Revision as of 16:56, 28 March 2019

Context

How fungi or plants invade a medium, how sexually transmitted diseases spread over a population, how cancer tumors grow in human bodies, how communication routes densify, are questions that may seem to refer to quite unrelated problems. However, the structure, dynamics and shape of the underlying network may rely on very similar models. The nature of such networks is not uniquely defined: some examples are informational networks (of relation between individuals, citation graphs,...), technological (power grids, public transportation, computer network,...), or biological (vascular, biochemical, neural network,...). In all the aforementioned examples, transformation arises from individuals, be it the development of a new connection between existing entities, as it often appears in neurons, or the introduction of a new individual in the system. All these contributions sum up to the evolution of the network as a unit on the macroscopic level. Modeling of such intricate processes ranges from simple explanatory toy-models to more realistic approaches, which need to be able to capture modifications at different scales. This can be achieved by linking microscopic objects, which describe individuals, with their collective mean behavior. Techniques borrowing from statistical physics for the analysis of nonlinear, non-equilibrium physical systems in the study of such collective behavior are of increasing use, in e.g. social, economical or biological systems.

The expansion of such networks may also be hindered by internal or external constraints which can significantly affect the observed results and patterns. When explicitly including the spatial dimension, the models considered may provide a pertinent description of the interaction processes at the small (micro) scale as well as the large (macro)scale featuring the emerging behavior, possibly under the form of a (thin) propagating front. The modeling and analysis of such dynamical processes within a multi-scale framework, where the different granularities of the system are to be considered, is a complex research field, that requires involving various disciplines.

In this project, we will specifically address the modeling and analysis of the expanding interconnected hyphal network (the vegetative filaments produced to form the mycelium) of the fungus Podospora anserina.

110 px

240 px

Left: Example of the reconstitution (as reconstructed by numerous pictures juxtaposition and conformal mapping, 112 tiles) of the complete thallus of P. anserina, grown 23h on a Petri dish. The diameter is approx. 20 mm.
Center: small-scale (approx. 1 mm) image processing and vectorization; raw data from experiment (at time t=18h) is superimposed to the output of the vectorization process.
Right: observed macroscopic mycelium (diameter around 8 cm) after a 4 day-growth. Note the expanding front, represented by the hyphal concentration isovalues shown at different times (colored lines).

A toy-model: Podospora Anserina

In real-life conditions, P. anserina is a coprophilous filamentous ascomycete that grows on herbivore dungs, a highly competitive habitat where several dozens of species are present and feed on partially degraded plant material. The success of the filamentous fungi group in colonizing most natural environments (from Antarctic ice to hot deserts and seawater) can be largely attributed to hyphal growth and branching, allowing an efficient spatial exploration and exploitation of the nutritive resources. Some species, especially pathogens, present a finely tuned regulation between a filamentous growth and a unicellular growth, the latter property being essential for pathogenicity. Within the Biology group at LIED Paris-Diderot, P. anserina is used as an efficient lab model because:

• it is very easy (and cheap!) to grow,
• the complete sexual cycle can be obtained in vitro in seven days, and yields to the production of sexual spores, named ascospores,
• the availability of its genome sequence has enabled the development of several useful tools in molecular and cellular biology, as well as in cytology.

It hence represents a convenient lab-scale (toy)model for studying the development of filamentous fungi, or even more general living systems networks. The efficient growth of such filamentous fungi is adapted through a mycelial network, in particular in the presence of external constraints disturbing or impeding the environmental exploration. Constraints can be of different nature: e.g. i) chemical/physical like various carbon source, nutrient deficiency/gradient, temperature gradient, hygrometry, electric field, presence of a toxic chemical compound, ii) mechanical like the avoiding of an obstacle or a labyrinthic geometry and also iii) biological like the presence of another organism or the local deletion of the hyphal network.

Note that the biological characterization of P. anserina mutants available at LIED, affected in some key steps of their growth or development, is of interest per se, e.g. for the study of cell wall biogenesis, cellular polarization and branching process. Developing quantitative tools, in collaboration with physicists, allows to determine the growth velocity of hyphae, to analyze the occurrence of branching and to measure hyphal density over time. Also note that the question of scales is indeed of paramount importance: the hypha is a few microns wide (typically 4 to 6), while the mycelial network can operate on scales ranging from a few square cm up to many square km.

Participants

Yves D'Angelo (SC), Rémi Catellier, Laurent Monasse (LJAD), Florence Chapeland-Leclerc, Gwenaël Ruprich-Robert, Eric Herbert, Cécilia Bobée, Pascal David (LIED), Adélaïde Olivier (Lab Math at Orsay), Amandine Véber (CMAP, Ecole Polytechnique, Palaiseau), Franco Flandoli (Scuola Normale di Pisa).