Abstract

Developmental fate decisions in cell populations fundamentally depend on at least two parameters: a signal that is perceived by the cell and the intrinsic ability of the cell to respond to the signal. The same regulatory logic holds for phase transitions in the life cycle of an organism, for example the switch to reproductive development in flowering plants. Here we have tested the response of the monocarpic plant species Arabidopsis thaliana to a signal that directs flower formation, the plant-specific transcription factor LEAFY (LFY). Using transient steroid-dependent LEAFY (LFY) activation in lfy null mutant Arabidopsis plants, we show that the plant’s competence to respond to the LFY signal changes during development. Very early in the life cycle, the plant is not competent to respond to the signal. Subsequently, transient LFY activation can direct primordia at the flanks of the shoot apical meristem to adopt a floral fate. Finally, the plants acquire competence to initiate the flower-patterning program in response to transient LFY activation. Similar to a perennial life strategy, we did not observe reprogramming of all primordia after perception of the transient signal, instead only a small number of meristems responded, followed by reversion to the prior developmental program. The ability to initiate flower formation and to direct flower patterning in response to transient LFY upregulation was dependent on the known direct LFY target APETALA1 (AP1). Prolonged LFY or activation could alter the developmental gradient and bypass the requirement for AP1. Prolonged high AP1 levels, in turn, can also alter the plants’ competence. Our findings shed light on how plants can fine-tune important phase transitions and developmental responses.

Highlights

  • The entire above ground body of higher plants is generated postembryonically by a group of stem cells located in the shoot apical meristem (Steeves and Sussex, 1989)

  • During the Arabidopsis life cycle, different types of lateral organs are produced by these primordia (Steeves and Sussex, 1989; Poethig, 2003; Albani and Coupland, 2010)

  • It is known that pre-existing primordia can be reprogrammed to adopt floral fate (Hempel and Feldman, 1995)

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Summary

Introduction

The entire above ground body of higher plants is generated postembryonically by a group of stem cells located in the shoot apical meristem (Steeves and Sussex, 1989). Lateral organs arise from primordia that form in the organogenic region at the periphery of the shoot apical meristem (Ha et al, 2010). During the Arabidopsis life cycle, different types of lateral organs are produced by these primordia (Steeves and Sussex, 1989; Poethig, 2003; Albani and Coupland, 2010). The primordia give rise to cauline leaves subtending secondary inflorescence branches. Both axillary and secondary inflorescences repeat the body plan of the central shoot or primary inflorescence

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