Search Menu
DOE PAGES title logo U.S. Department of Energy
Office of Scientific and Technical Information
Search Scholarly Publications

Title: Deep learning predicts microbial interactions from self-organized spatiotemporal patterns

Abstract

Microorganisms in terrestrial habitats self-organize to form specific spatial patterns through their interactions with each other and with the environment. Spatial patterns of microorganisms can therefore be viewed as a key ecological phenotype. However, their use for predicting microbial interactions is currently lacking, primarily due to an intrinsic limitation of current network inference methods that are based on population-level analyses. To address this gap, here we propose supervised deep learning as a new tool for predicting interspecies interactions from spatial patterns of microbial assembly. In a case study of two interacting organisms, we developed an agent-based model to simulate their spatiotemporal evolution under diverse growth and interaction scenarios. These data were subsequently used as a primary source to train, validate, and test deep neural networks. To do so, we first tested the effectiveness of the deep learning method for small-size domains (100 µm × 100 µm) over which interaction coefficients are assumed to be invariant. We obtained fairly accurate predictions, as indicated by an average R2 value of 0.84. We further tested how deep learning models can be extended to relatively larger domains (450 µm × 450 µm) where interaction coefficients are varying in space. Notably, without any additional training,more » our deep neural network model was able to successfully recover the spatial distribution of interaction coefficients. Lastly, we evaluated the applicability of our computational approach to real biological data through imaging experiments of binary interactions between Pseudomonas fluorescens and a mutant of Escherichia coli. These co-culture experiments were designed to control interactions as a function of environmental conditions. For example, P. fluorescens and E. coli develop a degrader-cheater relationship when growing on chitin polymers, which however turns into competition when growing on chitin hydrolysis products (i.e., N-acetyl glucosamine). Consistent with our expectations, the analysis of real images using the deep neural network model correctly predicted the dramatic shifts in interactions of the two organisms in the two different environmental contexts mentioned above. The combined use of the agent-based model and machine learning algorithm developed in this work successfully demonstrates how to infer microbial interactions from spatially distributed data, presenting itself as a useful tool for the analysis of more complex microbial community interactions.« less

Authors:
ORCiD logo; ; ; ; ; ;
Publication Date:
Research Org.:
Pacific Northwest National Lab. (PNNL), Richland, WA (United States)
Sponsoring Org.:
USDOE
OSTI Identifier:
1762535
Alternate Identifier(s):
OSTI ID: 1633302
Report Number(s):
PNNL-SA-150281
Journal ID: ISSN 2001-0370; S2001037020302865; PII: S2001037020302865
Grant/Contract Number:  
AC05-76RL01830
Resource Type:
Published Article
Journal Name:
Computational and Structural Biotechnology Journal
Additional Journal Information:
Journal Name: Computational and Structural Biotechnology Journal Journal Volume: 18 Journal Issue: C; Journal ID: ISSN 2001-0370
Publisher:
Elsevier
Country of Publication:
Sweden
Language:
English
Subject:
59 BASIC BIOLOGICAL SCIENCES; 97 MATHEMATICS AND COMPUTING; Machine learning; Agent-based modeling; Soil microbiomes; Microscopy imaging technology; Network inference

Citation Formats

Lee, Joon-Yong, Sadler, Natalie C., Egbert, Robert G., Anderton, Christopher R., Hofmockel, Kirsten S., Jansson, Janet K., and Song, Hyun-Seob. Deep learning predicts microbial interactions from self-organized spatiotemporal patterns. Sweden: N. p., 2020. Web. doi:10.1016/j.csbj.2020.05.023.
Copy to clipboard
Lee, Joon-Yong, Sadler, Natalie C., Egbert, Robert G., Anderton, Christopher R., Hofmockel, Kirsten S., Jansson, Janet K., & Song, Hyun-Seob. Deep learning predicts microbial interactions from self-organized spatiotemporal patterns. Sweden. https://doi.org/10.1016/j.csbj.2020.05.023
Copy to clipboard
Lee, Joon-Yong, Sadler, Natalie C., Egbert, Robert G., Anderton, Christopher R., Hofmockel, Kirsten S., Jansson, Janet K., and Song, Hyun-Seob. Wed . "Deep learning predicts microbial interactions from self-organized spatiotemporal patterns". Sweden. https://doi.org/10.1016/j.csbj.2020.05.023.
Copy to clipboard
@article{osti_1762535,
title = {Deep learning predicts microbial interactions from self-organized spatiotemporal patterns},
author = {Lee, Joon-Yong and Sadler, Natalie C. and Egbert, Robert G. and Anderton, Christopher R. and Hofmockel, Kirsten S. and Jansson, Janet K. and Song, Hyun-Seob},
abstractNote = {Microorganisms in terrestrial habitats self-organize to form specific spatial patterns through their interactions with each other and with the environment. Spatial patterns of microorganisms can therefore be viewed as a key ecological phenotype. However, their use for predicting microbial interactions is currently lacking, primarily due to an intrinsic limitation of current network inference methods that are based on population-level analyses. To address this gap, here we propose supervised deep learning as a new tool for predicting interspecies interactions from spatial patterns of microbial assembly. In a case study of two interacting organisms, we developed an agent-based model to simulate their spatiotemporal evolution under diverse growth and interaction scenarios. These data were subsequently used as a primary source to train, validate, and test deep neural networks. To do so, we first tested the effectiveness of the deep learning method for small-size domains (100 µm × 100 µm) over which interaction coefficients are assumed to be invariant. We obtained fairly accurate predictions, as indicated by an average R2 value of 0.84. We further tested how deep learning models can be extended to relatively larger domains (450 µm × 450 µm) where interaction coefficients are varying in space. Notably, without any additional training, our deep neural network model was able to successfully recover the spatial distribution of interaction coefficients. Lastly, we evaluated the applicability of our computational approach to real biological data through imaging experiments of binary interactions between Pseudomonas fluorescens and a mutant of Escherichia coli. These co-culture experiments were designed to control interactions as a function of environmental conditions. For example, P. fluorescens and E. coli develop a degrader-cheater relationship when growing on chitin polymers, which however turns into competition when growing on chitin hydrolysis products (i.e., N-acetyl glucosamine). Consistent with our expectations, the analysis of real images using the deep neural network model correctly predicted the dramatic shifts in interactions of the two organisms in the two different environmental contexts mentioned above. The combined use of the agent-based model and machine learning algorithm developed in this work successfully demonstrates how to infer microbial interactions from spatially distributed data, presenting itself as a useful tool for the analysis of more complex microbial community interactions.},
doi = {10.1016/j.csbj.2020.05.023},
journal = {Computational and Structural Biotechnology Journal},
number = C,
volume = 18,
place = {Sweden},
year = {Wed Jan 01 00:00:00 EST 2020},
month = {Wed Jan 01 00:00:00 EST 2020}
}
Copy to clipboard
Journal Article:
Free Publicly Available Full Text
Publisher's Version of Record
https://doi.org/10.1016/j.csbj.2020.05.023
Copyright Statement
Other availability
Search WorldCat Search WorldCat to find libraries that may hold this journal

Figures / Tables:

Fig. 1 Fig. 1: Deep learning pipeline to infer microbial interactions from microbial assembly patterns: (a) training deep learning networks using in silico images generated from agent-based models to predict interactions from new test (or unseen) datasets. aGR and aRB represent the effect of R (red) on the growth of G (green)more » and the effect of G on the growth of R, respectively; (b) prediction of spatial variation of interaction coefficients in real images using a sliding window method (left panel), final prediction determined by taking averages from an ensemble of best-performing deep learning models (middle panel), and interaction heatmaps generated by integrating neighboring sliding window estimations (right panel).« less
All figures and tables (6 total)
Save / Share:
Export Metadata
Save to My Library
You must Sign In or Create an Account in order to save documents to your library.

Works referenced in this record:

Spatial Ecology of Bacteria at the Microscale in Soil
journal, January 2014

Microbial interactions: from networks to models
journal, July 2012

  • Faust, Karoline; Raes, Jeroen
  • Nature Reviews Microbiology, Vol. 10, Issue 8
  • DOI: 10.1038/nrmicro2832

Colony analysis and deep learning uncover 5-hydroxyindole as an inhibitor of gliding motility and iridescence in Cellulophaga lytica
journal, March 2018

  • Chapelais-Baron, Maylis; Goubet, Isabelle; Péteri, Renaud
  • Microbiology, Vol. 164, Issue 3
  • DOI: 10.1099/mic.0.000617

Deep learning
journal, May 2015

  • LeCun, Yann; Bengio, Yoshua; Hinton, Geoffrey
  • Nature, Vol. 521, Issue 7553
  • DOI: 10.1038/nature14539

Deep learning and process understanding for data-driven Earth system science
journal, February 2019

Chromatic Bacteria – A Broad Host-Range Plasmid and Chromosomal Insertion Toolbox for Fluorescent Protein Expression in Bacteria
journal, December 2018

Selection, Succession, and Stabilization of Soil Microbial Consortia
journal, May 2019

Live imaging of root–bacteria interactions in a microfluidics setup
journal, March 2017

  • Massalha, Hassan; Korenblum, Elisa; Malitsky, Sergey
  • Proceedings of the National Academy of Sciences, Vol. 114, Issue 17
  • DOI: 10.1073/pnas.1618584114

Human-level control through deep reinforcement learning
journal, February 2015

  • Mnih, Volodymyr; Kavukcuoglu, Koray; Silver, David
  • Nature, Vol. 518, Issue 7540
  • DOI: 10.1038/nature14236

Advancing microbial sciences by individual-based modelling
journal, June 2016

  • Hellweger, Ferdi L.; Clegg, Robert J.; Clark, James R.
  • Nature Reviews Microbiology, Vol. 14, Issue 7
  • DOI: 10.1038/nrmicro.2016.62

Automatic early stopping using cross validation: quantifying the criteria
journal, June 1998

Deciphering links between bacterial interactions and spatial organization in multispecies biofilms
journal, August 2019

Construction of Escherichia coli K-12 in-frame, single-gene knockout mutants the Keio collection
journal, February 2006

  • Baba, Tomoya; Ara, Takeshi; Hasegawa, Miki
  • Molecular Systems Biology, Vol. 2, Article No. 2006.0008
  • DOI: 10.1038/msb4100050

Minimal Interspecies Interaction Adjustment (MIIA): Inference of Neighbor-Dependent Interactions in Microbial Communities
journal, June 2019

Cross-biome patterns in soil microbial respiration predictable from evolutionary theory on thermal adaptation
journal, January 2019

  • Bradford, Mark A.; McCulley, Rebecca L.; Crowther, Thomas. W.
  • Nature Ecology & Evolution, Vol. 3, Issue 2
  • DOI: 10.1038/s41559-018-0771-4

Soil biofilms: microbial interactions, challenges, and advanced techniques for ex-situ characterization
journal, July 2019

Microbial interactions and community assembly at microscales
journal, June 2016

Exact stochastic simulation of coupled chemical reactions
journal, December 1977

  • Gillespie, Daniel T.
  • The Journal of Physical Chemistry, Vol. 81, Issue 25
  • DOI: 10.1021/j100540a008

Mathematical Modeling of Microbial Community Dynamics: A Methodological Review
journal, October 2014

  • Song, Hyun-Seob; Cannon, William; Beliaev, Alexander
  • Processes, Vol. 2, Issue 4
  • DOI: 10.3390/pr2040711

Micro-scale determinants of bacterial diversity in soil
journal, November 2013

  • Vos, Michiel; Wolf, Alexandra B.; Jennings, Sarah J.
  • FEMS Microbiology Reviews, Vol. 37, Issue 6
  • DOI: 10.1111/1574-6976.12023

A microfluidics-based in situ chemotaxis assay to study the behaviour of aquatic microbial communities
journal, August 2017

  • Lambert, Bennett S.; Raina, Jean-Baptiste; Fernandez, Vicente I.
  • Nature Microbiology, Vol. 2, Issue 10
  • DOI: 10.1038/s41564-017-0010-9

Modeling and Simulating Chemical Reactions
journal, January 2008

Phenotypic responses to interspecies competition and commensalism in a naturally-derived microbial co-culture
journal, January 2018

A primer on deep learning in genomics
journal, November 2018

Systems-level analysis of microbial community organization through combinatorial labeling and spectral imaging
journal, February 2011

  • Valm, A. M.; Welch, J. L. M.; Rieken, C. W.
  • Proceedings of the National Academy of Sciences, Vol. 108, Issue 10
  • DOI: 10.1073/pnas.1101134108

Cell-to-cell bacterial interactions promoted by drier conditions on soil surfaces
journal, September 2018

  • Tecon, Robin; Ebrahimi, Ali; Kleyer, Hannah
  • Proceedings of the National Academy of Sciences, Vol. 115, Issue 39
  • DOI: 10.1073/pnas.1808274115

A general method for numerically simulating the stochastic time evolution of coupled chemical reactions
journal, December 1976

A guide to deep learning in healthcare
journal, January 2019

Strong inter-population cooperation leads to partner intermixing in microbial communities
journal, January 2013

  • Momeni, Babak; Brileya, Kristen A.; Fields, Matthew W.
  • eLife, Vol. 2
  • DOI: 10.7554/eLife.00230

Random Forests
journal, January 2001

    Sort by:
    [ × clear filter / sort ]

    Figures / Tables found in this record:

    Fig. 1 (p. 3)figure
    Table 1 (p. 6)table
    Fig. 2 (p. 7)figure
    Fig. 3 (p. 8)figure
    Fig. 4 (p. 8)figure
    Fig. 5 (p. 9)figure
      [ × clear filter / sort ]
      Figures/Tables have been extracted from DOE-funded journal article accepted manuscripts.

      Similar Records in DOE PAGES and OSTI.GOV collections: