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Mathematical Biosciences and Engineering

2013, Volume 10, Issue 2: 399-424. doi: 10.3934/mbe.2013.10.399
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Competition of motile and immotile bacterial strains in a petri dish

  • 1.
    Department of Mathematical and Statistical Sciences, University of Alberta, Edmonton, Alberta, T6G 2G1
  • Received: 01 September 2012 Accepted: 29 June 2018 Published: 01 January 2013

  • MSC : Primary: 92B05, 35Kxx, 35C07; Secondary: 92D25, 92D40, 35B35.

  • Bacterial competition is an important component in many practicalapplications such as plant roots colonization and medicine(especially in dental plaque). Bacterial motility has two types ofmechanisms --- directed movement (chemotaxis) and undirectedmovement. We study undirected bacterial movement mathematically andnumerically which is rarely considered in literature. To studybacterial competition in a petri dish, we modify and extend themodel used in Wei et al. (2011) to obtain a group of more generaland realistic PDE models. We explicitly consider the nutrients andincorporate two bacterial strains characterized by motility. We usedifferent nutrient media such as agar and liquid in the theoreticalframework to discuss the results of competition. The consistency ofour numerical simulations and experimental data suggest theimportance of modeling undirected motility in bacteria. In agar themotile strain has a higher total density than the immotile strain,while in liquid both strains have similar total densities.Furthermore, we find that in agar as bacterial motility increases,the extinction time of the motile bacteria decreases withoutcompetition but increases in competition. In addition, we show theexistence of traveling-wave solutions mathematically andnumerically.

    Citation: Silogini Thanarajah, Hao Wang. Competition of motile and immotile bacterial strains in a petri dish[J]. Mathematical Biosciences and Engineering, 2013, 10(2): 399-424. doi: 10.3934/mbe.2013.10.399

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  • Bacterial competition is an important component in many practicalapplications such as plant roots colonization and medicine(especially in dental plaque). Bacterial motility has two types ofmechanisms --- directed movement (chemotaxis) and undirectedmovement. We study undirected bacterial movement mathematically andnumerically which is rarely considered in literature. To studybacterial competition in a petri dish, we modify and extend themodel used in Wei et al. (2011) to obtain a group of more generaland realistic PDE models. We explicitly consider the nutrients andincorporate two bacterial strains characterized by motility. We usedifferent nutrient media such as agar and liquid in the theoreticalframework to discuss the results of competition. The consistency ofour numerical simulations and experimental data suggest theimportance of modeling undirected motility in bacteria. In agar themotile strain has a higher total density than the immotile strain,while in liquid both strains have similar total densities.Furthermore, we find that in agar as bacterial motility increases,the extinction time of the motile bacteria decreases withoutcompetition but increases in competition. In addition, we show theexistence of traveling-wave solutions mathematically andnumerically.


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  • This article has been cited by:

    1. Tianran Zhang, Wendi Wang, Kaifa Wang, Minimal wave speed of a bacterial colony model, 2016, 40, 0307904X, 10419, 10.1016/j.apm.2016.07.028
    2. Tianran Zhang, Qingming Gou, Minimal Wave Speed of Bacterial Colony Model with Saturated Functional Response, 2014, 2014, 1085-3375, 1, 10.1155/2014/510671
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