Stochasticity in plant developmental processes

Editors

Karen Alim

Max-Planck-Institute for Dynamics and Self-Organisation, Max Planck Society

Naomi Nakayama

University of Edinburgh

Impact

The non-linear least-square fitting of the distribution of eudicot floral organ numbers. Each of the six models (see the legend for color definition) is plotted in (A,B) whereas only the specified distributions are plotted in the other panels. In each panel, upper and bottom graph are linear and semi-log plot, respectively. ΔAICc values are shown in Table S4. (A) Anemone flaccida tepals. (B) Eranthis pinnatifida nectaries. (C) Ranunculus ficaria petals (Ludwig, 1901), fit best by the modified ERF distribution based on the ΔAICc, although the right tail follows the log-normal distribution. (D) Ranunculus bulbosus petals (de Vries, 1894), originally fit by the modified beta distribution by Pearson (1895), but better fit by the Poisson distribution. (E) Sanguinaria canadensis petals (Spencer, 1944), fit best by the modified ERF distribution. (F) Microseris pygmaea × Microseris bigelovii pappus parts (Bachmann and Chambers, 1978), best fit by the Poisson distribution. (G) Microseris pygmaea pappus parts (Bachmann and Chambers, 1978), best fit by the modified ERF and fit not as well by the Poisson distribution. (H) Nyctanthes arbor-tristis petals (Roy, 1963), fit best by the standard Gaussian distribution. (I) Sanguinaria canadensis ovules (Harris, 1910), fit well by the log-normal and gamma distributions. (J) Hibiscus syricacus seeds (Harris, 1911), best-fit by the modified beta distribution. (K) Leucanthemum vulgare ray florets (Ludwig, 1895), representing an example of a bimodal distribution fit by the beta distribution.

Original Research

03 November 2014

A developmental basis for stochasticity in floral organ numbers

Miho S. Kitazawa

and

Koichi Fujimoto

6,765 views

22 citations

Effect of intrinsic noise on oscillation robustness in Ostreococcus tauri in entrained and constant conditions. (A) 12 h:12 h light/dark (LD) cycles. (B) Constant light (LL). For each light condition, three independent realizations of the system’s dynamics obtained using the stochastic simulation algorithm (SSA) are shown, together with the deterministic behavior (dotted pink lines) and the mean stochastic behavior obtained by averaging over 10000 independent runs (dotted black lines). Note how the greater variability between the independent runs observed in LL compared to LD causes the mean population behavior to exhibit damped oscillations in LL (B) and sustained oscillations in LD (A). Interestingly, some individual cells can drift out of phase even in LD; however, the light entrainment is able to limit these occurrences so that, as a population, the cells oscillate regularly.

Perspective

21 October 2014

Stochastic models of cellular circadian rhythms in plants help to understand the impact of noise on robustness and clock structure

Maria L. Guerriero

, 1 more and

Gerben van Ooijen

8,122 views

16 citations

Stochastic rule for the selection of a division plane. (A,B) Two glandular trichomes showing the quadrant cells studied by Berthold and Thompson. Each circular gland divides twice across its center to produce four quadrant cells. These quadrant cells can undergo three types of division, all of which are predicted by soap films (C–E). The division plane with least area is anticlinal, forming a wedge cell and a triangular cell (D,E). The other division is periclinal (C) and corresponds to a local minimum of surface area or surface energy in the case of soap bubbles (F). (G) The proportion of cells adopting the optimal division plane i as a function of the relative area difference, δij, in its favor. The solid line is the best fit of the experimental data with a probability function of the form (1 + exp(-βδij))−1. Values of β computed for individual species are also reported (inset) (modified from Besson and Dumais, 2011).

Opinion

09 October 2014

Stochasticity in the symmetric division of plant cells: when the exceptions are the rule

Sébastien Besson

and

Jacques Dumais

4,691 views

25 citations

Review

08 September 2014

Stochasticity in plant cellular growth and patterning

Heather M. Meyer

and

Adrienne H. K. Roeder

Plants, along with other multicellular organisms, have evolved specialized regulatory mechanisms to achieve proper tissue growth and morphogenesis. During development, growing tissues generate specialized cell types and complex patterns necessary for establishing the function of the organ. Tissue growth is a tightly regulated process that yields highly reproducible outcomes. Nevertheless, the underlying cellular and molecular behaviors are often stochastic. Thus, how does stochasticity, together with strict genetic regulation, give rise to reproducible tissue development? This review draws examples from plants as well as other systems to explore stochasticity in plant cell division, growth, and patterning. We conclude that stochasticity is often needed to create small differences between identical cells, which are amplified and stabilized by genetic and mechanical feedback loops to begin cell differentiation. These first few differentiating cells initiate traditional patterning mechanisms to ensure regular development.

8,941 views

55 citations

Open for submission