Systemic control of legume susceptibility to rhizobial infection by a mobile microRNA

Tsikou, Daniela; Yan, Zhe; Holt, Dennis B.; Abel, Nikolaj B.; Reid, Dugald; Madsen, Lene Heegaard; Bhasin, Hemal; Sexauer, Moritz; Stougaard, Jens; Markmann, Katharina

doi:10.1126/science.aat6907

Cited by 215 publications

(241 citation statements)

References 36 publications

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“…Consistent with Tsikou et al . (), when examined at 3 dai, lhk1‐1 roots were not significantly different from the corresponding wild‐type samples in terms of the CLE‐RS1 gene expression, whereas CLE‐RS3 was significantly lower in the mutant (Fig. S4).…”

Section: Resultsmentioning

confidence: 91%

“…Consistent with Tsikou et al . (), the absence of functional LHK1 strongly limited the steady‐state level of the TML mRNA in M. loti ‐inoculated roots. However, under the conditions used in this studies, TML remained somewhat responsive to M. loti infection in the lhk1‐1 single mutant, whereas this was totally lost in the triple cytokinin receptor mutant.…”

Section: Discussionmentioning

confidence: 89%

“…3–5 d (Suzuki et al ., ), which would not be fast enough to limit the initial M. loti infections. However, significant changes to shoot and root miR2111 levels were already detected within the first 2 d after M. loti inoculation (Tsikou et al ., ), indicating that regulation of TML is a relatively rapid process. Our data emphasize the root function of LHK1‐cortex in regulating M. loti infection (Fig.…”

Section: Discussionmentioning

confidence: 99%

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Inside out: root cortex‐localized LHK1 cytokinin receptor limits epidermal infection of Lotus japonicus roots by Mesorhizobium loti

et al. 2019

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Summary During Lotus japonicus–Mesorhizobium loti symbiosis, the LOTUS HISTIDINE KINASE1 (LHK1) cytokinin receptor regulates both the initiation of nodule formation and the scope of root infection. However, the exact spatiotemporal mechanism by which this receptor exerts its symbiotic functions has remained elusive. In this study, we performed cell type‐specific complementation experiments in the hyperinfected lhk1‐1 mutant background, targeting LHK1 to either the root epidermis or the root cortex. We also utilized various genetic backgrounds to characterize expression of several genes regulating symbiotic infection. We show here that expression of LHK1 in the root cortex is required and sufficient to regulate both nodule formation and epidermal infections. The LHK1‐dependent signalling that restricts subsequent infection events is triggered before initial cell divisions for nodule primordium formation. We also demonstrate that AHK4, the Arabidopsis orthologue of LHK1, is able to regulate M. loti infection in L. japonicus, suggesting that an endogenous cytokinin receptor could be sufficient for engineering nitrogen‐fixing root nodule symbiosis in nonlegumes. Our data provide experimental evidence for the existence of an LHK1‐dependent root cortex‐to‐epidermis feedback mechanism regulating rhizobial infection. This root‐localized regulatory module functionally links with the systemic autoregulation of nodulation (AON) to maintain the homeostasis of symbiotic infection.

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Section: Resultsmentioning

confidence: 91%

Section: Discussionmentioning

confidence: 89%

Section: Discussionmentioning

confidence: 99%

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Inside out: root cortex‐localized LHK1 cytokinin receptor limits epidermal infection of Lotus japonicus roots by Mesorhizobium loti

et al. 2019

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“…Plants engage in symbiotic and parasitic interactions through coordinated interorganismal communication. Two recent studies used grafting to uncover miRNAs that participate in this communication system during symbiotic plant–microbe and pathogenic plant–parasite interactions (Shahid et al ., ; Tsikou et al ., ). Members of the legume family participate in tight symbiotic associations with N‐fixing rhizobia through the formation of specialized root‐derived nodules.…”

Section: Interorganismal Communication Through Mobile Mirnasmentioning

confidence: 97%

“…Although grafting plays a central role in the successful production of many crops, the underlying mechanisms that make particular graft combinations productive remain largely unknown. Independent of its application in agriculture, grafting experiments have been used to discover mobile proteins, mRNAs, small RNAs, and small molecules that impact plant morphology (Kim, ; Haywood et al ., ), reproductive transitions (Corbesier et al ., ; Jaeger & Wigge, ), host–microbe and plant–parasite interactions (Shahid et al ., ; Tsikou et al ., ), root–shoot balance (Lin et al ., ; Spiegelman et al ., ; Chen et al ., ; Landrein et al ., ), and other fundamental organismal processes (Martin et al ., ; Navarro et al ., ; Takahashi et al ., ; Tylewicz et al ., ). Advances in genomic resources and molecular techniques that support grafted crops make it possible for the distinct fields of agricultural and experimental grafting to be merged.…”

Section: Introductionmentioning

confidence: 99%

Connecting the pieces: uncovering the molecular basis for long‐distance communication through plant grafting

Thomas

Frank

2019

New Phytologist

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Summary Vascular plants are wired with a remarkable long‐distance communication system. This network can span from as little as a few centimeters (or less) in species like Arabidopsis, up to 100 m in the tallest giant sequoia, linking distant organ systems into a unified, multicellular organism. Grafting is a fundamental technique that allows researchers to physically break apart and reassemble the long‐distance transport system, enabling the discovery of molecular signals that underlie intraorganismal communication. In this review, we highlight how plant grafting has facilitated the discovery of new long‐distance signaling molecules that function in coordinating developmental transitions, abiotic and biotic responses, and cross‐species interactions. This rapidly expanding area of research offers sustainable approaches for improving plant performance in the laboratory, the field, the orchard, and beyond.

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miRNAs in Plant Development

Swarup

Denyer

2019

Annual Plant Reviews Online

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Since the discovery of the first microRNA (miRNA) in Caenorhabditis elegans about 25 years ago, small RNAs have emerged as key players in the broad regulation of gene expression in most developmental processes in both plants and animals. miRNAs are small (20–24 nt) noncoding RNA molecules involved in post‐transcriptional regulation of gene expression. miRNAs regulate gene expression by cleavage of the target transcript and/or through translational repression. The former appears to be a more prevalent mechanism in plants whereas the later appears to be predominant in animals. The level of miRNA‐target sequence complementarity typically dictates whether mRNA repression or transcript cleavage occurs. This article will focus on our current understanding of the roles of miRNAs in plant development with a key focus on developmentally important miRNAs of the model plant, Arabidopsis thaliana , their modes of action, and the networks to which they belong. This article will also briefly discuss conservation of microRNAs across other plant species and directions for future research on miRNA.

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Systemic control of legume susceptibility to rhizobial infection by a mobile microRNA

Cited by 215 publications

References 36 publications

Inside out: root cortex‐localized LHK1 cytokinin receptor limits epidermal infection of Lotus japonicus roots by Mesorhizobium loti

Inside out: root cortex‐localized LHK1 cytokinin receptor limits epidermal infection of Lotus japonicus roots by Mesorhizobium loti

Connecting the pieces: uncovering the molecular basis for long‐distance communication through plant grafting

miRNAs in Plant Development

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