Differentiation of Symbiotic Cells and Endosymbionts in Medicago truncatula Nodulation Are Coupled to Two Transcriptome-Switches

The legume plant Medicago truncatula establishes a symbiosis with the nitrogen-fixing bacterium Sinorhizobium meliloti which takes place in root nodules. The formation of nodules employs a complex developmental program involving organogenesis, specific cellular differentiation of the host cells and the endosymbiotic bacteria, called bacteroids, as well as the specific activation of a large number of plant genes. By using a collection of plant and bacterial mutants inducing non-functional, Fix− nodules, we studied the differentiation processes of the symbiotic partners together with the nodule transcriptome, with the aim of unravelling links between cell differentiation and transcriptome activation. Two waves of transcriptional reprogramming involving the repression and the massive induction of hundreds of genes were observed during wild-type nodule formation. The dominant features of this “nodule-specific transcriptome” were the repression of plant defense-related genes, the transient activation of cell cycle and protein synthesis genes at the early stage of nodule development and the activation of the secretory pathway along with a large number of transmembrane and secretory proteins or peptides throughout organogenesis. The fifteen plant and bacterial mutants that were analyzed fell into four major categories. Members of the first category of mutants formed non-functional nodules although they had differentiated nodule cells and bacteroids. This group passed the two transcriptome switch-points similarly to the wild type. The second category, which formed nodules in which the plant cells were differentiated and infected but the bacteroids did not differentiate, passed the first transcriptome switch but not the second one. Nodules in the third category contained infection threads but were devoid of differentiated symbiotic cells and displayed a root-like transcriptome. Nodules in the fourth category were free of bacteria, devoid of differentiated symbiotic cells and also displayed a root-like transcriptome. A correlation thus exists between the differentiation of symbiotic nodule cells and the first wave of nodule specific gene activation and between differentiation of rhizobia to bacteroids and the second transcriptome wave in nodules. The differentiation of symbiotic cells and of bacteroids may therefore constitute signals for the execution of these transcriptome-switches

DNF2 and SYMCRK : two genes involved in the symbiotic control of defense reaction in Medicago truncatula

Medicago truncatula forme une association symbiotique avec Sinorhizobium meliloti qui conduit à la formation de nodosités fixatrices d’azote. Les cellules symbiotiques végétales accueillent des centaines de bactéries qui restent viables dans la nodosité et se différencient en bactéroïdes fixateurs d’azote. Dans le but de mieux comprendre les mécanismes moléculaires nécessaires à la mise en place de cette interaction, nous avons recherché de nouveaux gènes de plante requis pour une symbiose effective en utilisant des approches de génétique directe et inverse. Des méthodes de biologie cellulaire et moléculaire ont été utilisées pour caractériser le phénotype des mutants et mieux comprendre la fonction biologique de ces gènes.Le gène symbiotique DNF2 code une phosphatidylinositol phospholipase C putative. Les nodosités formées par le mutant dnf2 contiennent une zone de fixation qui est réduite et dans laquelle les rhizobia ne se différencient pas complètement en bactéroïdes. De plus ces nodosités sénescent rapidement et présentent des réactions similaires à des réponses de défense. Sous certaines conditions d’expérimentation, le phénotype sauvage peut être restauré chez ce mutant ce qui montre le caractère conditionnel du phénotype.Le gène symbiotique SYMCRK code un récepteur kinase riche en cystéine. Le phénotype du mutant symCRK est similaire à celui de dnf2, ce qui suggère que ces deux gènes sont impliqués dans des processus aboutissant à des réponses similaires, probablement la persistance des bactéries dans les cellules végétales ou l’inhibition des réactions de défense de la plante. Les phénotypes Fix- atypiques des mutants dnf2 et symCRK suggèrent que les gènes correspondants sont impliqués dans les processus de répression des défenses de la plante et de persistance des bactéroïdes.Medicago truncatula and Sinorhizobium meliloti form a symbiotic association resulting in the formation of nitrogen-fixing nodules. In the nodules, symbiotic plant cells home and maintain hundreds of viable bacteria which are differentiated into bacteroids, the nitrogen-fixing form of rhizobia. In order to better understand the molecular mechanism sustaining this phenomenon, we used a combination of forward and reverse genetics approaches to identify genes required for nitrogen fixation. In addition we have used cell and molecular biology to characterize the phenotype of the corresponding mutants and to gain an insight into the genes functions.The symbiotic gene DNF2 encodes a putative phosphatidylinositol phospholipase C-like protein. Nodules formed by the mutant contain a zone of infected cells reduced to a few cell layers. In this zone, bacteria do not differentiate properly into bacteroids. Mutant nodules senesce rapidly and they exhibit defense-like reactions. The dnf2 symbiotic phenotype has been shown to be dependent on the experimental conditions.The symbiotic gene SYMCRK encodes a cystein-rich receptor kinase. The symCRK phenotype is similar to dnf2 suggesting that the two genes SYMCRK and DNF2 are participating in similar processes. This atypical phenotype amongst Fix- mutants unravels DNF2 and SYMCRK as new actors of bacteroid persistence inside symbiotic plant cells and repression of plant defense

Perioral myoclonia syndrome with absences: about 2 cases

peer reviewedPerioral myoclonia with absences (POMA) was first described in 1994 by CP Panayotopoulos who identified 6 cases that did not fit with the classical syndrome of absence epilepsy in children and whose predominant symptom during the absence seizure was the occurrence of myoclonia of perioral muscles. The POMA belongs to the group of generalized idiopathic epilepsies. It begins in childhood and there is a female predominance. It may be accompanied by tonic-clonic generalized seizures as well as absence status epilepticus. It has the EEG characteristics of typical absence seizures and therefore remains currently considered as such. The clinical manifestations of POMA are often misdiagnosed as focal motor seizures. This syndrome can be pharmacoresistant and is not likely to regress spontaneously. We present two clinical observations of perioral myoclonia with absences. The first case illustrates the typical electro-clinical features of this syndrome while the second illustrates its pharmacoresistance

DNF2 et SYMCRK (deux gènes impliqués dans le contrôle symbiotique des réactions de défense chez Medicago truncatula)

Medicago truncatula forme une association symbiotique avec Sinorhizobium meliloti qui conduit à la formation de nodosités fixatrices d azote. Les cellules symbiotiques végétales accueillent des centaines de bactéries qui restent viables dans la nodosité et se différencient en bactéroïdes fixateurs d azote. Dans le but de mieux comprendre les mécanismes moléculaires nécessaires à la mise en place de cette interaction, nous avons recherché de nouveaux gènes de plante requis pour une symbiose effective en utilisant des approches de génétique directe et inverse. Des méthodes de biologie cellulaire et moléculaire ont été utilisées pour caractériser le phénotype des mutants et mieux comprendre la fonction biologique de ces gènes.Le gène symbiotique DNF2 code une phosphatidylinositol phospholipase C putative. Les nodosités formées par le mutant dnf2 contiennent une zone de fixation qui est réduite et dans laquelle les rhizobia ne se différencient pas complètement en bactéroïdes. De plus ces nodosités sénescent rapidement et présentent des réactions similaires à des réponses de défense. Sous certaines conditions d expérimentation, le phénotype sauvage peut être restauré chez ce mutant ce qui montre le caractère conditionnel du phénotype.Le gène symbiotique SYMCRK code un récepteur kinase riche en cystéine. Le phénotype du mutant symCRK est similaire à celui de dnf2, ce qui suggère que ces deux gènes sont impliqués dans des processus aboutissant à des réponses similaires, probablement la persistance des bactéries dans les cellules végétales ou l inhibition des réactions de défense de la plante. Les phénotypes Fix- atypiques des mutants dnf2 et symCRK suggèrent que les gènes correspondants sont impliqués dans les processus de répression des défenses de la plante et de persistance des bactéroïdes.Medicago truncatula and Sinorhizobium meliloti form a symbiotic association resulting in the formation of nitrogen-fixing nodules. In the nodules, symbiotic plant cells home and maintain hundreds of viable bacteria which are differentiated into bacteroids, the nitrogen-fixing form of rhizobia. In order to better understand the molecular mechanism sustaining this phenomenon, we used a combination of forward and reverse genetics approaches to identify genes required for nitrogen fixation. In addition we have used cell and molecular biology to characterize the phenotype of the corresponding mutants and to gain an insight into the genes functions.The symbiotic gene DNF2 encodes a putative phosphatidylinositol phospholipase C-like protein. Nodules formed by the mutant contain a zone of infected cells reduced to a few cell layers. In this zone, bacteria do not differentiate properly into bacteroids. Mutant nodules senesce rapidly and they exhibit defense-like reactions. The dnf2 symbiotic phenotype has been shown to be dependent on the experimental conditions.The symbiotic gene SYMCRK encodes a cystein-rich receptor kinase. The symCRK phenotype is similar to dnf2 suggesting that the two genes SYMCRK and DNF2 are participating in similar processes. This atypical phenotype amongst Fix- mutants unravels DNF2 and SYMCRK as new actors of bacteroid persistence inside symbiotic plant cells and repression of plant defense.PARIS11-SCD-Bib. électronique (914719901) / SudocSudocFranceF

Cellulite faciale sévère au départ d'une lésion de varicelle - à propos d'un cas

peer reviewe

Growth Conditions Determine the DNF2 Requirement for Symbiosis

International audienceRhizobia and legumes are able to interact in a symbiotic way leading to the development of root nodules. Within nodules, rhizobia fix nitrogen for the benefit of the plant. These interactions are efficient because spectacularly high densities of nitrogen fixing rhizobia are maintained in the plant cells. DNF2, a Medicago truncatula gene has been described as required for nitrogen fixation, bacteroid's persistence and to prevent defense-like reactions in the nodules. This manuscript shows that a Rhizobium mutant unable to differentiate is not sufficient to trigger defense-like reactions in this organ. Furthermore, we show that the requirement of DNF2 for effective symbiosis can be overcome by permissive growth conditions. The dnf2 knockout mutants grown in vitro on agarose or Phytagel as gelling agents are able to produce nodules fixing nitrogen with the same efficiency as the wild-type. However, when agarose medium is supplemented with the plant defense elicitor ulvan, the dnf2 mutant recovers the fix- phenotype. Together, our data show that plant growth conditions impact the gene requirement for symbiotic nitrogen fixation and suggest that they influence the symbiotic suppression of defense reactions in nodules