Evidence for emergent behaviour in the community-scale dynamics of a fungal microcosm

Bown, James L.; Sturrock, Craig J.; Samson, W. B.; Staines, Harry; Palfreyman, John W.; White, Nia A.; Ritz, Karl; Crawford, John W.

doi:10.1098/rspb.1999.0871

Cited by 14 publications

(21 citation statements)

References 16 publications

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“…Likewise, the model presented in Bown et al (1999) is not able to predict the interaction outcomes detailed here.…”

Section: Discussionmentioning

confidence: 91%

“…Such a modelling framework permits an investigative approach (Marks & Lechowicz 2006), where we are able to explore and interpret the underlying mechanisms that lead to the colony formations. The only other modelling frameworks that we are aware of, which consider fungal interactions, are Davidson et al (1996) and Bown et al (1999). Davidson et al (1996) consider fungal interactions in terms of a collision between two initially distinct activator concentrations (an initial activator concentration corresponds to a fungal inoculum).…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Modelling interactions in fungi

Falconer

Bown

White

et al. 2007

J. R. Soc. Interface.

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Indeterminate organisms have received comparatively little attention in theoretical ecology and still there is much to be understood about the origins and consequences of community structure. The fungi comprise an entire kingdom of life and epitomize the indeterminate growth form. While interactions play a significant role in shaping the community structure of indeterminate organisms, to date most of our knowledge relating to fungi comes from observing interaction outcomes between two species in two-dimensional arena experiments. Interactions in the natural environment are more complex and further insight will benefit from a closer integration of theory and experiment. This requires a modelling framework capable of linking genotype and environment to community structure and function. Towards this, we present a theoretical model that replicates observed interaction outcomes between fungal colonies. The hypotheses underlying the model propose that interaction outcome is an emergent consequence of simple and highly localized processes governing rates of uptake and remobilization of resources, the metabolic cost of production of antagonistic compounds and non-localized transport of internal resources. The model may be used to study systems of many interacting colonies and so provides a platform upon which the links between individual-scale behaviour and community-scale function in complex environments can be built.

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“…Likewise, the model presented in Bown et al (1999) is not able to predict the interaction outcomes detailed here.…”

Section: Discussionmentioning

confidence: 91%

Section: Discussionmentioning

confidence: 99%

Modelling interactions in fungi

Falconer

Bown

White

et al. 2007

J. R. Soc. Interface.

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show abstract

“…This communication can be enhanced by some hyphae fusing and becoming anastomosised (see centre of figure 1(b)). Thus the colony can be considered an integrated unit and is more than the sum of its individual hyphae [3]. Different events occurring within the colony cannot therefore be totally independent and the local environments occurring within the mycelial boundary cannot all be treated as entirely separate domains.…”

Section: Fungal Coloniesmentioning

confidence: 99%

A New Paradigm for SpeckNets: Inspiration from Fungal Colonies

Falconer

Bown

Hart

et al. 2008

2008 Second IEEE International Conference on Self-Adaptive and Self-Organizing Systems Workshops

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In this position paper, we propose the development of a new biologically inspired paradigm based on fungal colonies, for the application to pervasive adaptive systems. Fungal colonies have a number of properties that make them an excellent candidate for inspiration for engineered systems. Here we propose the application of such inspiration to a speckled computing platform. We argue that properties from fungal colonies map well to properties and requirements for controlling SpeckNets and suggest that an existing mathematical model of a fungal colony can developed into a new computational paradigm.

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“…A mycelium, or fungal colony, has no characteristic scale above that of an individual hypha (the basic unit of the mycelium) and can potentially persist indefinitely, reproducing when environmental circumstances are favourable. The connected nature of the mycelial network means that local behaviour can, and is, affected by conditions in remote parts of the colony via mechanisms including translocation (White et al 1998;Bown et al 1999;Olsson 1999). Therefore, the behaviour of the colony is dependent on the interaction between genotype and a complex spatial convolution of environmental conditions across the whole mycelium.…”

Section: Introductionmentioning

confidence: 99%

“…Although phenomenological, the model illustrates the important point that relatively few processes can be orchestrated by different contexts to produce wide-ranging phenotypes, and this capacity must be embodied in any general representation. Bown et al (1999) chose a multi-scaled approach to examine the relative contribution of local and non-local effects on the dynamics of a two-species fungal microcosm. This model represents implicitly the physiological processes that are important in the outcome of individual fungal interactions.…”

Section: Introductionmentioning

confidence: 99%

Biomass recycling and the origin of phenotype in fungal mycelia

et al. 2005

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Fungi are one of the most important and widespread components of the biosphere, and are essential for the growth of over 90% of all vascular plants. Although they are a separate kingdom of life, we know relatively little about the origins of their ubiquitous existence. This reflects a wider ignorance arising from their status as indeterminate organisms epitomized by extreme phenotypic plasticity that is essential for survival in complex environments. Here we show that the fungal phenotype may have its origins in the defining characteristic of indeterminate organisms, namely their ability to recycle locally immobilized internal resources into a mobilized form capable of being directed to new internal sinks. We show that phenotype can be modelled as an emergent phenomenon resulting from the interplay between simple local processes governing uptake and remobilization of internal resources, and macroscopic processes associated with their transport. Observed complex growth forms are reproduced and the sensitive dependence of phenotype on environmental context may be understood in terms of nonlinearities associated with regulation of the recycling apparatus.

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Evidence for emergent behaviour in the community-scale dynamics of a fungal microcosm

Cited by 14 publications

References 16 publications

Modelling interactions in fungi

Modelling interactions in fungi

A New Paradigm for SpeckNets: Inspiration from Fungal Colonies

Biomass recycling and the origin of phenotype in fungal mycelia

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