Mechanical constraints imposed by 3D cellular geometry and arrangement modulate growth patterns in the Arabidopsis embryo

George W. Bassel; Petra Stamm; Gabriella Mosca; Pierre Barbier de Reuille; Daniel J. Gibbs; Robin Winter; Ales Janka; Michael J. Holdsworth; Richard S. Smith

doi:10.1073/pnas.1404616111

Edited by Philip N. Benfey, Duke University, Durham, NC, and approved May 6, 2014 (received for review March 28, 2014)

Significance

During plant growth and development, the gene expression that promotes growth does not always spatially correlate with observed growth. This suggests that additional factors guide morphogenesis. Here we propose that mechanical cues play an instructive role and test our hypothesis by using a full 3D cellular-level finite-element simulation model of the mature Arabidopsis embryo. We demonstrate that the size, shape, and arrangement of plant cells all influence their ability to grow in response to growth-promoting gene expression. These principles were sufficient to explain the displacement of growth from the center of growth-promoting gene expression. These findings represent a previously undescribed mechanism governing 3D growth patterns in multicellular plant organs.

Abstract

Morphogenesis occurs in 3D space over time and is guided by coordinated gene expression programs. Here we use postembryonic development in Arabidopsis plants to investigate the genetic control of growth. We demonstrate that gene expression driving the production of the growth-stimulating hormone gibberellic acid and downstream growth factors is first induced within the radicle tip of the embryo. The center of cell expansion is, however, spatially displaced from the center of gene expression. Because the rapidly growing cells have very different geometry from that of those at the tip, we hypothesized that mechanical factors may contribute to this growth displacement. To this end we developed 3D finite-element method models of growing custom-designed digital embryos at cellular resolution. We used this framework to conceptualize how cell size, shape, and topology influence tissue growth and to explore the interplay of geometrical and genetic inputs into growth distribution. Our simulations showed that mechanical constraints are sufficient to explain the disconnect between the experimentally observed spatiotemporal patterns of gene expression and early postembryonic growth. The center of cell expansion is the position where genetic and mechanical facilitators of growth converge. We have thus uncovered a mechanism whereby 3D cellular geometry helps direct where genetically specified growth takes place.

Footnotes

↵¹To whom correspondence may be addressed. E-mail: g.w.bassel{at}bham.ac.uk or smith{at}mpipz.mpg.de.

Author contributions: G.W.B. and R.S.S. designed research; G.W.B., P.S., D.J.G., and R.S.S. performed research; G.W.B., G.M., P.B.d.R., R.W., A.J., and R.S.S. contributed new reagents/analytic tools; G.W.B., M.J.H., and R.S.S. analyzed data; and G.W.B. and R.S.S. wrote the paper.
The authors declare no conflict of interest.
This article is a PNAS Direct Submission.
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