Single-cell approaches for understanding morphogenesis using Computational Morphodynamics

In multicellular organisms cells grow, divide and adopt different fates, resulting in tissues and organs with specific functions. In recent years, a number of studies have brought quantitative knowledge about how these processes are orchestrated, shed-ding new light on cells as active and central players in morphogenesis. We explore recent advances in understanding plant morphogenesis from a quantitative perspective, defining the re-search field of Computational Morphodynamics. The focus is on studies combining theoretical and experimental approaches integrating hypotheses of how molecular and mechanical regulation at the cellular level lead to tissue behaviour. Finally, we dis-cuss some of the main challenges for future work

Computational morphodynamics of plants: integrating development over space and time

The emerging field of computational morphodynamics aims to understand the changes that occur in space and time during development by combining three technical strategies: live imaging to observe development as it happens; image processing and analysis to extract quantitative information; and computational modelling to express and test time-dependent hypotheses. The strength of the field comes from the iterative and combined use of these techniques, which has provided important insights into plant development

Cellular basis of flower and leaf primordium initiation in Arabidopsis thaliana : how to make an organ in three dimensions

Le développement d’un organisme multicellulaire requière la coordination de la croissance, détermination tissulaire et différenciation cellulaire. Cependant, alors que les bases de la génétique de la morphogenèse ont été rigoureusement étudiées, le processus permettant la conversion de l’activité génétique en des structures biologiques complexes est bien moins compris. Chez Arabidopsis thaliana, les feuilles et fleurs initiés à partir du Méristème Apical Primaire (MAP) ont une expression génétique casi similaire. Toutefois, leur forme est considérablement différente dès les premières étapes de leur développement. Une compréhension de ce paradoxe requière avant tout de précisément quantifier la croissance dans toutes les dimensions de ces organes. Dans cet article, je présente une méthode de quantification spatio-temporelle complète de la croissance et de la prolifération des feuilles et des fleurs chez A. thaliana. En analysant des séries d’images confocales, j’en ai conclu que la différence morphologique observée entre feuilles et fleurs émerge principalement d’une asymétrie de la distribution de la croissance entre leurs côtés abaxial et adaxial, tôt dans leur développement. Je montre que le tissue contribuant principalement au développement des primordia est la couche 2 (L2) chez les feuilles et la couche 3 (L3) chez les fleurs. Mes résultats préliminaires démontrent que les premiers signes de l’initiation d’organes est un changement de distribution de la croissance, et non de la prolifération. Dans le futur, en appliquant, par exemple, cette méthodologie à l’étude de gènes de développement, il sera possible de finalement réconcilier la morphogenèse et la génétique de l’initiation des plantes.The development of a multicellular organism requires the proper coordination of growth, pattern determination and cell differentiation. Still, while the genetic basis of morphogenesis has been extensively studied, the process converting gene activity into intricate biological shapes is less understood. In Arabidopsis thaliana, flowers and leaves, both initiated from the shoot apical meristem (SAM), have a very similar genetic expression profile. Yet, their shape differs considerably from early developmental stages. A full comprehension of this paradox requires an accurate quantification of cellular growth in those organs. In this paper, I am presenting a methodology for the complete spatio-temporal quantitative analysis of growth and proliferation of initiating leaves and flowers in wild type Arabidopsis thaliana. By analyzing time series of leaf and flower confocal images, I conclude that the morphological differences observed between flowers and leaves mainly arises from asymmetrical distributions of growth between their adaxial and abaxial sides during their initiation. I show that the tissue that mainly contributes to the development of early primordium is the layer 2 (L2) in leaves, and the layer 3 (L3) in flowers. My preliminary results also demonstrate that the first signs of organ initiation are a change in growth distribution, not cell proliferation. In the future, by applying this methodology, for example, to study morphogen reporter lines, it could finally bridge the gap between the morphogenesis and the genetics of plant initiation

Models of Mechanics and Growth in Developmental Biology: A Computational Morphodinamics approach

Recent evidence has revealed the role of mechanical cues in the development of shapes in organisms. This thesis is an effort to test some of the fundamental hypotheses about the relation between mechanics and patterning in plants. To do this, we develop mechanical models designed to include specific features of plant cell walls. These are heterogeneous stiffness and material anisotropy as well as rates and directions of growth, which we then relate to different domains of the plant tissue.In plant cell walls, anisotropic fiber deposition is the main controller of longitudinal growth. In our model, this is achieved spontaneously, by applying feedback from the maximal stress direction to the fiber orientation. We show that a stress feedback model is in fact an energy minimization process. This can be considered as an evolutionary motivation for the emergence of a stress feedback mechanism. Then we add continuous growth and cell division to the model and employ the strain signal directing large growth deformations. We show the advantages of strain-based growth model for emergence of plant-like organ shapes as well as for reproducing microtubular dynamics in hypocotyls and roots. We also investigate possibilities for describing microtubular patterns, at root hair outgrowth sites according to stress patterns. Altogether, the work described in this thesis, provides a new improved growth model for plant tissue, where mechanical properties are handled with appropriate care in the event of growth driven by either molecular or mechanical signals. The model unifies the patterning process for several different plant tissues, from shoot to single root hair cells, where it correctly predict microtubular dynamics and growth patterns. In a long-term perspective, this understanding can propagate to novel technologies for improvement of yield in agriculture and the forest industry

Shifting foundations: the mechanical cell wall and development.

The cell wall has long been acknowledged as an important physical mediator of growth in plants. Recent experimental and modelling work has brought the importance of cell wall mechanics into the forefront again. These data have challenged existing dogmas that relate cell wall structure to cell/organ growth, that uncouple elasticity from extensibility, and those which treat the cell wall as a passive and non-stressed material. Within this review we describe experiments and models which have changed the ways in which we view the mechanical cell wall, leading to new hypotheses and research avenues. It has become increasingly apparent that while we often wish to simplify our systems, we now require more complex multi-scale experiments and models in order to gain further insight into growth mechanics. We are currently experiencing an exciting and challenging shift in the foundations of our understanding of cell wall mechanics in growth and development.Work in the authors’ groups is funded by The Gatsby Charitable Foundation (GAT3396/PR4, SB; GAT3395/PR4, HJ), the Swedish Research Council (VR2013‐4632, HJ), the Knut and Alice Wallenberg Foundation via ShapeSystems (HJ), and the BBSRC (BB.L002884.1, SB).This is the final version of the article. It first appeared from Elsevier via https://doi.org/10.1016/j.pbi.2015.12.00

Sculpting the surface: Structural patterning of plant epidermis.

Plant epidermis are multifunctional surfaces that directly affect how plants interact with animals or microorganisms and influence their ability to harvest or protect from abiotic factors. To do this, plants rely on minuscule structures that confer remarkable properties to their outer layer. These microscopic features emerge from the hierarchical organization of epidermal cells with various shapes and dimensions combined with different elaborations of the cuticle, a protective film that covers plant surfaces. Understanding the properties and functions of those tridimensional elements as well as disentangling the mechanisms that control their formation and spatial distribution warrant a multidisciplinary approach. Here we show how interdisciplinary efforts of coupling modern tools of experimental biology, physics, and chemistry with advanced computational modeling and state-of-the art microscopy are yielding broad new insights into the seemingly arcane patterning processes that sculpt the outer layer of plants