A mechanistic Individual-based Model of microbial communities.

Pahala Gedara Jayathilake,David Swailes,A Stephen Mcgough,Steve Rushton,Oluwole Oyebamiji,Ben Bridgens,Jinju Chen,Curtis Madsen,Ben Allen,Prashant Gupta,Bowen Li,Rebeca González-Cabaleiro,Irina Dana Ofiteru,Paolo Zuliani,Tom Curtis,Darren Wilkinson

doi:10.1371/journal.pone.0181965

Pahala Gedara Jayathilake, David Swailes + Show 14 more

Open Access

https://doi.org/10.1371/journal.pone.0181965

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Journal: PLOS ONE	Publication Date: Aug 3, 2017
Citations: 70	License type: CC BY 4.0

Affiliation: Newcastle University

Abstract

Accurate predictive modelling of the growth of microbial communities requires the credible representation of the interactions of biological, chemical and mechanical processes. However, although biological and chemical processes are represented in a number of Individual-based Models (IbMs) the interaction of growth and mechanics is limited. Conversely, there are mechanically sophisticated IbMs with only elementary biology and chemistry. This study focuses on addressing these limitations by developing a flexible IbM that can robustly combine the biological, chemical and physical processes that dictate the emergent properties of a wide range of bacterial communities. This IbM is developed by creating a microbiological adaptation of the open source Large-scale Atomic/Molecular Massively Parallel Simulator (LAMMPS). This innovation should provide the basis for “bottom up” prediction of the emergent behaviour of entire microbial systems. In the model presented here, bacterial growth, division, decay, mechanical contact among bacterial cells, and adhesion between the bacteria and extracellular polymeric substances are incorporated. In addition, fluid-bacteria interaction is implemented to simulate biofilm deformation and erosion. The model predicts that the surface morphology of biofilms becomes smoother with increased nutrient concentration, which agrees well with previous literature. In addition, the results show that increased shear rate results in smoother and more compact biofilms. The model can also predict shear rate dependent biofilm deformation, erosion, streamer formation and breakup.

Highlights

When using typical parameters for each functional group and nutrient conditions [32,33], it is found that the growth of Ammonia Oxidizing Bacteria (AOB) and Nitrite Oxidizing Bacteria (NOB) is negligible comparted to HET and HET dominates in the biofilm (Fig 3)
It is worth noting that HET could be outcompeted by AOB and NOB if the nutrients and initial inoculation were more favourable for AOB and NOB
The Individualbased Models (IbMs) developed in this study enables us to predict biofilm deformation, detachment and streamer formation based on mechanical interactions between Extracellular Polymeric Substances (EPS) and cells