Recentrifuge (Martı́ Jose Manuel 2019).

We will run all these steps using a single workflow, then discuss each step and the results in more detail.

Hands-on: Pre-Processing
  1. Import the workflow into Galaxy
    • Copy the URL (e.g. via right-click) of this workflow or download it to your computer.
    • Import the workflow into Galaxy
    • Click on Workflow on the top menu bar of Galaxy. You will see a list of all your workflows.
    • Click on galaxy-upload Import at the top-right of the screen
    • Provide your workflow
      • Option 1: Paste the URL of the workflow into the box labelled “Archived Workflow URL”
      • Option 2: Upload the workflow file in the box labelled “Archived Workflow File”
    • Click the Import workflow button

    Below is a short video demonstrating how to import a workflow from GitHub using this procedure:

    Video: Importing a workflow from URL

  2. Run Workflow : Quality and contamination control in bacterial isolate using Illumina MiSeq Data workflow using the following parameters
    • “DRR187559_1”: DRR187559_1, which is the forward read data.

    • “DRR187559_2”: DRR187559_2, which is the reverse read data.

    • Click on Workflow on the top menu bar of Galaxy. You will see a list of all your workflows.
    • Click on the workflow-run (Run workflow) button next to your workflow
    • Configure the workflow as needed
    • Click the Run Workflow button at the top-right of the screen
    • You may have to refresh your history to see the queued jobs

The workflow will take some time. Once completed, results will be available in your history. While waiting, read the next sections for details on each workflow step and the corresponding outputs.

Read quality control and improvement

During sequencing, errors are introduced, such as incorrect nucleotides being called. These are due to the technical limitations of each sequencing platform. Sequencing errors might bias the analysis and can lead to a misinterpretation of the data. Adapters may also be present if the reads are longer than the fragments sequenced and trimming these may improve the number of reads mapped. Sequence quality control is therefore an essential first step in any analysis.

Assessing the quality by hand would be too much work. That’s why tools like NanoPlot or FastQC are made, as they generate a summary and plots of the data statistics. NanoPlot is mainly used for long-read data, like ONT and PACBIO and FastQC for short read, like Illumina and Sanger. You can read more in our dedicated Quality Control Tutorial.

Before doing any analysis, the first questions we should ask about the input reads include:

  • What is the coverage of my genome?
  • How good are my reads?
  • Do I need to ask/perform for a new sequencing run?
  • Is it suitable for the analysis I need to do?

Quality control

Hands-on: Quality Control
  1. FastQC ( Galaxy version 0.74+galaxy0) with the following parameters:
    • param-files “Short read data from your current history”: both DRR187559_1 and DRR187559_2
    1. Click on param-files Multiple datasets
    2. Select several files by keeping the Ctrl (or COMMAND) key pressed and clicking on the files of interest

  2. Inspect the webpage outputs
Hands-on: Quality Control

Inspect the webpage outputs of FastQC

FastQC combines quality statistics from all separate reads and combines them in plots. An important plot is the Per base sequence quality.

DRR187559_1 DRR187559_2
FastQC plot showing reads that mostly stay in the green. Same as previous plot, but the beginning of the reads are slightly better quality.

Here you have the reads sequence length on the x-axes against the quality score (Phred-score) on the y-axis. The y-axis is divided in three sections:

  • Green = good quality,
  • Orange = mediocre quality, and
  • Red = bad quality.

For each position, a boxplot is drawn with:

  • the median value, represented by the central red line
  • the inter-quartile range (25-75%), represented by the yellow box
  • the 10% and 90% values in the upper and lower whiskers
  • the mean quality, represented by the blue line
Question

How does the mean quality score change along the sequence?

The mean quality score (blue line) decreases at the sequences end. It is common for the mean quality to drop towards the end of the sequences, as the sequencers are incorporating more incorrect nucleotides at the end. For Illumina data it is normal that the first few bases are of some lower quality and how longer the reads get the worse the quality becomes. This is often due to signal decay or phasing during the sequencing run.

Quality improvement

Depending on the analysis it could be possible that a certain quality or length is needed. In this case we are going to trim the data using fastp (Chen et al. 2018):

  • Trim the start and end of the reads if those fall below a quality score of 20

    Different trimming tools have different algorithms for deciding when to cut but trimmomatic will cut based on the quality score of one base alone. Trimmomatic starts from each end, and as long as the base is below 20, it will be cut until it reaches one greater than 20. A sliding window trimming will be performed where if the average quality of 4 bases drops below 20, the read will be truncated there.

  • Filter for reads to keep only reads with at least 30 bases: Anything shorter will complicate the assembly

Hands-on: Quality improvement
  1. fastp ( Galaxy version 0.23.4+galaxy0) with the following parameters:
    • “Single-end or paired reads”: Paired
      • param-file “Input 1”: DRR187559_1
      • param-file “Input 2”: DRR187559_2
    • In “Filter Options”:
      • In “Length filtering Options”:
        • Length required: 30
    • In “Read Modification Options”:
      • In “Per read cuitting by quality options”:
        • Cut by quality in front (5’): Yes
        • Cut by quality in front (3’): Yes
        • Cutting window size: 4
        • Cutting mean quality: 20
    • In “Output Options”:
      • “Output JSON report”: Yes
  2. Edit the tags of the fastp FASTQ outputs to
    1. Remove the #unfiltered tag
    2. Add a new tag #filtered

fastp generates also a report, similar to FastQC, useful to compare the impact of the trimming and filtering.

Question

Looking at fastp HTML report

  1. How did the average read length change before and after filtering?
  2. Did trimming improve the mean quality scores?
  3. Did trimming affect the GC content?
  4. Is this data ok to assemble? Do we need to re-sequence it?
  1. Read lengths went down more significantly:
    • Before filtering: 190bp, 221bp
    • After filtering: 189bp, 219bp
  2. It increased the percentage of Q20 and Q30 bases (bases with quality score above 20 and 30 respectively)
  3. No, it did not. If it had, that would be unexpected.
  4. This data looks OK. The number of short reads in R1 is not optimal but assembly should partially work but not the entire, closed genome.

Identification of expected species and detection of contamination

When working with bacterial isolates, it is crucial to verify whether the expected species or strains are present in the data and to identify any potential contamination. Ensuring the presence of the intended species is essential for the accuracy and reliability of the research, as deviations could lead to erroneous conclusions. Additionally, detecting contamination is vital to maintain the integrity of the samples and to avoid misleading results that could compromise subsequent analyses and applications.

Taxonomic profiling

To find out which microorganisms are present, we will compare the filtered reads of the sample to a reference database, i.e. sequences of known microorganisms stored in a database, using Kraken2 (Wood et al. 2019).

In the \(k\)-mer approach for taxonomy classification, we use a database containing DNA sequences of genomes whose taxonomy we already know. On a computer, the genome sequences are broken into short pieces of length \(k\) (called \(k\)-mers), usually 30bp.

Kraken examines the \(k\)-mers within the query sequence, searches for them in the database, looks for where these are placed within the taxonomy tree inside the database, makes the classification with the most probable position, then maps \(k\)-mers to the lowest common ancestor (LCA) of all genomes known to contain the given \(k\)-mer.

Kraken2

Kraken2 uses a compact hash table, a probabilistic data structure that allows for faster queries and lower memory requirements. It applies a spaced seed mask of s spaces to the minimizer and calculates a compact hash code, which is then used as a search query in its compact hash table; the lowest common ancestor (LCA) taxon associated with the compact hash code is then assigned to the k-mer.

You can find more information about the Kraken2 algorithm in the paper Improved metagenomic analysis with Kraken 2.

For this tutorial, we will use the PlusPF database which contains the RefSeq Standard (archaea, bacteria, viral, plasmid, human, UniVec_Core), protozoa and fungi data.

Hands-on: Assign taxonomic labels with Kraken2
  1. Kraken2 ( Galaxy version 2.1.3+galaxy1) with the following parameters:
    • “Single or paired reads”: Paired
      • param-file “Forward strand”: fastp Read 1 output
      • param-file “Reverse strand”: fastp Read 2 output
    • “Minimum Base Quality”: 10
    • In “Create Report”:
      • “Print a report with aggregrate counts/clade to file”: Yes
    • “Select a Kraken2 database”: PlusPF-16

Kraken2 generates 2 outputs:

  • Classification: tabular files with one line for each sequence classified by Kraken and 5 columns:

    1. C/U: a one letter indicating if the sequence classified or unclassified
    2. Sequence ID as in the input file
    3. NCBI taxonomy ID assigned to the sequence, or 0 if unclassified
    4. Length of sequence in bp (read1|read2 for paired reads)
    5. A space-delimited list indicating the lowest common ancestor (LCA) mapping of each k-mer in the sequence

      For example, 562:13 561:4 A:31 0:1 562:3 would indicate that:

      1. The first 13 k-mers mapped to taxonomy ID #562
      2. The next 4 k-mers mapped to taxonomy ID #561
      3. The next 31 k-mers contained an ambiguous nucleotide
      4. The next k-mer was not in the database
      5. The last 3 k-mers mapped to taxonomy ID #562

      |:| indicates end of first read, start of second read for paired reads

     Column 1	Column 2	Column 3	Column 4	Column 5
     C	DRR187559.1	1280	164|85	0:1 1279:1 0:41 1279:10 0:5 1280:5 1279:1 0:1 1279:1 0:7 1279:5 0:2 1279:6 0:12 1279:5 0:19 1279:2 0:6 |:| 0:39 1279:2 0:6 1279:3 0:1
     C	DRR187559.2	1280	70|198	0:2 1279:5 0:29 |:| 0:52 1279:5 0:13 1279:3 0:23 1279:2 0:45 1280:1 0:9 1280:3 A:8
     C	DRR187559.3	1279	106|73	0:4 1279:3 0:36 1279:4 0:10 1279:5 0:3 1279:5 0:2 |:| 0:39
     C	DRR187559.4	1279	121|189	1279:6 0:17 1279:4 0:28 1279:2 0:30 |:| 0:7 1279:5 0:19 1279:5 0:20 1279:1 0:8 1279:1 0:1 1279:6 0:25 1279:2 0:44 A:11
     C	DRR187559.5	1279	68|150	1279:2 0:20 1279:3 0:9 |:| 0:10 1279:3 0:24 1279:2 0:9 1279:5 0:21 1279:5 0:20 1279:5 0:9 1279:1 0:2
     C	DRR187559.6	1280	137|246	0:2 1280:5 0:28 1279:1 0:28 1279:2 0:8 1279:2 0:23 1279:1 0:3 |:| 1279:1 0:2 1279:3 0:61 1279:2 0:14 1279:2 0:97 A:30 
    
    Question
    1. Is the first sequence in the file classified or unclassified?
    2. What is the taxonomy ID assigned to the first classified sequence?
    3. What is the corresponding taxon?
    1. classified
    2. 1280
    3. 1280 corresponds to Staphylococcus aureus .
  • Report: tabular files with one line per taxon and 6 columns or fields

    1. Percentage of fragments covered by the clade rooted at this taxon
    2. Number of fragments covered by the clade rooted at this taxon
    3. Number of fragments assigned directly to this taxon
    4. A rank code, indicating
      • (U)nclassified
      • (R)oot
      • (D)omain
      • (K)ingdom
      • (P)hylum
      • (C)lass
      • (O)rder
      • (F)amily
      • (G)enus, or
      • (S)pecies

      Taxa that are not at any of these 10 ranks have a rank code that is formed by using the rank code of the closest ancestor rank with a number indicating the distance from that rank. E.g., G2 is a rank code indicating a taxon is between genus and species and the grandparent taxon is at the genus rank.

    5. NCBI taxonomic ID number
    6. Indented scientific name
     Column 1	Column 2	Column 3	Column 4	Column 5	Column 6
     0.24 	1065 	1065 	U 	0 	unclassified
     99.76 	450716 	14873 	R 	1 	root
     96.44 	435695 	2 	R1 	131567 	cellular organisms
     96.44 	435675 	3889 	D 	2 	Bacteria
     95.56 	431709 	78 	D1 	1783272 	Terrabacteria group
     95.53 	431578 	163 	P 	1239 	Firmicutes
     95.49 	431390 	4625 	C 	91061 	Bacilli
     94.38 	426383 	1436 	O 	1385 	Bacillales
     94.04 	424874 	2689 	F 	90964 	Staphylococcaceae
     93.44 	422124 	234829 	G 	1279 	Staphylococcus 
    
    Question
    1. How many taxa have been found?
    2. What are the percentage on unclassified?
    3. What are the domains found?
    1. 627, as the number of lines
    2. 0.24%
    3. Only Bacteria

Species identification

In Kraken output, there are quite a lot of identified taxa with different levels. To obtain a more accurate and detailed understanding at the species level, we will use Bracken.

Bracken refines the Kraken results by re-estimating the abundances of species in metagenomic samples, providing a more precise and reliable identification of species, which is crucial for downstream analysis and interpretation.

Bracken (Bayesian Reestimation of Abundance after Classification with Kraken) is a “simple and worthwile addition to Kraken for better abundance estimates” (Ye et al. 2019). Instead of only using proportions of classified reads, it takes a probabilistic approach to generate final abundance profiles. It works by re-distributing reads in the taxonomic tree: “Reads assigned to nodes above the species level are distributed down to the species nodes, while reads assigned at the strain level are re-distributed upward to their parent species” (Lu et al. 2017).

Hands-on: Extract species with Bracken
  1. Bracken ( Galaxy version 2.9+galaxy0) with the following parameters:
    • param-collection “Kraken report file”: Report output of Kraken
    • “Select a kmer distribution”: PlusPF-16, same as for Kraken

      It is important to choose the same database that you also chose for Kraken2

    • “Level”: Species
    • “Produce Kraken-Style Bracken report”: Yes

Bracken generates 2 outputs:

  • Kraken style report: tabular files with one line per taxon and 6 columns or fields. Same configuration as the Report output of Kraken:

    1. Percentage of fragments covered by the clade rooted at this taxon
    2. Number of fragments covered by the clade rooted at this taxon
    3. Number of fragments assigned directly to this taxon
    4. A rank code, indicating
      • (U)nclassified
      • (R)oot
      • (D)omain
      • (K)ingdom
      • (P)hylum
      • (C)lass
      • (O)rder
      • (F)amily
      • (G)enus, or
      • (S)pecies
    5. NCBI taxonomic ID number
    6. Indented scientific name
     Column 1	Column 2	Column 3	Column 4	Column 5	Column 6
     100.00 	450408 	0 	R 	1 	root
     99.14 	446538 	0 	R1 	131567 	cellular organisms
     99.14 	446524 	0 	D 	2 	Bacteria
     99.14 	446524 	0 	D1 	1783272 	Terrabacteria group
     99.13 	446491 	0 	P 	1239 	Firmicutes
     99.13 	446491 	0 	C 	91061 	Bacilli
     99.06 	446152 	0 	O 	1385 	Bacillales
     99.06 	446152 	0 	F 	90964 	Staphylococcaceae
     99.04 	446101 	0 	G 	1279 	Staphylococcus
     95.62 	430661 	430661 	S 	1280 	Staphylococcus aureus 
    
    Question
    1. How many taxa have been found?
    2. What is the family found?
    1. 119, as the number of lines
    2. Staphylococcaceae, with 99.06%!
  • Report: tabular files with one line per taxon and 7 columns or fields

    1. Taxon name
    2. Taxonomy ID
    3. Level ID (S=Species, G=Genus, O=Order, F=Family, P=Phylum, K=Kingdom)
    4. Kraken assigned reads
    5. Added reads with abundance re-estimation
    6. Total reads after abundance re-estimation
    7. Fraction of total reads
     Column 1	Column 2	Column 3	Column 4	Column 5	Column 6	Column 7
     Staphylococcus aureus 	1280 	S 	182995 	247666 	430661 	0.95616
     Staphylococcus roterodami 	2699836 	S 	698 	48 	746 	0.00166
     Staphylococcus epidermidis 	1282 	S 	587 	13 	600 	0.00133
     Staphylococcus lugdunensis 	28035 	S 	511 	3 	514 	0.00114
     Staphylococcus schweitzeri 	1654388 	S 	409 	26 	435 	0.00097
     Staphylococcus simiae 	308354 	S 	398 	2 	400 	0.00089 
    
Question
  1. How many species have been found?
  2. Which the species has been the most identified? And in which proportion?
  3. What are the other species?
  1. 51 (52 lines including 1 line with header)
  2. Staphylococcus aureus with 95.6% of the reads.
  3. Most of the other species are from Staphylococcus genus, so same as Staphylococcus aureus. The other species in really low proportion.

As expected Staphylococcus aureus represents most of the reads in the data.

Contamination detection

To explore Kraken report and specially to detect more reliably minority organisms or contamination, we will use Recentrifuge (Martı́ Jose Manuel 2019).

Recentrifuge enhances analysis by reanalyzing metagenomic classifications with interactive charts that highlight confidence levels. It supports 48 taxonomic ranks of the NCBI Taxonomy, including strains, and generates plots for shared and exclusive taxa, facilitating robust comparative analysis.

Recentrifuge includes a novel contamination removal algorithm, useful when negative control samples are available, ensuring data integrity with control-subtracted plots. It also excels in detecting minority organisms in complex datasets, crucial for sensitive applications such as clinical and environmental studies.

Hands-on: Identify contamination
  1. Recentrifuge ( Galaxy version 1.12.1+galaxy0) with the following parameters:
    • param-file “Select taxonomy file tabular formated”: Classification output of Krancken2 tool
    • “Type of input file (Centrifuge, CLARK, Generic, Kraken, LMAT)”: Kraken
    • In “Database type”:
      • “Cached database whith taxa ID”: NCBI-2023-06-27
    • In “Output options”:
      • “Type of extra output to be generated (default on CSV)”: TSV
      • “Remove the log file”: Yes
    • In ” Fine tuning of algorithm parameters”:
      • “Strain level instead of species as the resolution limit for the robust contamination removal algorithm; use with caution, this is an experimental feature”: Yes

Recentrifuge generates 3 outputs:

  • A statistic table with general statistics about assignations

    Question
    1. How many sequences have been used?
    2. How many sequences have been classified?
    1. 451,780
    2. 450,715
  • A data table with a report for each taxa

    Question
    1. How many taxa have been kept?
    2. What is the lowest level in the data?
    1. 187 (190 lines including 3 header lines)
    2. The lowest level is strain.
  • A HTML report with a Krona chart

    Question
    1. What is the percentage of classified sequences?
    2. When clicking on Staphylococcus aureus, what can we say about the strains?
    3. Is there any contamination?
    1. 99.8%
    2. 99% of sequences assigned to Staphylococcus aureus are not assigned to any strains, probably because they are too similar to several strains. Staphylococcus aureus subsp. aureus JKD6159 is the strain with the most classified sequences, but only 0.3% of the sequences assigned to Staphylococcus aureus.
    3. There is no sign of a possible contamination. Most sequences are classified to taxon on the Staphylococcus aureus taxonomy. Only 3% of the sequences are not classified to Staphylococcus.

Once we have identified contamination, if any is present, the next step is to remove the contaminated sequences from the dataset to ensure the integrity of the remaining data. This can be done using bioinformatics tools designed to filter out unwanted sequences, such as BBduk (Bushnell et al. 2017).

BBduk tool is a member of the BBTools package, where ‘Duk’ stands for Decontamination Using Kmers. BBduk filters or trims reads for adapters and contaminants using k-mers, effectively removing unwanted sequences and improving the quality of the dataset.

Additionally, it’s important to document and report the contamination findings to maintain transparency and guide any necessary adjustments in sample collection or processing protocols.

Conclusion

In this tutorial, we inspected the quality of the bacterial isolate sequencing data and checked the expected species and potential contamination. Prepared short reads can be used in downstream analysis, like Genome Assembly. Even after the assembly, you can identify contamination using a tool like CheckM (Parks et al. 2015). CheckM tool can be used for screening the ‘cleanness’ of bacterial assemblies.

To learn more about data quality control, you can follow this tutorial: Quality Control.