Cell-Based Model of the Generation and Maintenance of the Shape and Structure of the Multilayered Shoot Apical Meristem of Arabidopsis thaliana

Banwarth-Kuhn, Mikahl; Nematbakhsh, Ali; Rodriguez, Kevin; Snipes, Stephen; Rasmussen, Carolyn G.; Reddy, G. Venugopala; Alber, Mark

doi:10.1007/s11538-018-00547-z

Cited by 12 publications

(33 citation statements)

References 94 publications

(186 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…(2005); see also Banwarth-Kuhn et al. (2018) in this issue] to the biomechanics. A similar mechanical/regulatory model with breakable springs for the stem cell niche of mouse olfactory receptor neurons was implemented in the Plenum prototype implementation of the dynamical grammars declarative modeling language (Yosiphon 2009).…”

Section: Declarative Modelingmentioning

confidence: 95%

Prospects for Declarative Mathematical Modeling of Complex Biological Systems

Mjolsness

2019

Bull Math Biol

View full text Add to dashboard Cite

Declarative modeling uses symbolic expressions to represent models. With such expressions, one can formalize high-level mathematical computations on models that would be difficult or impossible to perform directly on a lower-level simulation program, in a general-purpose programming language. Examples of such computations on models include model analysis, relatively general-purpose model reduction maps, and the initial phases of model implementation, all of which should preserve or approximate the mathematical semantics of a complex biological model. The potential advantages are particularly relevant in the case of developmental modeling, wherein complex spatial structures exhibit dynamics at molecular, cellular, and organogenic levels to relate genotype to multicellular phenotype. Multiscale modeling can benefit from both the expressive power of declarative modeling languages and the application of model reduction methods to link models across scale. Based on previous work, here we define declarative modeling of complex biological systems by defining the operator algebra semantics of an increasingly powerful series of declarative modeling languages including reaction-like dynamics of parameterized and extended objects; we define semantics-preserving implementation and semantics-approximating model reduction transformations; and we outline a “meta-hierarchy” for organizing declarative models and the mathematical methods that can fruitfully manipulate them. Electronic supplementary material The online version of this article (10.1007/s11538-019-00628-7) contains supplementary material, which is available to authorized users.

show abstract

Section: Declarative Modelingmentioning

confidence: 95%

Prospects for Declarative Mathematical Modeling of Complex Biological Systems

Mjolsness

2019

Bull Math Biol

View full text Add to dashboard Cite

show abstract

“…The study combining experimental data on the organization of the extracellular matrix and numerical simulations demonstrated that auxin plays an essential role in altering cells' mechanical properties; this process involves the ABP1 and KATANIN 1 proteins (Sassi et al, 2014). Also, the advanced cell-based mathematical model describes the relationship between the concentration of morphogens and the cellular mechanistic properties in the developing apical shoot meristems (Banwarth-Kuhn et al, 2019).…”

Section: Existing Models and Modeling Approachesmentioning

confidence: 99%

“…Thus, the models of plant tissue morphogenesis put at the forefront three biological facts: (i) the dependence on intercellular hormonal signaling, (ii) the importance of the intracellular state and individual cellular characteristics, (iii) the relevance of mechanical stresses in intercellular interactions. Therefore, scRNA-seq technologies, microscopy, imaging techniques, and a range of complementary approaches to measuring cell mechanical properties (Banwarth-Kuhn et al, 2019;Bidhendi and Geitmann, 2019) can provide a complete picture of morphogenetic processes at the cellular level.…”

Section: Existing Models and Modeling Approachesmentioning

confidence: 99%

“…In center-based models, cells are represented as dots with mass, connected by mechanical elements (springs). Banwarth-Kuhn et al (2019) give an example of this formalism's application to the description of growth processes in the shoot apical meristem. Cellular Potts models are often used to describe the processes occurring in animal tissues and tumor formation processes; this formalism is implemented in CompuCell3D (Swat et al, 2012).…”

Section: Available Software and Tools For Cell-based Modelingmentioning

confidence: 99%

See 1 more Smart Citation

A Sight on Single-Cell Transcriptomics in Plants Through the Prism of Cell-Based Computational Modeling Approaches: Benefits and Challenges for Data Analysis

et al. 2021

View full text Add to dashboard Cite

Single-cell technology is a relatively new and promising way to obtain high-resolution transcriptomic data mostly used for animals during the last decade. However, several scientific groups developed and applied the protocols for some plant tissues. Together with deeply-developed cell-resolution imaging techniques, this achievement opens up new horizons for studying the complex mechanisms of plant tissue architecture formation. While the opportunities for integrating data from transcriptomic to morphogenetic levels in a unified system still present several difficulties, plant tissues have some additional peculiarities. One of the plants’ features is that cell-to-cell communication topology through plasmodesmata forms during tissue growth and morphogenesis and results in mutual regulation of expression between neighboring cells affecting internal processes and cell domain development. Undoubtedly, we must take this fact into account when analyzing single-cell transcriptomic data. Cell-based computational modeling approaches successfully used in plant morphogenesis studies promise to be an efficient way to summarize such novel multiscale data. The inverse problem’s solutions for these models computed on the real tissue templates can shed light on the restoration of individual cells’ spatial localization in the initial plant organ—one of the most ambiguous and challenging stages in single-cell transcriptomic data analysis. This review summarizes new opportunities for advanced plant morphogenesis models, which become possible thanks to single-cell transcriptome data. Besides, we show the prospects of microscopy and cell-resolution imaging techniques to solve several spatial problems in single-cell transcriptomic data analysis and enhance the hybrid modeling framework opportunities.

show abstract

“…A way to bring together these two aspects is to formulate a multi-scale approach, combining several levels of description and allowing them to interact. Several propositions exist and among them, gene-regulated network combined to growth [4,31,58,71,27], averaging approaches through analytical homogenisation [1,35,65,79,82], and the incorporation of a representation of individual cells in a continuous formulation of tissue deformation [5,13,42,48,53,99].…”

Section: Eect Of Dierential Growthmentioning

confidence: 99%

Smoothed particle hydrodynamics for root growth mechanics

Mimault

Ptashnyk

Bassel

et al. 2019

Engineering Analysis with Boundary Elements

View full text Add to dashboard Cite

A major challenge of plant developmental biology is to understand how cells grow during the formation of an organ. To date, it has proved dicult to develop computational models of entire organs at cellular resolution and, as a result, the testing of hypotheses on the biophysics of self-organisation is currently limited. Here, we formulate a model for plant tissue growth in an SPH framework. The framework identies the SPH particle with individual cells in a tissue, but the tissue growth is performed at the macroscopic level using SPH approximations. Plant tissue is represented as an anisotropic poro-elastic material where turgor pressure deforms the cell walls and biosynthesis and cell division control the density of the tissue. The performance of the model is evaluated through a series of tests and benchmarks. Results demonstrate good stability and convergence of simulations as well as readiness of the technique for more complex biological problems.

show abstract

Cell-Based Model of the Generation and Maintenance of the Shape and Structure of the Multilayered Shoot Apical Meristem of Arabidopsis thaliana

Cited by 12 publications

References 94 publications

Prospects for Declarative Mathematical Modeling of Complex Biological Systems

Prospects for Declarative Mathematical Modeling of Complex Biological Systems

A Sight on Single-Cell Transcriptomics in Plants Through the Prism of Cell-Based Computational Modeling Approaches: Benefits and Challenges for Data Analysis

Smoothed particle hydrodynamics for root growth mechanics

Contact Info

Product

Resources

About