/qurro

Visualize differentially ranked features (taxa, metabolites, ...) in tandem with log-ratios of their sample abundances

Primary LanguageJavaScriptBSD 3-Clause "New" or "Revised" LicenseBSD-3-Clause

Qurro: Quantitative Rank/Ratio Observations

Qurro logo
QIIME 2 CI Standalone CI Code Coverage DOI PyPI conda-forge

(Pronounced "churro.")

What does this tool do?

Lots of tools for analyzing " 'omic" datasets can produce feature rankings. These rankings can be used as a guide to look at the log-ratios of certain features in a dataset. Qurro is a tool for visualizing and exploring both of these types of data.

What are feature rankings?

The term "feature rankings" includes differentials, which we define as the estimated log-fold changes for features' abundances across different sample types. You can get this sort of output from lots of "differential abundance" tools, including but definitely not limited to ALDEx2, Songbird, Corncob, DESeq2, edgeR, etc.

The term "feature rankings" also includes feature loadings in a biplot (see Aitchison and Greenacre 2002); you can get biplots from running DEICODE, which is a tool that works well with microbiome datasets, or from a variety of other methods.

Differentials and feature loadings alike can be interpreted as rankings -- you can sort them numerically to "rank" features based on their association with some sort of variation in your dataset.

What can we do with feature rankings?

A common use of these rankings is examining the log-ratios of particularly high- or low-ranked features across the samples in your dataset, and seeing how these log-ratios relate to your sample metadata (e.g. "does this log-ratio differ between 'healthy' and 'sick' samples?"). For details as to why this approach is useful, check out this open access paper.

How does this tool help?

Qurro is an interactive web application for visualizing feature rankings and log-ratios. It does this using a two-plot interface: on the left side of the screen, a "rank plot" shows how features are ranked for a selected ranking, and on the right side of the screen a "sample plot" shows the log-ratios of selected features' abundances within samples. There are a variety of controls available for selecting features for a log-ratio, and changing the selected log-ratio updates both the rank plot (highlighting selected features) and the sample plot (changing the y-axis value of each sample to match the selected log-ratio).

A paper describing Qurro is now available at NAR Genomics and Bioinformatics here.

How do I use this tool?

Qurro can be used standalone (as a Python 3 script that generates a folder containing a HTML/JS/CSS visualization) or as a QIIME 2 plugin (that generates a QZV file that can be visualized at view.qiime2.org or by using qiime tools view).

Qurro is still being developed, so backwards-incompatible changes might occur. If you have any bug reports, feature requests, questions, or if you just want to yell at me, then feel free to open an issue in this repository!

Demos

See the Qurro website for a list of interactive demos using real datasets.

Screenshot: Visualizing KEGG orthologs in metagenomic data from the Red Sea

Screenshot showing a Qurro visualization of ranked features (which in this dataset correspond to KEGG orthologs) and a scatterplot plot of the log ratio of certain features' abundances in samples.

This visualization (which uses data from this study, with differentials generated by Songbird) can be viewed online here.

Installation and Usage

You can install Qurro using pip or conda.

System requirements

If you're using Qurro within QIIME 2, you will need a QIIME 2 version of at least 2020.11.

If you're using Qurro outside of QIIME 2, you will need a Python version of at least 3.6 and less than 3.10.

In either case, Qurro should work with most modern web browsers; Firefox or Chrome are recommended.

Installing with pip

pip install cython "numpy >= 1.12.0"
pip install qurro

Installing with conda

conda install -c conda-forge qurro

Temporary Caveat

Certain characters in column names in the sample metadata, feature metadata (if passed), and feature differentials (if passed) will be replaced with similar characters or just removed entirely:

Old Character(s) New Character
. :
] )
[ (
\ |
' or " Nothing

This is due to some downstream issues with handling these sorts of characters in field names. See this issue for context.

Tutorials

In-depth tutorials

These tutorials are all good places to start, depending on what sort of data and feature rankings you have.

  • Color Composition tutorial

    • Data Summary: Color composition data from abstract paintings
    • Feature rankings: Feature loadings in an arbitrary compositional biplot
    • Qurro used through QIIME 2 or standalone?: Standalone
  • "Moving Pictures" tutorial

    • Data Summary: Microbiome 16S rRNA marker gene sequencing data from four types of body site samples
    • Feature rankings: Feature loadings in a DEICODE biplot
    • Qurro used through QIIME 2 or standalone?: QIIME 2
  • Transcriptomics tutorial

    • Data Summary: Gene expression ("RNA-Seq") data from TCGA tumor and "solid tissue normal" samples
    • Feature rankings: ALDEx2 differentials
    • Qurro used through QIIME 2 or standalone?: Standalone

Selection tutorial

There are a lot of different ways to select features in Qurro, and the interface can be difficult to get used to. This document describes all of these methods, and provides some examples of where they could be useful in practice.

Basic command-line tutorials

These tutorials show examples of using Qurro in identical ways both inside and outside of QIIME 2.

Qarcoal

Qarcoal (pronounced "charcoal") is a new part of Qurro that lets you compute log-ratios based on taxonomic searching directly from the command-line. This can be useful for a variety of reasons.

Currently, Qarcoal is only available through Qurro's QIIME 2 plugin interface. Please see qarcoal_example.ipynb for a demonstration of using Qarcoal.

Poster

We presented this poster on Qurro at the 2019 CRISP Annual Review. The data shown here is already slightly outdated compared to the actual Qurro paper (e.g. the differentials are slightly different), but feel free to check out the poster anyway!

Acknowledgements

Dependencies

Code files for the following projects are distributed within qurro/support_files/vendor/. See the qurro/dependency_licenses/ directory for copies of these software projects' licenses (each of which includes a respective copyright notice).

The following software projects are required for Qurro's python code to function, although they are not distributed with Qurro (and are instead installed alongside Qurro).

Testing Dependencies

For python testing/style checking, Qurro uses pytest, pytest-cov, flake8, and black. You'll also need to have QIIME 2 installed to run most of the python tests (note that, due to click vs. black vs. QIIME 2 dependency issues, you should use a QIIME 2 environment of at least 2022.8; see CONTRIBUTING.md for details).

For JavaScript testing/style checking, Qurro uses Mocha, Chai, mocha-headless-chrome, nyc, jshint, and prettier.

Qurro also uses GitHub Actions and Codecov.

The Jupyter notebooks in Qurro's example_notebooks/ folder are automatically rerun using nbconvert, also.

Data Sources

The test data located in qurro/tests/input/mackerel/ were exported from QIIME 2 artifacts in this repository. These data are from Minich et al. 2020 [1].

The test data located in qurro/tests/input/byrd/ are from this repository. These data, in turn, originate from Byrd et al.'s 2017 study on atopic dermatitis [2].

The test data located in qurro/tests/input/sleep_apnea/ (and in example_notebooks/DEICODE_sleep_apnea/input/) are from this Qiita study, which is associated with Tripathi et al.'s 2018 study on sleep apnea [4].

The test data located in qurro/tests/input/moving_pictures/ (and in example_notebooks/moving_pictures/data/) are from the QIIME 2 moving pictures tutorial. The ordination files in these folders were computed based on the DEICODE moving pictures tutorial. These data (sans the DEICODE ordination) are associated with Caporaso et al. 2011 [5].

Lastly, the data located in qurro/tests/input/red_sea (and in example_notebooks/songbird_red_sea/input/, and shown in the screenshot above) were taken from Songbird's GitHub repository in its data/redsea/ folder, and are associated with Thompson et al. 2017 [3].

Logo

Qurro's logo was created using the Lalezar font. Also, shout out to this gist for showing how to center images in GitHub markdown files (which is more of a hassle than it sounds).

Special Thanks

The design of Qurro was strongly inspired by EMPeror and q2-emperor, along with DEICODE. A big shoutout to Yoshiki Vázquez-Baeza for his help in planning this project, as well as to Cameron Martino for a ton of work on getting the code in a distributable state (and making it work with QIIME 2). Thanks also to Jamie Morton, who wrote the original code for producing rank and sample plots from which this is derived.

And thanks to a bunch of the Knight Lab for helping name the tool :)

Citing Qurro

If you use Qurro in your research, please cite it! The preferred citation for Qurro is this manuscript at NAR Genomics and Bioinformatics. Here's the BibTeX:

@article {fedarko2020,
    author = {Fedarko, Marcus W and Martino, Cameron and Morton, James T and González, Antonio and Rahman, Gibraan and Marotz, Clarisse A and Minich, Jeremiah J and Allen, Eric E and Knight, Rob},
    title = "{Visualizing ’omic feature rankings and log-ratios using Qurro}",
    journal = {NAR Genomics and Bioinformatics},
    volume = {2},
    number = {2},
    year = {2020},
    month = {04},
    issn = {2631-9268},
    doi = {10.1093/nargab/lqaa023},
    url = {https://doi.org/10.1093/nargab/lqaa023},
    note = {lqaa023},
    eprint = {https://academic.oup.com/nargab/article-pdf/2/2/lqaa023/33137933/lqaa023.pdf},
}

References

[1] Minich, J. J., Petrus, S., Michael, J. D., Michael, T. P., Knight, R., & Allen, E. E. (2020). Temporal, environmental, and biological drivers of the mucosal microbiome in a wild marine fish, Scomber japonicus. mSphere, 5(3), e00401-20. Link.

[2] Byrd, A. L., Deming, C., Cassidy, S. K., Harrison, O. J., Ng, W. I., Conlan, S., ... & NISC Comparative Sequencing Program. (2017). Staphylococcus aureus and Staphylococcus epidermidis strain diversity underlying pediatric atopic dermatitis. Science Translational Medicine, 9(397), eaal4651. Link.

[3] Thompson, L. R., Williams, G. J., Haroon, M. F., Shibl, A., Larsen, P., Shorenstein, J., ... & Stingl, U. (2017). Metagenomic covariation along densely sampled environmental gradients in the Red Sea. The ISME Journal, 11(1), 138. Link.

[4] Tripathi, A., Melnik, A. V., Xue, J., Poulsen, O., Meehan, M. J., Humphrey, G., ... & Haddad, G. (2018). Intermittent hypoxia and hypercapnia, a hallmark of obstructive sleep apnea, alters the gut microbiome and metabolome. mSystems, 3(3), e00020-18. Link.

[5] Caporaso, J. G., Lauber, C. L., Costello, E. K., Berg-Lyons, D., Gonzalez, A., Stombaugh, J., ... & Gordon, J. I. (2011). Moving pictures of the human microbiome. Genome Biology, 12(5), R50. Link.

License

This tool is licensed under the BSD 3-clause license. Our particular version of the license is based on scikit-bio's license.