Neighbor detection at the leaf tip adaptively regulates upward leaf movement through spatial auxin dynamics

Publication date

2017-06-26

Authors

Pantazopoulou, C.ORCID 0000-0001-5412-6029ISNI 0000000492917325
Bongers, F.J.ISNI 0000000419577520
Küpers, J.J.ISNI 0000000492528290
Reinen, E.ISNI 0000000388440600
Das, D.ISNI 0000000518036623
Evers, J.B.
Anten, N.P.R.
Pierik, RonaldISNI 0000000394604341

Editors

Advisors

Supervisors

Document Type

Article

License

Abstract

Vegetation stands have a heterogeneous distribution of light quality, including the red/far-red light ratio (R/FR) that informs plants about proximity of neighbors. Adequate responses to changes in R/FR are important for competitive success. How the detection and response to R/FR are spatially linked and how this spatial coordination between detection and response affects plant performance remains unresolved. We show in Arabidopsis thaliana and Brassica nigra that localized FR enrichment at the lamina tip induces upward leaf movement (hyponasty) from the petiole base. Using a combination of organ-level transcriptome analysis, molecular reporters, and physiology, we show that PIF-dependent spatial auxin dynamics are key to this remote response to localized FR enrichment. Using computational 3D modeling, we show that remote signaling of R/FR for hyponasty has an adaptive advantage over local signaling in the petiole, because it optimizes the timing of leaf movement in response to neighbors and prevents hyponasty caused by self-shading.

Keywords

leaf movement, auxin, phytochrome, functional-structural plant model, shade avoidance

Citation

Pantazopoulou, C, Bongers, F J, Küpers, J J, Reinen, E, Das, D, Evers, J B, Anten, N P R & Pierik, R 2017, 'Neighbor detection at the leaf tip adaptively regulates upward leaf movement through spatial auxin dynamics', Proceedings of the National Academy of Sciences of the United States of America, vol. 114, no. 28, pp. 7450–7455. https://doi.org/10.1073/pnas.1702275114