Summary Plant root architecture plasticity in response to biotic stresses has not been thoroughly investigated. Infection by endoparasitic cyst nematodes induces root architectural changes that involve the formation of secondary roots at infection sites. However, the molecular mechanisms regulating secondary root formation in response to cyst nematode infection remain largely unknown. We first assessed whether secondary roots form in a nematode density‐dependent manner by challenging wild‐type Arabidopsis plants with increasing numbers of cyst nematodes (Heterodera schachtii). Next, using jasmonate‐related reporter lines and knockout mutants, we tested whether tissue damage by nematodes triggers jasmonate‐dependent secondary root formation. Finally, we verified whether damage‐induced secondary root formation depends on local auxin biosynthesis at nematode infection sites. Intracellular host invasion by H. schachtii triggers a transient local increase in jasmonates, which activates the expression of ERF109 in a COI1‐dependent manner. Knockout mutations in COI1 and ERF109 disrupt the nematode density‐dependent increase in secondary roots observed in wild‐type plants. Furthermore, ERF109 regulates secondary root formation upon H. schachtii infection via local auxin biosynthesis. Host invasion by H. schachtii triggers secondary root formation via the damage‐induced jasmonate‐dependent ERF109 pathway. This points at a novel mechanism underlying plant root plasticity in response to biotic stress.
SUMMARY Infections by root‐feeding nematodes have profound effects on root system architecture and consequently shoot growth of host plants. Plants harbor intraspecific variation in their growth responses to belowground biotic stresses by nematodes, but the underlying mechanisms are not well understood. Here, we show that the transcription factor TEOSINTE BRANCHED/CYCLOIDEA/PROLIFERATING CELL FACTOR‐9 (TCP9) modulates root system architectural plasticity in Arabidopsis thaliana in response to infections by the endoparasitic cyst nematode Heterodera schachtii. Young seedlings of tcp9 knock‐out mutants display a significantly weaker primary root growth inhibition response to cyst nematodes than wild‐type Arabidopsis. In older plants, tcp9 reduces the impact of nematode infections on the emergence and growth of secondary roots. Importantly, the altered growth responses by tcp9 are most likely not caused by less biotic stress on the root system, because TCP9 does not affect the number of infections, nematode development, and size of the nematode‐induced feeding structures. RNA‐sequencing of nematode‐infected roots of the tcp9 mutants revealed differential regulation of enzymes involved in reactive oxygen species (ROS) homeostasis and responses to oxidative stress. We also found that root and shoot growth of tcp9 mutants is less sensitive to exogenous hydrogen peroxide and that ROS accumulation in nematode infection sites in these mutants is reduced. Altogether, these observations demonstrate that TCP9 modulates the root system architectural plasticity to nematode infections via ROS‐mediated processes. Our study further points at a novel regulatory mechanism contributing to the tolerance of plants to root‐feeding nematodes by mitigating the impact of belowground biotic stresses.
Nematode migration, feeding site formation, withdrawal of plant assimilates and activation of plant defence responses have a significant impact on plant growth and development. Plants display intraspecific variation in tolerance limits for root-feeding nematodes. Although disease tolerance has been recognised as a distinct trait in biotic interactions of mainly crops, we lack mechanistic insights. Progress is hampered by difficulties in quantification and laborious screening methods. We turned to the model plant Arabidopsis thaliana, since it offers extensive resources to study the molecular and cellular mechanisms underlying nematode-plant interactions. We established through imaging of tolerance-related parameters that green canopy area was an accessible and robust measure for assessing damage as the consequence of cyst nematode infection. Subsequently, we developed a high-throughput phenotyping platform to non-destructively measure the green canopy area growth of 960 A. thaliana plants simultaneously. We show that A. thaliana can be used to study tolerance limits of plants to cyst and root-knot nematodes. Although our results can be adequately modelled with classical tolerance limit quantifying methods, real-time monitoring allowed more accurate growth rate measurements. Based on our findings, we believe that our phenotyping platform will enable further studies into the underlying mechanisms of tolerance to below-ground biotic stress.
Nematode migration, feeding site formation, withdrawal of plant assimilates, and activation of plant defence responses have a significant impact on plant growth and development. Plants display intraspecific variation in tolerance limits for root-feeding nematodes. Although disease tolerance has been recognised as a distinct trait in biotic interactions of mainly crops, we lack mechanistic insights. Progress is hampered by difficulties in quantification and laborious screening methods. We turned to the model plant Arabidopsis thaliana, since it offers extensive resources to study the molecular and cellular mechanisms underlying nematode-plant interactions. Through imaging of tolerance-related parameters the green canopy area was identified as an accessible and robust measure for assessing damage due to cyst nematode infection. Subsequently, a high-throughput phenotyping platform simultaneously measuring the green canopy area growth of 960 A. thaliana plants was developed. This platform can accurately measure cyst- and root-knot nematode tolerance limits in A. thaliana through classical modelling of tolerance limits. Furthermore, real-time monitoring provided data for a novel view of tolerance, identifying a compensatory growth response. These findings show that our phenotyping platform will enable further studies into a mechanistic understanding of tolerance to below-ground biotic stress.
Nematode migration, feeding site formation, withdrawal of plant assimilates and activation of plant defence responses have a significant impact on plant growth and development. Plants display intraspecific variation in tolerance limits for root-feeding nematodes. Although disease tolerance has been recognised as a distinct trait in biotic interactions of mainly crops, we lack mechanistic insights. Progress is hampered by difficulties in quantification and laborious screening methods. We turned to the model plant Arabidopsis thaliana, since it offers extensive resources to study the molecular and cellular mechanisms underlying nematode-plant interactions. We established through imaging of tolerance-related parameters that green canopy area was an accessible and robust measure for assessing damage as the consequence of cyst nematode infection. Subsequently, we developed a high-throughput phenotyping platform to non-destructively measure the green canopy area growth of 960 A. thaliana plants simultaneously.
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