A stochastic multicellular model identifies biological watermarks from disorders in self-organized patterns of phyllotaxis
Yassin Refahi,
Géraldine Brunoud,
Etienne Farcot,
Alain Jean-Marie,
Minna Pulkkinen,
Teva Vernoux,
Christophe Godin
Affiliations
Yassin Refahi
Laboratoire de Reproduction de développement des plantes, Lyon, France; Sainsbury Laboratory, University of Cambridge, Cambridge, United Kingdom
Géraldine Brunoud
Laboratoire de Reproduction de développement des plantes, Lyon, France
Etienne Farcot
School of Mathematical Sciences, The University of Nottingham, Nottingham, United Kingdom; Center for Integrative Plant Biology, The University of Nottingham, Notthingam, United Kingdom
Alain Jean-Marie
INRIA Project-Team Maestro, INRIA Sophia-Antipolis Méditerranée Research Center, Montpellier, France
Exploration of developmental mechanisms classically relies on analysis of pattern regularities. Whether disorders induced by biological noise may carry information on building principles of developmental systems is an important debated question. Here, we addressed theoretically this question using phyllotaxis, the geometric arrangement of plant aerial organs, as a model system. Phyllotaxis arises from reiterative organogenesis driven by lateral inhibitions at the shoot apex. Motivated by recurrent observations of disorders in phyllotaxis patterns, we revisited in depth the classical deterministic view of phyllotaxis. We developed a stochastic model of primordia initiation at the shoot apex, integrating locality and stochasticity in the patterning system. This stochastic model recapitulates phyllotactic patterns, both regular and irregular, and makes quantitative predictions on the nature of disorders arising from noise. We further show that disorders in phyllotaxis instruct us on the parameters governing phyllotaxis dynamics, thus that disorders can reveal biological watermarks of developmental systems.
