Rachel E. Taylor scite author profile

Plants perceive and integrate information from the environment to time critical transitions in their life cycle. Some mechanisms underlying this quantitative signal processing have been described, whereas others await discovery. Seeds have evolved a mechanism to integrate environmental information by regulating the abundance of the antagonistically acting hormones abscisic acid (ABA) and gibberellin (GA). Here, we show that hormone metabolic interactions and their feedbacks are sufficient to create a bistable developmental fate switch in Arabidopsis seeds. A digital single-cell atlas mapping the distribution of hormone metabolic and response components revealed their enrichment within the embryonic radicle, identifying the presence of a decision-making center within dormant seeds. The responses to both GA and ABA were found to occur within distinct cell types, suggesting cross-talk occurs at the level of hormone transport between these signaling centers. We describe theoretically, and demonstrate experimentally, that this spatial separation within the decision-making center is required to process variable temperature inputs from the environment to promote the breaking of dormancy. In contrast to other noise-filtering systems, including human neurons, the functional role of this spatial embedding is to leverage variability in temperature to transduce a fate-switching signal within this biological system. Fluctuating inputs therefore act as an instructive signal for seeds, enhancing the accuracy with which plants are established in ecosystems, and distributed computation within the radicle underlies this signal integration mechanism.seed | dormancy | signal integration | distributed control | variability P lant development is guided by the perception of diverse environmental cues and their integration into key transitions (1). One major decision in the life cycle of plants is when to commence flowering (2, 3). The other major decision is when to initiate a new plant (4). This decision is achieved through seed dormancy, an adaptive trait that determines where and when plants are established, and the entry and exit of plants into and out of ecosystems (4). The germination of seeds also represents the starting point for the vast majority of world agriculture, having great industrial, economic, and societal significance (5). During seed development, dormancy level is established in response to the environment experienced by the mother plant (6). This control is achieved through the quantitative regulation of genetically encoded regulatory factors, including the DOG1 locus (7, 8), and hormone abundance and sensitivity (9, 10). Following their release from the mother plant, the control of dormancy in seeds was proposed to be mediated by the activity of antagonistically acting factors (11). Later work identified this endogenous signal integration mechanism to consist of the antagonistically acting hormone abscisic acid (ABA) promoting dormancy and gibberellin (GA) promoting germination (9, 12). The relative abundance of ...

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WHIRLY protein functions in plants

Taylor

West

Foyer

2022

Food and Energy Security

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Environmental stresses pose a significant threat to food security. Understanding the function of proteins that regulate plant responses to biotic and abiotic stresses is therefore pivotal in developing strategies for crop improvement. The WHIRLY (WHY) family of DNA‐binding proteins are important in this regard because they fulfil a portfolio of important functions in organelles and nuclei. The WHY1 and WHY2 proteins function as transcription factors in the nucleus regulating phytohormone synthesis and associated growth and stress responses, as well as fulfilling crucial roles in DNA and RNA metabolism in plastids and mitochondria. WHY1, WHY2 (and WHY3 proteins in Arabidopsis) maintain organelle genome stability and serve as auxiliary factors for homologous recombination and double‐strand break repair. Our understanding of WHY protein functions has greatly increased in recent years, as has our knowledge of the flexibility of their localization and overlap of functions but there is no review of the topic in the literature. Our aim in this review was therefore to provide a comprehensive overview of the topic, discussing WHY protein functions in nuclei and organelles and highlighting roles in plant development and stress responses. In particular, we consider areas of uncertainty such as the flexible localization of WHY proteins in terms of retrograde signalling connecting mitochondria, plastids, and the nucleus. Moreover, we identify WHY proteins as important targets in plant breeding programmes designed to increase stress tolerance and the sustainability of crop yield in a changing climate.

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WHIRLY proteins maintain seed longevity by effects on seed oxygen signalling during imbibition

Taylor

Waterworth

West

et al. 2023

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The WHIRLY (WHY) family of DNA/RNA binding proteins fulfill multiple but poorly characterized functions in plants. We analysed WHY protein functions in the Arabidopsis Atwhy1,Atwhy3, Atwhy1why3 single and double mutants and wild type controls. The Atwhy3 and Atwhy1why3 double mutants showed a significant delay in flowering, having more siliques per plant but with fewer seeds per silique than the wild type. While germination was similar in the un-aged high-quality seeds of all lines, significant decreases in vigour and viability were observed in the aged mutant seeds compared to the wild type. Imbibition of un-aged high-quality seeds was characterized by large increases in transcripts that encode proteins involved in oxygen sensing and responses to hypoxia. Seed ageing resulted in a disruption of the imbibition-induced transcriptome profile such that transcripts encoding RNA metabolism and processing became the most abundant components of the imbibition signature. The imbibition-related profile of the Atwhy1why3 mutant seeds, was characterised by decreased expression of hypoxia-related and oxygen metabolism genes even in the absence of ageing. Seed ageing further decreased the abundance of hypoxia-related and oxygen metabolism transcripts relative to the wildtype. These findings suggest that the WHY1 and WHY3 proteins regulate the imbibition-induced responses to oxygen availability and hypoxia. Loss of WHY1 and WHY3 functions decreases the ability of Arabidopsis seeds to resist the adverse effects of seed ageing.

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Responsibility for the Soul of the Child: The Role of the State and Parents in Determining Religious Upbringing and Education

Taylor¹

2020

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Necrosis and ethylene‐inducing‐like peptide patterns from crop pathogens induce differential responses within seven brassicaceous species

et al. 2022

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Translational research is required to advance fundamental knowledge on plant immunity towards application in crop improvement. Recognition of microbe/pathogenassociated molecular patterns (MAMPs/PAMPs) triggers a first layer of immunity in plants. The broadly occurring family of necrosis-and ethylene-inducing peptide 1 (NEP1)-like proteins (NLPs) contains immunogenic peptide patterns that are recognized by a number of plant species. Arabidopsis can recognize NLPs by the pattern recognition receptor AtRLP23 and its co-receptors SOBIR1, BAK1, and BKK1, leading to induction of defence responses including the production of reactive oxygen species (ROS) and elevation of intracellular [Ca 2+ ]. However, little is known about NLP perception in Brassica crop species. Within 12 diverse accessions for each of six Brassica crop species, we demonstrate variation in response to Botrytis cinerea NLP BcNEP2, with Brassica oleracea (CC genome) being nonresponsive and only two Brassica napus cultivars responding to BcNEP2. Peptides derived from four fungal pathogens of these crop species elicited responses similar to BcNEP2 in B. napus and Arabidopsis. Induction of ROS by NLP peptides was strongly reduced in Atrlp23, Atsobir1 and Atbak1-5 Atbkk1-1 mutants, confirming that recognition of Brassica pathogen NLPs occurs in a similar manner to that of HaNLP3 from Hyaloperonospora arabidopsidis in Arabidopsis. In silico analysis of the genomes of two B. napus accessions showed similar presence of homologues for AtBAK1, AtBKK1 and AtSOBIR1 but variation in the organization of AtRLP23 homologues. We could not detect a strong correlation between the ability to respond to NLP peptides and resistance to B. cinerea.

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Rachel E. Taylor

Temperature variability is integrated by a spatially embedded decision-making center to break dormancy in Arabidopsis seeds

WHIRLY protein functions in plants

WHIRLY proteins maintain seed longevity by effects on seed oxygen signalling during imbibition

Responsibility for the Soul of the Child: The Role of the State and Parents in Determining Religious Upbringing and Education

Necrosis and ethylene‐inducing‐like peptide patterns from crop pathogens induce differential responses within seven brassicaceous species

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