A core mechanism for specifying root vascular patterning can replicate the anatomical variation seen in diverse plant species.

Nathan Mellor,Britta M C Kümpers,Shunsuke Miyashima,Ana Campilho,John R King,Anthony Bishopp,Hanna Help-Rinta-Rahko,Ari Pekka Mähönen,John Vaughan-Hirsch

doi:10.1242/dev.172411

Abstract

ABSTRACTPattern formation is typically controlled through the interaction between molecular signals within a given tissue. During early embryonic development, roots of the model plant Arabidopsis thaliana have a radially symmetric pattern, but a heterogeneous input of the hormone auxin from the two cotyledons forces the vascular cylinder to develop a diarch pattern with two xylem poles. Molecular analyses and mathematical approaches have uncovered the regulatory circuit that propagates this initial auxin signal into a stable cellular pattern. The diarch pattern seen in Arabidopsis is relatively uncommon among flowering plants, with most species having between three and eight xylem poles. Here, we have used multiscale mathematical modelling to demonstrate that this regulatory module does not require a heterogeneous auxin input to specify the vascular pattern. Instead, the pattern can emerge dynamically, with its final form dependent upon spatial constraints and growth. The predictions of our simulations compare to experimental observations of xylem pole number across a range of species, as well as in transgenic systems in Arabidopsis in which we manipulate the size of the vascular cylinder. By considering the spatial constraints, our model is able to explain much of the diversity seen in different flowering plant species.

Highlights

Patterning of organs involves the organization of cell fates within a tissue in space and time
Our results are consistent with recently published work suggesting that, in Arabidopsis, the cotyledons are used as a mechanism to determine the initial embryonic pattern; we propose that vascular patterning can be set or re-established as an emergent property of the interaction between auxin and cytokinin
The model is that of Arabidopsis: the number of xylem poles is specified through a heterogeneous input of auxin from the cotyledons

Summary

Introduction

Patterning of organs involves the organization of cell fates within a tissue in space and time. In many processes, ranging from floral morphogenesis in plants Roots represent an excellent choice of organ with which to study cellular patterning in plants because, when compared with other plant organs, the structures are both relatively simple and amenable to analysis via a range of microscopy techniques. The stele (or vascular cylinder) forms the central part of the root and is surrounded by outer layers, including the endodermis, cortex and epidermis. Cell identity is established already in the first daughter cells above the quiescent centre, and cell type-specific marker lines are expressed here, including markers such as TMO5 and AHP6, which define the xylem cell lineages (Schlereth et al, 2010; Mähönen et al, 2006a)

Methods

Results

Conclusion