NODULE INCEPTION Recruits the Lateral Root Developmental Program for Symbiotic Nodule Organogenesis in Medicago truncatula

Schiessl, Katharina; Lilley, Jodi L. Stewart; Lee, Tak; Tamvakis, Ioannis; Kohlen, Wouter; Bailey, Paul; Thomas, Aaron; Lupták, Jakub; Karunakaran, Ramakrishnan; Carpenter, Matthew D.; Mysore, Kirankumar S.; Wen, Jiangqi; Ahnert, Sebastian E.; Grieneisen, Verônica A.; Oldroyd, Giles

doi:10.1016/j.cub.2019.09.005

Cited by 191 publications

(240 citation statements)

References 76 publications

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“…Plasmid construction. The Golden Gate modular cloning system was used to prepare the plasmids as described in Schiessl et al 85 . Levels 0 and 1 used in this study are listed in Supplemental Table 6 and held for distribution in the ENSA project core collection (https://www.ensa.ac.…”

Section: Medicago Truncatula Root Assaysmentioning

confidence: 99%

An ancestral signalling pathway is conserved in plant lineages forming intracellular symbioses

Radhakrishnan

Keller

Rich

et al. 2019

Preprint

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Plants are the foundation of terrestrial ecosystems and their colonization of land was facilitated by mutualistic associations with arbuscular mycorrhizal fungi. Following that founding event, plant diversification has led to the emergence of a tremendous diversity of mutualistic symbioses with microorganisms, ranging from extracellular associations to the most intimate intracellular associations, where fungal or bacterial symbionts are hosted inside plant cells. Through analysis of 271 transcriptomes and 122 plant genomes, we demonstrate that the common symbiosis signalling pathway controlling the association with arbuscular mycorrhizal fungi and with nitrogen-fixing bacteria specifically co-evolved with intracellular endosymbioses, including ericoid and orchid mycorrhizae in angiosperms and ericoid-like associations of bryophytes. In contrast, species forming exclusively extracellular symbioses like ectomycorrhizae or associations with cyanobacteria have lost this signalling pathway. This work unifies intracellular symbioses, revealing conservation in their evolution across 450 million years of plant diversification. Introductory paragraphSince they colonized land 450 million years ago, plants have been the foundation of most terrestrial ecosystems 1 . Such successful colonization occurred only once in the plant kingdom and was supported by the symbiotic association formed with arbuscular mycorrhizal fungi 2,3 . Following that founding event, plant diversification was accompanied by the emergence of alternative or additional symbionts 4 . Among alternative symbioses, the association between orchids and basidiomycetes and between Ericales and ascomycetes or basidiomycetes are two endosymbioses with specific intracellular structures in two plant lineages that lost the ability to form the Arbuscular Mycorrhizal Symbiosis (AMS) 5 . As such, orchid mycorrhiza and ericoid-mycorrhiza represent two clear symbiosis switches, whereby intracellular associations are sustained, but the nature of the symbionts are radically different. Similarly, within the liverworts, the Jungermanniales engage in ericoid-like endosymbioses but not AM symbiosis and represent another symbiont switch that occurred during plant evolution 6 . Other symbioses can occur simultaneously with AMS, for example the root nodule symbiosis, an association with nitrogen-fixing bacteria that evolved in the last common ancestor of Fabales, Fagales, Cucurbitales and Rosales 7 . Another example is ectomycorrhizae, an extracellular symbiosis found in several gymnosperm and angiosperm lineages: in some lineages both AMS and ectomycorrhizae have been retained; while other lineages have switched from AMS to ectomycorrhizae 8 . Finally, associations with cyanobacteria, which occur only in the intercellular spaces of the plant tissue, can be found in diverse species within the embryophytes, in hornworts, liverworts, ferns, gymnosperms and angiosperms 9 . Despite the improved nutrient acquisition afforded to plants by these different types of mutualistic symbioses, e...

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Section: Medicago Truncatula Root Assaysmentioning

confidence: 99%

An ancestral signalling pathway is conserved in plant lineages forming intracellular symbioses

Radhakrishnan

Keller

Rich

et al. 2019

Preprint

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“…Many legumes can form a second secondary root organ, the nodule, which house nitrogen-fixing rhizobial bacteria and the formation of these nodule organs is dramatically repressed by nitrogen supply (Goh et al 2018). Indeed, in legumes there is a clear overlap in some of the genes and signals that regulate root development and nodulation in response to nitrogen and this dovetails with recent evidence that legume nodules are derived in part from a modified lateral root organ development program (Schiessl et al 2019;Soyano et al 2019).…”

Section: Introductionmentioning

confidence: 77%

The role of CLV1, CLV2 and HPAT homologs in nitrogen-regulation of root development

Wang

Reid

Foo

2020

Preprint

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Plants use a variety of hormonal and peptide signals to control root development, including in adapting root development to cope with nutrient stress. Nitrogen (N) is a major limiting factor in plant growth and in response to N stress plants dramatically modulate root development, including in legumes influencing the formation of N-fixing nodules in response to external N supply. Recently, specific CLE peptides and/or receptors important for their perception, including CLV1 and CLV2, have been found to play important roles in root development in a limited number of species, including in some cases the response to N. In the legume Medicago truncatula, this response also appears to be influenced by RDN1, a member of the hydroxyproline O-arabinosyltransferase (HPAT) family which can modify specific CLE peptides. However, it not known if this signalling pathway plays a central role in root development across species, in particular root responses to N. In this study, we sought to systematically examine the role of homologues of these genes in root development of the legume pea (Pisum sativum. L) and non-legume tomato (Solanum lycopersicum) using a mutant based approach. This included a detailed examination of root development in response to N in these mutant series in tomato. We found no evidence for a role of these genes in pea seedling root development. Furthermore, the CLV1-like FAB gene did not influence tomato root development, including N response. In contrast, both CLV2 and the HPAT FIN appear to positively influence root size in tomato but do not mediate root responses to N. These suggest a relatively species-specific role for these genes in root development, including N regulation of root architecture.

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“…Downstream of LysM-RLKs, multiple signalling pathways emerge from SYMRK; ranging from the activation of mevalonate pathway for a putative secondary messenger for activating Ca 2+ -oscillations (Kevei et al, 2007;Venkateshwaran et al, 2015), inhibition of MAPKK activity (Chen et al, 2012) and importantly to activation of LjNIN (Zhu et al, 2008;Wang et al, 2013), a transcriptional regulator that coordinates both infection and nodule organogenesis, and recently demonstrated to have recruited the lateral root development pathway for nodule development (Schiessl et al, 2019). Because overexpression of LjNFR5, LjNFR1 or especially, LjSYMRK is sufficient for spontaneous nodule formation in the absence of symbiont (Ried et al, 2014); it is unsurprising that there is a multitude of regulatory mechanisms on the receptors to ensure appropriate activation only when the symbiont is present.…”

Section: Rlk Interactions Downstream Of Ligand Perceptionmentioning

confidence: 99%

Receptor-Like Kinases Sustain Symbiotic Scrutiny

Chiu

Paszkowski

2020

Plant Physiol.

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Plant receptor-like kinases (RLKs) control the initiation, development and maintenance of symbioses with beneficial mycorrhizal fungi and nitrogen-fixing bacteria. Carbohydrate perception activates symbiosis signalling via Lysin-motif (LysM) RLKs and subsequently the common symbiosis signalling pathway. As the receptors activated are often also immune receptors in multiple species, exactly how carbohydrate identities avoid immune activation and drive symbiotic outcome is still not fully understood. This may involve the coincident detection of additional signalling molecules that provide specificity. Because of the metabolic costs of supporting symbionts, the level of symbiosis development is fine-tuned by a range of local and mobile signals that are activated by various RLKs. Beyond early, pre-contact symbiotic signalling, signal exchanges ensue throughout infection, nutrient exchange and turnover of symbiosis. Here, we review the latest understanding on plant symbiosis signalling from the perspective of RLK-mediated pathways.

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NODULE INCEPTION Recruits the Lateral Root Developmental Program for Symbiotic Nodule Organogenesis in Medicago truncatula

Cited by 191 publications

References 76 publications

An ancestral signalling pathway is conserved in plant lineages forming intracellular symbioses

An ancestral signalling pathway is conserved in plant lineages forming intracellular symbioses

The role of CLV1, CLV2 and HPAT homologs in nitrogen-regulation of root development

Receptor-Like Kinases Sustain Symbiotic Scrutiny

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