<p>In eucaryotes, mitogen-activated protein kinase (MAPK) cascades are evolutionarily conserved signalling modules crucial for growth regulation and stress tolerance. However, the regulatory role of MAPK in nutrient sensing by plants remains largely unclear. Here we uncovered MEKK14 and its paralogue MEKK13 determine lateral root elongation via enhanced cell division and expansion. We further fine-mapped a naturally occurring histidine-to-glutamine substitution in MEKK14 that weakens protein kinase activity and attenuates lateral root growth and response to nitrate (NO<sub>3</sub><sup>−</sup>). We further demonstrate that NO<sub>3</sub><sup>−</sup> transcriptionally upregulates <i>MEKK13/14</i> depending on NLP7 to activate a MKK3–MPK1/2/7/14 signalling module. Downstream of this signalling cascade, the core oscillator of the circadian clock CCA1 is phosphorylated and stabilized to feedback induce <i>MEKK13/14</i> expression and to activate auxin signalling-dependent lateral root foraging for NO<sub>3</sub><sup>−</sup>. Our findings reveal a positive-feedback phosphorylation–transcriptional regulatory loop in root NO<sub>3</sub><sup>−</sup> foraging, extending the regulatory function of MAPK signalling in the nutrient sensing.</p>

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A feedback regulatory loop by MAPK–CCA1 engages auxin signalling to stimulate root foraging for nitrate

  • Xiaofei Zhang,
  • Shanmin Zhou,
  • Jingyi Guo,
  • Ricardo F. H. Giehl,
  • Xiaodong Xu,
  • Lixing Yuan,
  • Fusuo Zhang,
  • Malcolm J. Bennett,
  • Nicolaus von Wirén,
  • Zhongtao Jia

摘要

In eucaryotes, mitogen-activated protein kinase (MAPK) cascades are evolutionarily conserved signalling modules crucial for growth regulation and stress tolerance. However, the regulatory role of MAPK in nutrient sensing by plants remains largely unclear. Here we uncovered MEKK14 and its paralogue MEKK13 determine lateral root elongation via enhanced cell division and expansion. We further fine-mapped a naturally occurring histidine-to-glutamine substitution in MEKK14 that weakens protein kinase activity and attenuates lateral root growth and response to nitrate (NO3). We further demonstrate that NO3 transcriptionally upregulates MEKK13/14 depending on NLP7 to activate a MKK3–MPK1/2/7/14 signalling module. Downstream of this signalling cascade, the core oscillator of the circadian clock CCA1 is phosphorylated and stabilized to feedback induce MEKK13/14 expression and to activate auxin signalling-dependent lateral root foraging for NO3. Our findings reveal a positive-feedback phosphorylation–transcriptional regulatory loop in root NO3 foraging, extending the regulatory function of MAPK signalling in the nutrient sensing.