Explaining Bacterial Dispersion on Leaf Surfaces with an Individual-Based Model (PHYLLOSIM)

A. van der Wal; R. Tecon; J.U. Kreft; W.M. Mooij; J.H.J. Leveau

doi:10.1371/journal.pone.0075633

Explaining Bacterial Dispersion on Leaf Surfaces with an Individual-Based Model (PHYLLOSIM)

A. van der Wal, R. Tecon, J.U. Kreft, W.M. Mooij, J.H.J. Leveau

Research output: Contribution to journal › Article › Academic › peer-review

13 Citations (Scopus)

Abstract

We developed the individual-based model PHYLLOSIM to explain observed variation in the size of bacterial clusters on plant leaf surfaces (the phyllosphere). Specifically, we tested how different 'waterscapes' impacted the diffusion of nutrients from the leaf interior to the surface and the growth of individual bacteria on these nutrients. In the 'null' model or more complex 'patchy' models, the surface was covered with a continuous water film or with water drops of equal or different volumes, respectively. While these models predicted the growth of individual bacterial immigrants into clusters of variable sizes, they were unable to reproduce experimentally derived, previously published patterns of dispersion which were characterized by a much larger variation in cluster sizes and a disproportionate occurrence of clusters consisting of only one or two bacteria. The fit of model predictions to experimental data was about equally poor (

Original language	English
Article number	e75633
Journal	PLoS ONE
Volume	8
Issue number	10
DOIs	https://doi.org/10.1371/journal.pone.0075633
Publication status	Published - 2013

Keywords

plant-microbe interactions
pseudomonas-syringae
biofilm formation
water availability
growth
detachment
diffusion
motility
colonization
wettability

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abstract = "We developed the individual-based model PHYLLOSIM to explain observed variation in the size of bacterial clusters on plant leaf surfaces (the phyllosphere). Specifically, we tested how different 'waterscapes' impacted the diffusion of nutrients from the leaf interior to the surface and the growth of individual bacteria on these nutrients. In the 'null' model or more complex 'patchy' models, the surface was covered with a continuous water film or with water drops of equal or different volumes, respectively. While these models predicted the growth of individual bacterial immigrants into clusters of variable sizes, they were unable to reproduce experimentally derived, previously published patterns of dispersion which were characterized by a much larger variation in cluster sizes and a disproportionate occurrence of clusters consisting of only one or two bacteria. The fit of model predictions to experimental data was about equally poor (",

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AU - Leveau, J.H.J.

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KW - water availability

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