Abstract

Light exposure results in distinct responses in specific seedling tissues during photomorphogenesis. Light promotes growth of cotyledons and leaves, as well as development and elongation of roots, whereas light inhibits elongation of hypocotyls. For distinct plant responses such as shade avoidance, far-red light or shifts in spectral light quality similarly have disparate impacts on distinct plant tissues, resulting in elongation of stems or petioles and a reduction in growth of leaf blades for many species. The physiological bases of such tissue- and organ-specific light responses were initially studied using localized irradiation of specific tissues and organs, or irradiation of dissected plant parts. These historical approaches were used to identify spatial-specific pools of photoreceptors responsible for regulating local, i.e., tissue- or organ-specific, or distal, i.e., interorgan, plant responses. The red/far-red responsive phytochromes have been the most widely studied among photoreceptors in this regard. Whereas, the spatial localization of photoreceptors regulating many tissue- or organ-specific light responses were identified, the underlying signaling networks responsible for mediating the observed responses have not been well defined. Recent approaches used to investigate the molecular bases of spatiotemporal light responses include selective irradiation of plants harboring mutations in specific photoreceptors, tissue-specific expression of photoreceptors, primarily in photoreceptor mutant backgrounds, or tissue-specific biochemical ablation of photoreceptor accumulation. Progressive integration of such approaches for regulating the availability of localized pools of phytochromes with the use of transcriptomic or proteomic analyses for assessing the genes or proteins which these spatially discrete pools of phytochrome regulate is yielding emergent insight into the molecular bases of spatiotemporal phytochrome signaling pathways responsible for regulating spatiotemporal light responses of which we have been aware of at the physiological level for decades. Here, I discuss historical and emerging approaches to elucidating spatiotemporal signaling mediated by phytochromes during photomorphogenesis.

Highlights

  • Plants exhibit developmental plasticity or an adaptive ability to alter growth and development in response to external cues

  • Light inhibits growth in the hypocotyl, but promotes growth and development in cotyledons and emerging true leaves, as well as in roots (Figure 1). Such divergent responses in distinct tissues could be maintained through having distinct pools of photoreceptors regulating the promotion of growth in cotyledons or roots, and distinct photoreceptors inhibiting hypocotyl elongation

  • Some very early studies investigating tissue-specific light responses were conducted with isolated plant parts such as fruits

Read more

Summary

INTRODUCTION

Plants exhibit developmental plasticity or an adaptive ability to alter growth and development in response to external cues. Phytochromes and cryptochromes, which have critical roles in photomorphogenesis, accumulate at different levels and patterns in distinct tissues and due to developmental cues (Adam et al, 1994; Somers and Quail, 1995a,b; Goosey et al, 1997; Nagatani, 1997; Tóth et al, 2001; Sharrock and Clack, 2002). These photoreceptors exhibit significant overlap in their patterns of expression, which do not fully support a role for spatially distinct photoreceptors in the control of divergent lightdependent growth responses in different tissues (Tóth et al, 2001). I focus primarily on investigations into the roles of phytochromes in spatiotemporal light responses in plants

Microbeam Irradiation
Tissue Dissection and Irradiation

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.