Modeling of root nitrate responses suggests preferential foraging arises from the integration of demand, supply and local presence signals

Boer, Meine D; Teixeira, Joana Santos; Tusscher, Kirsten H. ten

doi:10.1101/2019.12.19.882548

Cited by 3 publications

(3 citation statements)

References 51 publications

(98 reference statements)

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“…Localized nitrate patches result in an increase in lateral root elongation and density in Arabidopsis (Linkohr et al, 2002; Sun et al, 2017; Liu et al, 2020). Moderate, homogenous nitrate levels promote primary and lateral root growth while high homogenous nitrate levels suppress growth (Asim et al, 2020; Boer et al, 2020; Liu and von Wirén, 2022). Nitrate mediates these functions largely through its impacts on endogenous auxin pathways.…”

Section: Discussionmentioning

confidence: 99%

The NIN-LIKE PROTEIN 7 (NLP7) transcription factor modulates auxin pathways to regulate root cap development

Kumar

Caldwell

Iyer‐Pascuzzi

2022

Preprint

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The root cap surrounds the root tip and promotes root growth by protecting the root apical meristem, influencing root branching, and sensing environmental signals like nitrate. The root cap maintains a constant size through the coordination of cell production in the root meristem with cell release at the tip of the root, a process that requires an auxin minima in the last layer of the root cap. To perform its functions, the root cap must maintain a constant size and synchronize external cues with development, but mechanisms underlying such coordination are not well understood. Mutations in the NIN LIKE PROTEIN 7 (NLP7) transcription factor, a master regulator of nitrate signaling, lead to defects in root cap cell release and cell production. Nitrate impacts root development through crosstalk with auxin. Therefore, we hypothesized that NLP7 regulates root cap cell release and cell production by modulating auxin pathways. Here we show that mutations in NLP7 abolish the auxin minima required for root cap cell release and alter root cap expression levels of the auxin carriers PIN-LIKES 3 (PILS3) and PIN-FORMED 7 (PIN7). We find that NLP7 is required for proper root cap cell production and differentiation and for expression of transcription factors that regulate these processes. Nitrate deficiency impacts auxin pathways in the last layer of the root cap, and this is mediated in part by NLP7. Together, our data suggest that NLP7 integrates nitrate signaling with auxin pathways to optimize root cap development in response to external nitrate cues.

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Section: Discussionmentioning

confidence: 99%

The NIN-LIKE PROTEIN 7 (NLP7) transcription factor modulates auxin pathways to regulate root cap development

Kumar

Caldwell

Iyer‐Pascuzzi

2022

Preprint

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“…As an example, more lateral roots branch off where nutrient levels are higher, yet this response to local soil conditions depends both on how much the plant is in need of that nutrient and the extent to which other parts of the root system have failed to locate this nutrient. This integration of local, systemic and long range information depends on the status storage in the local plant organ as well as on the transport of systemic and long-distance signals through the vasculature (Boer et al, 2020; Guan, 2017). In contrast, the continuous moving and mixing of ants in an ant colony makes it impossible to store locational or directional information internally in groups of ants themselves.…”

Section: Facets Of Embodimentmentioning

confidence: 99%

Embodiment in distributed information processing: “Solid” plants versus “liquid” ant colonies

2022

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Information processing is an essential part of biology, enabling coordination of intra-organismal processes such as development, environmental adaptation and inter-organismal communication. Whilst in animals with specialised brain tissue a substantial amount of information processing occurs in a centralised manner, most biological computing is distributed across multiple entities, such as cells in a tissue, roots in a root system or ants in a colony. Physical context, called embodiment, also affects the nature of biological computing. While plants and ant colonies both perform distributed computing, in plants the units occupy fixed positions while individual ants move around. This distinction, solid versus liquid brain computing, shapes the nature of computations. Here we compare information processing in plants and ant colonies, highlighting how similarities and differences originate in, as well as make use of, the differences in embodiment. We end with a discussion on how this embodiment perspective may inform the debate on plant cognition.

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“…We thank Bas van den Herik for helpful discussions. This manuscript has been released as a pre-print at BioRxiv (Boer et al, 2019).…”

Section: Author Contributionsmentioning

confidence: 99%