| Abstract: | Morphological plasticity of root systems is critically important for plant survival because it allows plants to optimize their capacity to take up water and nutrients from the soil environment. Here we show that a signaling module composed of nitrogen (N)-responsive CLE (CLAVATA3/ESR-related) peptides and the CLAVATA1 (CLV1) leucine-rich repeat receptor-like kinase is expressed in the root vasculature in Arabidopsis thaliana and plays a crucial role in regulating the expansion of the root system under N-deficient conditions. CLE1, -3, -4, and -7 were induced by N deficiency in roots, predominantly expressed in root pericycle cells, and their overexpression repressed the growth of lateral root primordia and their emergence from the primary root. In contrast, clv1 mutants showed progressive outgrowth of lateral root primordia into lateral roots under N-deficient conditions. The clv1 phenotype was reverted by introducing a CLV1 promoter-driven CLV1:GFP construct producing CLV1:GFP fusion proteins in phloem companion cells of roots. The overaccumulation of CLE2, -3, -4, and -7 in clv1 mutants suggested the amplitude of the CLE peptide signals being feedback-regulated by CLV1. When CLE3 was overexpressed under its own promoter in wild-type plants, the length of lateral roots was negatively correlated with increasing CLE3 mRNA levels; however, this inhibitory action of CLE3 was abrogated in the clv1 mutant background. Our findings identify the N-responsive CLE-CLV1 signaling module as an essential mechanism restrictively controlling the expansion of the lateral root system in N-deficient environments.Living organisms have developed dynamic strategies to explore nutrients in the environment. Morphological plasticity of plant roots and microorganisms is often compared with foraging behavior of animals. Plant roots are highly dynamic systems because they can modify their structure to reach nutrient resources in soil and optimize their nutrient uptake capacities. This strategy appears to be associated with morphological adaptation, because plants are sessile in nature and nutrient availabilities in soil are often altered by surrounding biotic and abiotic factors and climate changes. Morphological modifications of plant root systems are particularly prominent when they grow in soil environments with unbalanced nutrient availabilities (1–4). Among the essential elements required for plant growth, nitrogen (N) has a particularly strong effect on root development (1–6). Lateral roots can be developed in N-rich soil patches where adequate amounts of nitrate (NO3−) or ammonium (NH4+) are available, whereas this local outgrowth of lateral roots is restricted in N-deficient patches (7–9). In addition to these local N responses, lateral root growth is stimulated in response to mild N deficiency and suppressed under excess N supply by systemic plant signals carrying information on the nutritional status of distant plant organs (4, 10–13). These morphological responses are important for plant fitness and N acquisition, despite the cost for structuring the root system architecture (2, 6). However, lateral root growth is not sustained when plants are deprived of N for an extended period (4). Under such severe circumstances, the development of new lateral roots should rather be restricted to prevent the risk of extending roots into N-poor environments. Economizing the cost for root development appears to be an important morphological strategy for plant survival.To modify root traits in response to changing N availabilities, plants use various types of signaling molecules including hormones and small RNAs (10, 13–17). In particular, auxin signaling proteins and auxin transporters have been proven essential for lateral root development in response to local nitrate supplies (10, 14–17). These proteins are involved in increasing auxin sensitivity or auxin accumulation at lateral root initials or lateral root tips exposed to NO3−, and the NRT1.1 nitrate transporter has been suggested to play a key role in NO3− sensing (8, 17, 18). In addition, mutations of the nitrate transporter NRT2.1 have been shown to repress or stimulate lateral root initiation depending on N conditions and sucrose supply (12, 19). Thus, N-dependent root development is apparently under control of complex mechanisms, although its signaling components have remained largely unidentified. In this study, we have identified several homologs of the CLE (CLAVATA3/ESR-related) gene family (20–24) to be up-regulated by N deficiency and involved in this yet unresolved regulatory mechanism. CLAVATA3 (CLV3) is known as a signaling peptide that binds to the CLAVATA1 (CLV1) leucine-rich repeat receptor-like kinase (LRR-RLK) and controls stem cell differentiation in the shoot apical meristem (25–32). CLE-receptor signaling modules are also known to control meristem function in the primary and lateral roots (33–35). The N-responsive CLE peptides described in the present study belong to the group of CLE peptides with the highest sequence similarity to CLAVATA3 (CLV3) (21–23) and may partly substitute for CLV3 in the shoot apical meristem (31, 36, 37). Our present findings indicate that the N-responsive CLE peptides and CLV1 are signaling components required for translating an N-deficient nutritional status into a morphological response inhibiting the outgrowth of lateral root primordia in Arabidopsis. The present study demonstrates a unique function of the CLE-CLV1 signaling module in roots and provides new insights into signaling mechanisms regulating the expansion of the plant root system in N-deficient environments. |
