Vanessa Wahl scite author profile

The timing of the induction of flowering determines to a large extent the reproductive success of plants. Plants integrate diverse environmental and endogenous signals to ensure the timely transition from vegetative growth to flowering. Carbohydrates are thought to play a crucial role in the regulation of flowering, and trehalose-6-phosphate (T6P) has been suggested to function as a proxy for carbohydrate status in plants. The loss of TREHALOSE-6-PHOSPHATE SYNTHASE 1 (TPS1) causes Arabidopsis thaliana to flower extremely late, even under otherwise inductive environmental conditions. This suggests that TPS1 is required for the timely initiation of flowering. We show that the T6P pathway affects flowering both in the leaves and at the shoot meristem, and integrate TPS1 into the existing genetic framework of flowering-time control.

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Trehalose-6-Phosphate: Connecting Plant Metabolism and Development

Ponnu¹,

Wahl²,

Schmid³

2011

Front. Plant Sci.

209

143

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Beyond their metabolic roles, sugars can also act as messengers in signal transduction. Trehalose, a sugar found in many species of plants and animals, is a non-reducing disaccharide composed of two glucose moieties. Its synthesis in plants is a two-step process, involving the production of trehalose-6-phosphate (T6P) catalyzed by trehalose-6-phosphate synthase (TPS) and its consecutive dephosphorylation to trehalose, catalyzed by trehalose-6-phosphate phosphatase (TPP). T6P has recently emerged as an important signaling metabolite, regulating carbon assimilation and sugar status in plants. In addition, T6P has also been demonstrated to play an essential role in plant development. This review recapitulates the recent advances we have made in understanding the role of T6P in coordinating diverse metabolic and developmental processes.

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Synchronization of developmental, molecular and metabolic aspects of source–sink interactions

et al. 2020

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Repeated Evolutionary Changes of Leaf Morphology Caused by Mutations to a Homeobox Gene

et al. 2014

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Elucidating the genetic basis of morphological changes in evolution remains a major challenge in biology. Repeated independent trait changes are of particular interest because they can indicate adaptation in different lineages or genetic and developmental constraints on generating morphological variation. In animals, changes to "hot spot" genes with minimal pleiotropy and large phenotypic effects underlie many cases of repeated morphological transitions. By contrast, only few such genes have been identified from plants, limiting cross-kingdom comparisons of the principles of morphological evolution. Here, we demonstrate that the REDUCED COMPLEXITY (RCO) locus underlies more than one naturally evolved change in leaf shape in the Brassicaceae. We show that the difference in leaf margin dissection between the sister species Capsella rubella and Capsella grandiflora is caused by cis-regulatory variation in the homeobox gene RCO-A, which alters its activity in the developing lobes of the leaf. Population genetic analyses in the ancestral C. grandiflora indicate that the more-active C. rubella haplotype is derived from a now rare or lost C. grandiflora haplotype via additional mutations. In Arabidopsis thaliana, the deletion of the RCO-A and RCO-B genes has contributed to its evolutionarily derived smooth leaf margin, suggesting the RCO locus as a candidate for an evolutionary hot spot. We also find that temperature-responsive expression of RCO-A can explain the phenotypic plasticity of leaf shape to ambient temperature in Capsella, suggesting a molecular basis for the well-known negative correlation between temperature and leaf margin dissection.

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Nitrate acts at the Arabidopsis thaliana shoot apical meristem to regulate flowering time

et al. 2019

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Summary Optimal timing of flowering, a major determinant for crop productivity, is controlled by environmental and endogenous cues. Nutrients are known to modify flowering time; however, our understanding of how nutrients interact with the known pathways, especially at the shoot apical meristem ( SAM ), is still incomplete. Given the negative side‐effects of nitrogen fertilization, it is essential to understand its mode of action for sustainable crop production. We investigated how a moderate restriction by nitrate is integrated into the flowering network at the SAM , to which plants can adapt without stress symptoms. This condition delays flowering by decreasing expression of SUPRESSOR OF OVEREXPRESSION OF CONSTANS 1 ( SOC 1 ) at the SAM . Measurements of nitrate and the responses of nitrate‐responsive genes suggest that nitrate functions as a signal at the SAM . The transcription factors NIN ‐ LIKE PROTEIN 7 ( NLP 7) and NLP 6, which act as master regulators of nitrate signaling by binding to nitrate‐responsive elements ( NRE s), are expressed at the SAM and flowering is delayed in single and double mutants. Two upstream regulators of SOC 1 ( SQUAMOSA PROMOTER BINDING PROTEIN ‐ LIKE 3 ( SPL 3 ) and SPL 5 ) contain functional NRE s in their promoters. Our results point at a tissue‐specific, nitrate‐mediated flowering time control in Arabidopsis thaliana .

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Vanessa Wahl

Regulation of Flowering by Trehalose-6-Phosphate Signaling in Arabidopsis thaliana

Trehalose-6-Phosphate: Connecting Plant Metabolism and Development

Synchronization of developmental, molecular and metabolic aspects of source–sink interactions

Repeated Evolutionary Changes of Leaf Morphology Caused by Mutations to a Homeobox Gene

Nitrate acts at the Arabidopsis thaliana shoot apical meristem to regulate flowering time

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