Mapping quorum sensing onto neural networks to understand collective decision making in heterogeneous microbial communities

Yusufaly, Tahir; Boedicker, James

doi:10.1088/1478-3975/aa7c1e

Cited by 6 publications

(7 citation statements)

References 54 publications

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“…While the modelling approach based on individual cells pursued here is very flexible and can accommodate many different features, approaches based on differential equations for chemical concentrations have the advantage that, at least in some limits, analytical solutions can be obtained 26,47 . In addition to these two strategies network-based approaches have been suggested 96 . We finally note that some of the results observed here may have relevance in morphogen-gradient based problems, in which the spatial distribution of the concentration of stimulating molecules can trigger a certain response of tissues.…”

Section: Discussionmentioning

confidence: 99%

Burst statistics in an early biofilm quorum sensing model: the role of spatial colony-growth heterogeneity

Kindler

Pulkkinen

Cherstvy

et al. 2019

Sci Rep

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Quorum-sensing bacteria in a growing colony of cells send out signalling molecules (so-called “autoinducers”) and themselves sense the autoinducer concentration in their vicinity. Once—due to increased local cell density inside a “cluster” of the growing colony—the concentration of autoinducers exceeds a threshold value, cells in this clusters get “induced” into a communal, multi-cell biofilm-forming mode in a cluster-wide burst event. We analyse quantitatively the influence of spatial disorder, the local heterogeneity of the spatial distribution of cells in the colony, and additional physical parameters such as the autoinducer signal range on the induction dynamics of the cell colony. Spatial inhomogeneity with higher local cell concentrations in clusters leads to earlier but more localised induction events, while homogeneous distributions lead to comparatively delayed but more concerted induction of the cell colony, and, thus, a behaviour close to the mean-field dynamics. We quantify the induction dynamics with quantifiers such as the time series of induction events and burst sizes, the grouping into induction families, and the mean autoinducer concentration levels. Consequences for different scenarios of biofilm growth are discussed, providing possible cues for biofilm control in both health care and biotechnology.

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Section: Discussionmentioning

confidence: 99%

Burst statistics in an early biofilm quorum sensing model: the role of spatial colony-growth heterogeneity

Kindler

Pulkkinen

Cherstvy

et al. 2019

Sci Rep

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“…Rudge et al observed the emergence of striking fractal patterns in growing colonies of E. coli [48]. Physical models such as the Hopfield model have also been implemented to predict how the capacity for groups of cells to make decisions scales with the number of cell types [44]. In the spirit of these observations, here we have identified that disrupting the long-range communication of a quorum sensing microbe through interference by a degrader strain yields complex physical behavior characteristic of a percolation transition.…”

Section: Discussionmentioning

confidence: 70%

“…With the recent advances in systems and molecular biology, many new studies are being conducted to understand the complex behaviors of microbes that arise due to cellular and spatial heterogeneity [9,[26][27][28][41][42][43][44]. Several studies have shown that many cellular systems exhibit emergent phenomena previously studied in non-biological contexts and that can be explained using physical and statistical mechanical rules [45][46][47][48].…”

Section: Discussionmentioning

confidence: 99%

Disruption of microbial communication yields a two-dimensional percolation transition

et al. 2019

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Bacteria communicate with each other to coordinate macro-scale behaviors including pathogenesis, biofilm formation and antibiotic production. Empirical evidence suggests that bacteria are capable of communicating at length scales far exceeding the size of individual cells. Several mechanisms of signal interference have been observed in nature, and how interference influences macro-scale activity within microbial populations is unclear. Here we examined the exchange of quorum sensing signals to coordinate microbial activity over long distances in the presence of a variable amount of interference through a neighboring signal-degrading strain. As the level of interference increased, communication over large distances was disrupted and at a critical amount of interference, large-scale communication was suppressed. We explored this transition in experiments and reaction-diffusion models, and confirmed that this transition is a 2D percolation transition. These results demonstrate the utility of applying physical models to emergence in complex biological networks to probe robustness and universal quantitative features.

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“…To quantify the interaction weight between strains, we constructed a mathematical model. The model is based on a set of differential equations and accounts for signal crosstalk by introducing a crosstalk weight for each pair of receptor and signal, similar to models used previously [5,34]. Specifically, the expression of the QS-regulated gene lacZ follows: where the effective concentration of signal as the result of crosstalk is, …”

Section: Resultsmentioning

confidence: 99%

“…Interactions between network components influence state dynamics and are represented as weights, with the magnitude of the weight indicating the strength of the interaction and the sign of the weight indicating whether the interaction promotes or inhibits activation. We have previously implemented a neural network to theoretically analyze the information capacity within a QS networks composed to multiple Staphylococcus aureus strains [34]. Here we extend these ideas, combining both experimental and theoretical results, to test whether neural network models can be used to predict and control the activation of QS in communities of bacteria producing multiple signals.…”

Section: Introductionmentioning

confidence: 99%

A neural network model predicts community-level signaling states in a diverse microbial community

Silva

Boedicker

2019

PLoS Comput Biol

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Signal crosstalk within biological communication networks is common, and such crosstalk can have unexpected consequences for decision making in heterogeneous communities of cells. Here we examined crosstalk within a bacterial community composed of five strains of Bacillus subtilis , with each strain producing a variant of the quorum sensing peptide ComX. In isolation, each strain produced one variant of the ComX signal to induce expression of genes associated with bacterial competence. When strains were combined, a mixture of ComX variants was produced resulting in variable levels of gene expression. To examine gene regulation in mixed communities, we implemented a neural network model. Experimental quantification of asymmetric crosstalk between pairs of strains parametrized the model, enabling the accurate prediction of activity within the full five-strain network. Unlike the single strain system in which quorum sensing activated upon exceeding a threshold concentration of the signal, crosstalk within the five-strain community resulted in multiple community-level quorum sensing states, each with a unique combination of quorum sensing activation among the five strains. Quorum sensing activity of the strains within the community was influenced by the combination and ratio of strains as well as community dynamics. The community-level signaling state was altered through an external signal perturbation, and the output state depended on the timing of the perturbation. Given the ubiquity of signal crosstalk in diverse microbial communities, the application of such neural network models will increase accuracy of predicting activity within microbial consortia and enable new strategies for control and design of bacterial signaling networks.

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Mapping quorum sensing onto neural networks to understand collective decision making in heterogeneous microbial communities

Cited by 6 publications

References 54 publications

Burst statistics in an early biofilm quorum sensing model: the role of spatial colony-growth heterogeneity

Burst statistics in an early biofilm quorum sensing model: the role of spatial colony-growth heterogeneity

Disruption of microbial communication yields a two-dimensional percolation transition

A neural network model predicts community-level signaling states in a diverse microbial community

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