Recherche de suppresseurs de la toxicité induite chez Arabidopsis thaliana par l’effecteur de type 3 DspA/E et étude du stress oxydant au cours de l’infection / Looking for suppressors of the induced toxicity by the type 3 effector DspA/E in Arabidopsis thaliana and study of the oxidative stress during the infection.

Launay, Alban

23 May 2014

La bactérie Erwinia amylovora est responsable de la maladie du feu bactérien des Maleae (pommier, poirier…). Le pouvoir pathogène de cette bactérie dépend d'une seringue moléculaire appelé système de sécrétion de type 3 (SSTT). Ce SSTT permet à la bactérie d’injecter des effecteurs dans les cellules de la plante. Parmi les effecteurs injectés, DspA/E est l'effecteur indispensable au pouvoir pathogène d’E. amylovora. Cet effecteur est à lui seul capable de provoquer la mort des cellules chez le pommier et le tabac et permet à la bactérie de se multiplier de manière transitoire chez A. thaliana. L’objectif de ce travail de thèse était de comprendre la fonction de DspA/E dans la cellule végétale et d’identifier des facteurs végétaux impliqués dans la toxicité de DspA/E. Afin de répondre à cette question, des plantes transgéniques exprimant DspA/E sous contrôle d’un promoteur inductible à l’estradiol ont été construites.Dans un premier temps, la caractérisation phénotypique des lignées exprimant DspA/E a été effectuée. Les résultats obtenus montrent que DspA/E est toxique lorsqu'il est exprimé in planta (il provoque la mort des cellules, inhibe la germination, la croissance racinaire et la traduction) et permet la multiplication in planta d’un mutant dspA/E. Un crible de mutants suppresseurs de la toxicité de l'effecteur DspA/E a été effectué sur une lignée transgénique exprimant DspA/E dans le but d'identifier un ou plusieurs gènes impliqués dans la toxicité de DspA/E. Ce crible suppresseur a permis d'identifier un candidat potentiel impliqué dans la photo-respiration, la glycolate oxydase 2 (GOX2). L’analyse fonctionnelle réalisée sur le mutant gox2-2 a permis de montrer que le gène GOX2 est un régulateur positif des réponses de défense d’A. thaliana en réponse à l’infection par E. amylovora.Enfin, la caractérisation du stress oxydant a permis de montrer que plusieurs formes actives de l’oxygène (H2O2 et O2.-) s’accumulent au cours de l’interaction entre A. thaliana et E. amylovora. Ceci a permis également de comprendre le rôle de DspA/E sur ce stress oxydant. Nos résultats suggèrent que la glycolate oxydase 2 participerait à l’induction du stress oxydant en perturbant le métabolisme des sucres. / The bacterium E. amylovora is responsible for the fire blight disease of Maleae (apple, pear…). The pathogenicity of this bacterium relies on a molecular syringe, the type three secretion system (TTSS). This TTSS allows the bacterium to inject effector proteins into the plant cell. Among these effectors, DspA/E is essential for the pathogenicity of E. amylovora. This effector can provoke cell death on apple and tobacco and allows the bacterium to multiply transiently in A. thaliana.The purpose of the thesis was to understand the function of DspA/E in the plant cell and to identify plant factors involved in the toxicity of DspA/E. To answer this question, transgenic plants which express DspA/E under an estradiol-inducible promoter were built.At first, phenotypical characterization of DspA/E transgenic lines was performed. Our results showed that DspA/E is toxic when expressed in planta (it provokes cell death, inhibits germination, root growth and translation) and allows in planta multiplication of dspA/E bacterial mutant. A screening for suppressor mutants of DspA/E toxicity was performed on a DspA/E transgenic line in order to identify one or several genes involved in the toxicity of DspA/E. This screening allowed us to identify a potential candidate involved in photorespiration, the glycolate oxidase 2 (GOX2). Functional analysis performed on the gox2-2 mutant allowed us to show that the GOX2 gene is a positive regulator of A. thaliana responses against E. amylovora.Finally, characterization of oxidative stress allowed us to show that several reactive oxygen species (H2O2 et O2.-) accumulate during A. thaliana and E. amylovora interaction. This allowed us to understand the role of DspA/E in the oxidative stress. Our results suggest that the glycolate oxidase 2 could be involved in the induction of the oxidative stress by disrupting sugar metabolism.

Arabidopsis thaliana

Erwinia amylovora

DspA/E

Glycolate oxidase 2

Stress oxydant

Arabidopsis thaliana

Erwinia amylovora

DspA/E

Glycolate oxidase 2

Oxidative stress

Etude du rôle des sidérophores microbiens dans la modulation des défenses de la plante Arabidopsis thaliana / Study of the role of microbial siderophores in modulating immunity from the plant Arabidopsis thaliana

Aznar, Aude

21 May 2014

Le fer est un élément essentiel pour presque tous les êtres vivants cependant, il est peu biodisponible et est toxique dans sa forme libre car il engendre des formes réactives de l'oxygène via la réaction de Fenton. Pour se procurer le fer, les microorganismes sécrètent de petites molécules nommées sidérophores ayant une très forte affinité pour Fe3+. Les sidérophores sont requis pour la pathogénie de plusieurs agents pathogènes sur hôtes animaux ou végétaux, mais ce sont également des éliciteurs de défense. Des travaux antérieurs ont montré que les sidérophores activent les défenses et les gènes de réponse à la carence en fer chez Arabidopsis thaliana. L’activation de réponses de défense par le sidérophore requiert un niveau physiologique de fer dans la plante indiquant que le fer participe à la mise en place de ce processus. Au cours de ma thèse, les réponses globales de la plante A. thaliana au sidérophore deferrioxamine (DFO) ont été étudiées par une approche transcriptome. Les résultats obtenus montrent que le principal processus activé est l’immunité. En utilisant des chélateurs de fer différents, j’ai montré que l’effet chélation du fer est responsable de l’activation de l’immunité. Le traitement sidérophore provoque également une perturbation de l’homéostasie du fer et d’autres métaux dans la plante. Dans un mutant irt1 affecté dans le transport de plusieurs métaux lourds dont le fer, l’activation des défenses par la DFO est compromise. Par ailleurs, j’ai étudié l’effet du statut en fer de la plante sur sa sensibilité à la bactérie pathogène Dickeya dadantii et sur l’expression des défenses. Il apparait que le fer est requis pour la mise en place de plusieurs processus de défense en réponse à D. dadantii. Les plantes carencées en fer sont plus résistantes à l’infection. Une quantité de fer physiologique dans la plante est requise pour la multiplication bactérienne et pour l’expression des facteurs de pathogénie, les pectate lyases. Le marquage du fer par la méthode Perls’-DAB-H2O2 montre que celui–ci est très peu abondant dans les tissues végétaux contenant les bactéries qui, elles, sont chargées de fer. Dans l’ensemble, nos résultats montrent que le fer est requis dans l’arsenal défensif de la plante mais qu’il est également un facteur limitant pour le cycle infectieux de D. dadantii. / Iron is an essential element for almost all living organisms, however, it is not bioavailable and is toxic in its free form as it generates reactive oxygen species via the Fenton reaction. To obtain iron, microorganisms secrete small molecules named siderophores with very high affinity for Fe3 +. Siderophores are required for the pathogenesis of several pathogens on animals or plants, but they also are elicitors of defenses. Previous work has shown that siderophores activate defenses and iron deficiency response genes in Arabidopsis thaliana. The activation of defense responses by the siderophore requires a physiological level of iron in the plant indicating that iron is involved in the activation of this process. In my thesis, the global response of the plant A. thaliana to the siderophore deferrioxamine (DFO) has been studied by a transcriptomic approach. The results obtained show that the main process being activated is immunity. By using different iron chelating agents, I have shown that the iron chelation effect is responsible for the activation of immunity. The siderophore treatment also causes disturbance in the homeostasis of iron and other metals in the plant. In an irt1 mutant affected in the transport of heavy metals including iron, activation of defenses by the DFO is compromised. In addition, I studied the effect of iron status of the plant on its susceptibility to the pathogenic bacteria Dickeya dadantii and on the expression of defenses. It appears that iron is required for the establishment of several defense processes in response to D. dadantii. The iron deficient plants are more resistant to infection. A physiological amount of iron in the plant is required for bacterial growth and for expression of the virulence factors, pectate lyases. Iron staining by the Perls' -DAB - H2O2 method shows that low abundance of this metal in plant tissue coincides with the presence of bacteria, which contain high amounts of iron. Overall, our results show that iron is required in the defense arsenal of the plant but it is also a limiting factor for the infectious cycle of D. dadantii.

Sidérophore

Arabidopsis thaliana

Défense des plantes

Fer

Éliciteur

Dickeya dadantii

Siderophore

Arabidopsis thaliana

Plant defense

Iron

Elicitor

Dickeya dadantii

Etude des interactions entre la plante Arabidopsis thaliana (L.) Heynh et le ver de terre Aporrectodea caliginosa (Savigny) : application à la phytoremédiation de l'arsenic et de l'antimoine

Jana, Ulrike

14 December 2009

L‘arsenic et l‘antimoine bien que n‘étant pas recensés parmi les polluants majeurs de l‘environnement sont souvent retrouvés associés à d‘autres contaminants. En France, et plus particulièrement dans la région Auvergne, de nombreux sites miniers où s‘effectuait l‘extraction de l‘antimoine sont désormais à l‘abandon. Pouvant présenter des risques pour les populations avoisinantes, leur réhabilitation est donc une mission d‘intérêt public. L‘idée de ce travail de doctorat est de tester l‘effet d‘un catalyseur : le ver de terre sur l‘efficacité des processus de phytoremédiation. En tant qu‘« ingénieurs du sol », ils sont à la base des processus de pédogénèse et peuvent donc assurer la restructuration du sol. De plus, de nombreuses études ont montré leurs effets positifs sur la production de biomasse végétale. Cependant, les mécanismes moléculaires responsables de cette acroissement de production demeurent méconnus. Un système expérimental novateur, jamais utilisé en Ecologie des Sols et couplant la plante modèle Arabidopsis thaliana (L.) Heynh et Aporrectodea caliginosa (Savigny), un ver de terre endogé commun des régions tempérées, a été mis en place afin de 1) identifier les principales voies métaboliques modifiées en réponse aux vers de terre et pouvant expliquer leurs effets positifs sur la croissance et le développement des végétaux, 2) étudier la nutrition minérale en fer et en phosphate, notamment au niveau des variations d‘expression des transporteurs de ces deux éléments, 3) tester ce système pour la phytoextraction de sédiments, issus d‘un ancien site minier, contaminés à l‘arsenic et à l‘antimoine. Les résultats montrent que l‘amélioration des processus de minéralisation est déterminante dans l‘accroissement de la biomasse d‘Arabidopsis thaliana qui se traduit aussi par une élévation des teneurs en azote dans les parties aériennes. Cependant, la présence de phytohormones, produites par des bactéries activées par leur transit dans le ver de terre semble également impliquée dans le renforcement de l‘absorption d‘azote. A l‘échelle moléculaire, les vers entraînent une surexpression du gène HBT, impliqué dans la division cellulaire et semblent diminuer le stress oxydant puisque la quantité de transcrits SOD Cu/Zn diminue. Les résultats montrent de plus que les vers de terre augmentent de façon significative l‘absorption et l‘accumulation de fer, de phosphate et d‘autres minéraux essentiels à la croissance du végétal. Moléculairement, l‘augmentation de l‘absorption des nutriments se traduit par une augmentation de la transcription de certains gènes codant des transporteurs tels que PHT1.3, qui est un transporteur de haute affinité pour le phosphate. Une augmentation de la transcription et également de l‘activité de la protéine FRO2, qui est à l‘origine de la chélation et de la réduction du fer a été observée. Dans les feuilles, les vers de terre induisent de manière systémique la surexpression d‘un transporteur de phosphate localisé dans les chloroplastes, PHT2.1 et la surexpression de transporteurs du fer appartenant à la famille des NRAMPs, notamment NRAMP1,2 et 6. Dans le contexte d‘une problématique de phytoremédiation, l‘effet des vers de terre sur la capacité de phytoextraction d‘Arabidopsis a été testé et, il ressort clairement de cette étude que les vers de terre permettent une meilleure absorption d‘antimoine et d‘arsenic. Cependant, ces deux métalloïdes tendent à rester dans les racines et ne sont que faiblement transferrés vers les parties aériennes. Cette formidable augmentation des concentrations en polluants dans les racines entraîne un retard de croissance considérable et affecte, dans une moindre mesure cependant, l‘activité photosynthétique et les échanges gazeux d‘Arabidopsis. Ainsi, ce travail de thèse a donc tout d‘abord démontré la sensibilité aux vers de terre de la plante modèle Arabidopsis thaliana. Ce système expérimental novateur offre de nouvelles possibilités de recherches dans le domaine des études des interactions entre les vers de terre et les plantes, notamment en raison de la grande diversité de mutants d‘Arabidopsis. De plus, ce travail a également permis de démontrer le rôle crucial de catalyseur que peuvent jouer les vers de terre en vue d‘optimisation des processus de phytoextraction. / Arsenic and antimony do not belong to the major pollutants of the environment but are offen foun associated with other contaminants. In France, more specifically in Auvergne region, a large number of old mining site where antimony was extracted are currently abandoned. As they present several risks for the neighbourhood populations, their habilitaion appears to be essential. The main idea if this PhD work is to test a catalysor: the earthworms in order to increase phytoremédiation efficacity. As ―soils ingeniors‖, they are involved in pedogenesis process and can lead to soil reorganization. Moreover, several studies have presented their positive effects on plant biomass. Nevertheless, the molecular mechanisms responsible of this production enhancement remain still unknown. An innovative experimental system, never used in Soil Ecology, using the model plant Arabidopsis thaliana (L.) Heynh and the endogeic temperate earthworms Aporrectodea caliginosa (Savigny) has been set up. This research work has three goals. First, identify the main metabolic pathway affected by earthworm presence and able to explain their positive effects on plant growth and development. Then, this research work focused on phosphorus and iron nutrition particularly by studing the molecular variation of several transporters of these elements. Lastly this system has been tested for phytoextraction of wastes from an old mining site polluted by arsenic and antimony. In the first part of this study, the mineralization process improvement appears to be a determining factor in Arabidopsis growth enhancement due to nitrogen increase in the shoots. Nevertheless, phytohormones producted by bacteria activated during their transit into earthworm gut seem to be involved in nitrate assimilation. At the molecular scale, earthworms enhance an overaccumulation of HBT transcripts involved in cell division and they seem to decrease the oxidative stress as SOD transcripts are underexpressed. The second part of this study focused on mineral nutrition. Results show that earthworms enhance significantly the uptake and accumulation of phosphorus, iron and other growth essential minerals. At the molecular scale, the nutrient uptake increase result in an increase of several transporters such as Pht1.3, which is a high affinity phosphate transporter and also an overexpression and an increase in enzymatic activity of the ferric chelate reductase protein FRO2. In the leaves, this experiment also show the overaccumulation of a phosphate chloroplastic transporter Pht2.1 and over expression of iron transporter belonging to the NRAMPS family, especially NRAMP1,2 and 6. Then, this system has been transposed to the phytoremédiation and earthworm effects have been tested on the phytoextraction properties of Arabidopsis. Earthworms allow a better uptake of arsenic and antimony. Nevertheless the pollutants tend to remain in the root system and are not translocated in the aerial part. This incredible increase in pollutant tissue concentration leads to a growth and development delay and affect the Arabidopsis photosynthetic activity. To conclude, this PhD work has first shown earthworm sensitivity of Arabidopsis. This innovative system offers new investigation possibilities in the interaction between earthworms and plant area, especially due to the large range of Arabidopsis mutants. Moreover, this work has also demonstrated the key role as catalysor that can play earthworms in order to optimize phytoremédiation process.

Arabidopsis thaliana

Aporrectodea caliginosa

Arsenic

Antimoine

Expression de gênes

Echanges gazeux

Arabidopsis thaliana

Aporrectodea caliginosa

Arsenic

Antimony

Gene expression

Gas exchange

Etude des ARN Polymérases ARN-dépendantes impliquées dans le RNA silencing

Devert, Anthony

21 October 2011

Ce travail de thèse porte sur l’étude des ARN polymérases ARN dépendant impliquées dans le RNA silencing chez Arabidopsis thaliana. Durant ma thèse, la recherche d'interacteurs des RDR, parmi des protéines impliquées dans le RNA silencing, a permis la détection d'interaction entre RDR6 et SDE3, RDR6 et SGS3, mais aussi entre SDE3 et SGS3 en Co-IP et BiFC. Une co-localisation de ces protéines a été observée lorsqu'elles sont produites transitoirement dans des cellules épidermales de N. benthamiana.Un crible d’une banque d’ADNc d’A. thaliana par double hybride de levure, a permis d’isoler des interacteurs potentiels de RDR6. Deux interacteurs potentiels, AtUAP56-1 et U2B’’, sont impliqués dans l’épissage des précurseurs des ARNm. Un effet sur le RNA silencing dans des mutants de l’épissage en 3’ des ARNm était connu et nous avons confirmé l’interaction entre RDR6 et AtUAP56-1 par BiFC. L’étude de lignées mutantes pour AtUAP56-1 a donc été initiée.Une étude biochimique de RDR6 et de RDR2 a été réalisée. Des formes recombinantes de RDR2 et RDR6 ont été produites de façon transitoire dans des feuilles de N. benthamiana, et une étude comparative de RDR2 et RDR6 a été réalisée. Les deux RDR sont actives sur des matrices ARN et ADN, et montrent in vitro une activité amorce-indépendante. De plus, nous avons détecté pour la première fois une activité amorce-dépendante de RDR6 et RDR2. Ces résultats apportent de nouvelles données biochimiques qui sont en accord avec les études menées in vivo et enrichissent les modèles actuels du RNA silencing. / The aim of this work was to study RNA-dependent RNA polymerases involved in RNA silencing in Arabidopsis thaliana. During my thesis, the search for RDR interactors among proteins involved in RNA silencing allowed the detection of interactions between RDR6 and SDE3, RDR6 and SGS3, and also between SDE3 and SGS3 using Co-IP and BiFC. In addition, the co-localisation of these proteins was observed when produced transiently in epidermal cells of N. Benthamiana.A screen of an A. thaliana cDNA library by yeast two hybrid allowed us to identify some putative new RDR6 interactors. Two putative RDR6 interactors, AtUAP56 and U2B’’, are known to be involved in pre-miRNA splicing. Furthermore, a link between pre-mRNA 3’ splicing and RNA silencing was previously reported. We also confirmed the interaction between AtUAP56-1 and RDR6 by BiFC. An investigation of A. thaliana of AtUAP56-1 mutants has been initiated.Recombinant RDRs were produced transiently in N. Benthamiana, and a biochemical comparative study of RDR2 and RDR6 performed. We found that RDR2, like RDR6, has a de novo polymerase activity on DNA and RNA templates, and for both RDRs we also showed, for the first time, a primer-dependant synthesis of dsRNA from RNA template. These findings provide important new insights into our understanding of the molecular mechanisms of RNA silencing amplification in Arabidopsis.

ARN polymérase ARN-dépendantes

Rdr

RNA silencing

Arabidopsis thaliana

RNA-dependent RNA polymerases

Rdr

RNA silencing

Arabidopsis thaliana

Caractérisation de la phostine : une petite molécule organique de synthèse mimant les symptômes d'une carence en phosphate chez Arabidopsis thaliana / Chracterization of the phostin : a small organic synthetic molecule mimicking phosphate starvation symptoms in Arabidopsis thaliana

Bonnot, Clémence

14 November 2011

La Phostine (PSN ; PHOSphate STarvation response INductor) est une petite molécule organique de synthèse, identifiée dans une chimiothèque par son effet inducteur de l’expression du gène PHT1;4 codant un transporteur de phosphate chez Arabidopsis thaliana. Au cours de cette thèse, j’ai caractérisé l’effet de la PSN chez Arabidopsis et montré que cette drogue induit plusieurs réponses typiques de la carence en phosphate : expression de gènes régulés localement ou à longue distance, accumulation d’anthocyanes et d’amidon, activité des phosphatases acides, inhibition de la croissance des racines. De plus, la PSN provoque une accumulation de phosphate soluble dans les racines.L’étude d’analogues structuraux de la PSN m’a permis d’identifier un motif commun (#10) nécessaire à son activité biologique. Il apparaît que la PSN et ses analogues actifs sont instables à pH acide, ce qui libère le motif #10. Nous montrons que le motif #10 pénètre dans la plante essentiellement par les racines et qu’il ne circule pas des racines vers les feuilles, et faiblement des feuilles vers les racines. L’accumulation de #10 dans les racines expliquerait l’ensemble des effets observés de la PSN et de ses analogues actifs. Nous avons isolé un mutant d’Arabidopsis dont la croissance racinaire résiste à la PSN. Chez ce mutant, la PSN ne provoque plus l’accumulation d’anthocyanes et d’amidon dans les feuilles, ni celle de phosphate dans les racines. En absence de PSN, et sur un milieu de culture partiellement appauvri en phosphate, les feuilles et les racines de ce mutant accumulent plus de phosphate que celles du type sauvage. Chez les plantes, l’homéostasie du phosphate est soumise à une régulation complexe, la caractérisation approfondie de ce mutant apportera de nouveaux éléments pour sa compréhension. / The Phostin (PSN ; PHOSphate STarvation response INductor) is a small organic synthetic molecule identified in a chemical library by its induction effect on PHT1;4 expression, a gene encoding a phosphate transporter in Arabidopsis thaliana. During my PhD, I characterized the effects of PSN in Arabidopsis and shown that this drug induces several phosphate starvation responses: expression of locally or systemically regulated genes, anthocyanin and starch accumulation, acid phosphatase activity, primary root growth inhibition. Moreover, PSN induces inorganic soluble phosphate accumulation in roots.Thanks to PSN’s structural analogues, we identified a common motif (motif #10) necessary to its biological activity. PSN and its analogues are unstable in acidic conditions, leading to the release of #10 motif. We have shown that #10 motif enters the plant mostly by the roots and do not circulate from roots to shoots, and weakly from shoots to roots. The accumulation of #10 motif in the roots explains all the PSN and analogues observed effects. We characterized an Arabidopsis mutant resistant to PSN for its root growth. In this mutant, PSN does not induce anthocyanin or starch accumulation in leaves, neither phosphate in roots. When growing without PSN, on partially phosphate depleted medium, the mutant presents higher phosphate content than the wild type. Phosphate homeostasis is a very complex process in plant, the deep characterization of this mutant will bring new elements for the comprehension of this pathway.

Phosphate

Arabidopsis thaliana

Carence nutritive

Génétique chimique

Phostine

Mutant hipi

Phosphate

Arabidopsis thaliana

Nutrient deficiency

Chemical genetics

Phostine

Hipi mutant

Identificação e caracterização funcional de genes da subfamília Ammonium Transporter 2 (AMT2) de cana-de-açúcar (Saccharum spp.) / Identification and functional characterization of genes from the Ammonium Transporter subfamily 2 (AMT2) in sugarcane (Saccharum spp.)

Koltun, Alessandra

26 August 2016

A cana-de-açúcar (Saccharum spp.) desempenha um papel de grande importância no cenário socioeconômico brasileiro, e representa 42% da matriz energética renovável do país. A expansão da área de cultivo da cana-de-açúcar para solos marginais e a necessidade de manutenção da alta produtividade dessa cultura tem levado à maior aplicação de fertilizantes a base de nitrogênio (N). Tal fato aliado à baixa responsividade da cana-de-açúcar a fertilizantes nitrogenados acarreta altos custos econômicos e ambientais. O amônio é a fonte preferencial de N para essa gramínea, sendo que pouco se conhece sobre a funcionalidade dos transportadores de NH4+ pertencentes à família gênica AMT (AMMONIUM TRANSPORTER). Neste contexto, é relevante esclarecer os mecanismos que influenciam na eficiência do uso de N (NUE), visando reduzir o impacto econômico e ambiental da aplicação dos fertilizantes nitrogenados nos sistemas agrícolas. Dessa forma, esse trabalho teve como objetivo a caracterização molecular e funcional de membros da subfamília AMT2 de cana-de-açúcar através de expressão heteróloga em mutantes de Saccharomyces cerevisiae (cepa 31019b) e Arabidopsis thaliana (qko), defectivos no transporte de amônio. As sequências gênicas e promotoras de ScAMT2;1 e ScAMT3;3A foram identificadas em biblioteca de BAC (bacterial artificial chromosome) de cana-de-açúcar (cultivar \'R570\'). Análises de expressão gênica de ScAMT2;1 e ScAMT3;3A em cana-de-açúcar demonstraram uma expressão preferencial em raízes e em folhas maduras, respectivamente, e que estes genes são regulados de maneira distinta entre si e entre os órgãos, de acordo com o desenvolvimento e com o status de N da planta. A complementação de levedura com os AMT2 de cana-de-açúcar demonstrou que estes genes restauram o crescimento do mutante, sendo que ScAMT2;1 permite maior absorção de amônio; porém o experimento não indicou sensibilidade dessas proteínas ao metilamônio (análogo tóxico ao amônio). Experimentos de localização da expressão órgão/tecido específico em arabidopsis selvagem \'Col-0\', utilizando os promotores de ScAMT2;1 ou ScAMT3;3A fusionados a GUS ou GFP, demonstraram que esses AMTs são preferencialmente expressos na região da endoderme/periciclo e vascular das células das raízes e região vascular da parte aérea, sendo regulados pela disponibilidade e fonte de N. Plantas de arabidopsis qko superexpressando ScAMT2;1, ScAMT3;3A ou transformadas com ScAMT2;1 dirigido por seu promotor endógeno, crescidas in vitro com amônio como fonte exclusiva de N, apresentaram um aumento significativo na produção de biomassa em relação a qko não transformada, principalmente para ScAMT2;1, indicando que essas proteínas são capazes de transportar amônio e complementar o mutante. Dados de influxo e acúmulo de 15N-amônio in vivo em raízes e parte aérea de plantas qko superexpressando ScAMT2;1 ou ScAMT3;3A demonstraram que ScAMT2;1 atua na absorção de amônio pelas raízes e provavelmente do carregamento do xilema, enquanto ScAMT3;3A está possivelmente envolvida na remobilização de amônio na parte aérea, podendo atuar aditivamente na absorção de NH4+ em raízes sob alto amônio. Esses resultados indicam que os transportadores ScAMT2;1 e ScAMT3;3A de cana-de-açúcar são funcionais, atuando com propriedades e funções distintas no transporte de amônio nessa gramínea e de acordo com a disponibilidade de N. / Sugarcane (Saccharum spp.) plays a major role in the Brazilian socio-economic scenario, and represents 42% of renewable energy sources in the country. The expansion of sugarcane cultivation to marginal lands and the requirement to maintain high yields have led to increased application of nitrogen (N) fertilizer. This fact, coupled with the low response of sugarcane to N fertilization, entails high economic and environmental costs. Ammonium is the preferred source of N by this grass; however, little is known about the functionality of NH4+ transporters belonging to the AMT gene family (AMMONIUM TRANSPORTER). In this context, it is important to clarify the mechanisms that affect the nitrogen use efficiency (NUE) in order to reduce the economic and environmental impact of the application of N fertilizers in agricultural systems. Therefore, this study aimed to conduct the molecular and functional characterization of members of the AMT2 subfamily from sugarcane by heterologous expression in mutants of Saccharomyces cerevisiae (strain 31019b) and Arabidopsis thaliana (qko), both defective in ammonium transport. Gene and regulatory region sequences of ScAMT2;1 and ScAMT3;3A were identified in a bacterial artificial chromosome (BAC) library of sugarcane (cultivar \'R570\'). Expression analysis of ScAMT2;1 and ScAMT3;3A in sugarcane showed a preferential expression in roots and mature leaves, respectively, and indicated a distinct expression pattern between genes and organs according to the ontogeny and the N status of the plant. The yeast complementation with AMT2 of sugarcane demonstrated that these genes restore the mutant growth, with ScAMT2;1 enabling higher ammonium absorption; however, the experiment did not indicate sensitivity to methylammonium (toxic ammonium analog). Arabidopsis wild type \'Col-0\' transformed with the promoter region of ScAMT2;1 or ScAMT3;3A directing the expression of GUS or GFP, demonstrated preferential expression in the endodermis/pericycle regions of roots and vascular region in shoots, being regulated by the availability and source of N. Arabidopsis qko overexpressing ScAMT2;1, ScAMT3;3A or transformed with ScAMT2;1 driven by its endogenous promoter, grown in vitro with ammonium as the sole source of nitrogen, showed a significant increase in biomass production compared to untransformed qko, especially for ScAMT2;1, indicating that these proteins are capable of transporting ammonium and complementing the mutant. Data of 15N-ammonium influx and accumulation in vivo in roots and shoots of qko plants overexpressing ScAMT2;1 or ScAMT3;3A showed that ScAMT2;1 acts in ammonium uptake by roots and probably in the xylem loading, while ScAMT3;3A is possibly involved in ammonium remobilization in shoots, and may act additively in the absorption of NH4+ in roots under high ammonium. These results indicate that ScAMT2;1 and ScAMT3;3A from sugarcane are functional, working with distinct properties and functions in ammonium transport according to the availability of N

Arabidopsis thaliana

Arabidopsis thaliana

BAC

BAC

Expressão heteróloga

Heterologous expression

Saccharomyces cerevisiae

Saccharomyces cerevisiae

Identificação e caracterização funcional de genes da subfamília Ammonium Transporter 2 (AMT2) de cana-de-açúcar (Saccharum spp.) / Identification and functional characterization of genes from the Ammonium Transporter subfamily 2 (AMT2) in sugarcane (Saccharum spp.)

Alessandra Koltun

26 August 2016

A cana-de-açúcar (Saccharum spp.) desempenha um papel de grande importância no cenário socioeconômico brasileiro, e representa 42% da matriz energética renovável do país. A expansão da área de cultivo da cana-de-açúcar para solos marginais e a necessidade de manutenção da alta produtividade dessa cultura tem levado à maior aplicação de fertilizantes a base de nitrogênio (N). Tal fato aliado à baixa responsividade da cana-de-açúcar a fertilizantes nitrogenados acarreta altos custos econômicos e ambientais. O amônio é a fonte preferencial de N para essa gramínea, sendo que pouco se conhece sobre a funcionalidade dos transportadores de NH4+ pertencentes à família gênica AMT (AMMONIUM TRANSPORTER). Neste contexto, é relevante esclarecer os mecanismos que influenciam na eficiência do uso de N (NUE), visando reduzir o impacto econômico e ambiental da aplicação dos fertilizantes nitrogenados nos sistemas agrícolas. Dessa forma, esse trabalho teve como objetivo a caracterização molecular e funcional de membros da subfamília AMT2 de cana-de-açúcar através de expressão heteróloga em mutantes de Saccharomyces cerevisiae (cepa 31019b) e Arabidopsis thaliana (qko), defectivos no transporte de amônio. As sequências gênicas e promotoras de ScAMT2;1 e ScAMT3;3A foram identificadas em biblioteca de BAC (bacterial artificial chromosome) de cana-de-açúcar (cultivar \'R570\'). Análises de expressão gênica de ScAMT2;1 e ScAMT3;3A em cana-de-açúcar demonstraram uma expressão preferencial em raízes e em folhas maduras, respectivamente, e que estes genes são regulados de maneira distinta entre si e entre os órgãos, de acordo com o desenvolvimento e com o status de N da planta. A complementação de levedura com os AMT2 de cana-de-açúcar demonstrou que estes genes restauram o crescimento do mutante, sendo que ScAMT2;1 permite maior absorção de amônio; porém o experimento não indicou sensibilidade dessas proteínas ao metilamônio (análogo tóxico ao amônio). Experimentos de localização da expressão órgão/tecido específico em arabidopsis selvagem \'Col-0\', utilizando os promotores de ScAMT2;1 ou ScAMT3;3A fusionados a GUS ou GFP, demonstraram que esses AMTs são preferencialmente expressos na região da endoderme/periciclo e vascular das células das raízes e região vascular da parte aérea, sendo regulados pela disponibilidade e fonte de N. Plantas de arabidopsis qko superexpressando ScAMT2;1, ScAMT3;3A ou transformadas com ScAMT2;1 dirigido por seu promotor endógeno, crescidas in vitro com amônio como fonte exclusiva de N, apresentaram um aumento significativo na produção de biomassa em relação a qko não transformada, principalmente para ScAMT2;1, indicando que essas proteínas são capazes de transportar amônio e complementar o mutante. Dados de influxo e acúmulo de 15N-amônio in vivo em raízes e parte aérea de plantas qko superexpressando ScAMT2;1 ou ScAMT3;3A demonstraram que ScAMT2;1 atua na absorção de amônio pelas raízes e provavelmente do carregamento do xilema, enquanto ScAMT3;3A está possivelmente envolvida na remobilização de amônio na parte aérea, podendo atuar aditivamente na absorção de NH4+ em raízes sob alto amônio. Esses resultados indicam que os transportadores ScAMT2;1 e ScAMT3;3A de cana-de-açúcar são funcionais, atuando com propriedades e funções distintas no transporte de amônio nessa gramínea e de acordo com a disponibilidade de N. / Sugarcane (Saccharum spp.) plays a major role in the Brazilian socio-economic scenario, and represents 42% of renewable energy sources in the country. The expansion of sugarcane cultivation to marginal lands and the requirement to maintain high yields have led to increased application of nitrogen (N) fertilizer. This fact, coupled with the low response of sugarcane to N fertilization, entails high economic and environmental costs. Ammonium is the preferred source of N by this grass; however, little is known about the functionality of NH4+ transporters belonging to the AMT gene family (AMMONIUM TRANSPORTER). In this context, it is important to clarify the mechanisms that affect the nitrogen use efficiency (NUE) in order to reduce the economic and environmental impact of the application of N fertilizers in agricultural systems. Therefore, this study aimed to conduct the molecular and functional characterization of members of the AMT2 subfamily from sugarcane by heterologous expression in mutants of Saccharomyces cerevisiae (strain 31019b) and Arabidopsis thaliana (qko), both defective in ammonium transport. Gene and regulatory region sequences of ScAMT2;1 and ScAMT3;3A were identified in a bacterial artificial chromosome (BAC) library of sugarcane (cultivar \'R570\'). Expression analysis of ScAMT2;1 and ScAMT3;3A in sugarcane showed a preferential expression in roots and mature leaves, respectively, and indicated a distinct expression pattern between genes and organs according to the ontogeny and the N status of the plant. The yeast complementation with AMT2 of sugarcane demonstrated that these genes restore the mutant growth, with ScAMT2;1 enabling higher ammonium absorption; however, the experiment did not indicate sensitivity to methylammonium (toxic ammonium analog). Arabidopsis wild type \'Col-0\' transformed with the promoter region of ScAMT2;1 or ScAMT3;3A directing the expression of GUS or GFP, demonstrated preferential expression in the endodermis/pericycle regions of roots and vascular region in shoots, being regulated by the availability and source of N. Arabidopsis qko overexpressing ScAMT2;1, ScAMT3;3A or transformed with ScAMT2;1 driven by its endogenous promoter, grown in vitro with ammonium as the sole source of nitrogen, showed a significant increase in biomass production compared to untransformed qko, especially for ScAMT2;1, indicating that these proteins are capable of transporting ammonium and complementing the mutant. Data of 15N-ammonium influx and accumulation in vivo in roots and shoots of qko plants overexpressing ScAMT2;1 or ScAMT3;3A showed that ScAMT2;1 acts in ammonium uptake by roots and probably in the xylem loading, while ScAMT3;3A is possibly involved in ammonium remobilization in shoots, and may act additively in the absorption of NH4+ in roots under high ammonium. These results indicate that ScAMT2;1 and ScAMT3;3A from sugarcane are functional, working with distinct properties and functions in ammonium transport according to the availability of N

Arabidopsis thaliana

BAC

Expressão heteróloga

Saccharomyces cerevisiae

Arabidopsis thaliana

BAC

Heterologous expression

Saccharomyces cerevisiae

Clonagem e caracterização do gene PUMILIO de Arabidopsis thaliana / Cloning and characterization of the gene from Arabidopsis thaliana PUMILIO

Favaro, Elaine Cristina

25 February 2002

Proteínas que se ligam a RNAs geralmente regulam estabilidade, localização e tradução de mensageiros por interação com seqüências específicas na região 3 não traduzida. A proteína PUMILIO foi descrita pela primeira vez em Drosophila, apresentando a função de controlar a tradução de mensageiros alvo durante o desenvolvimento. Homólogos podem ser encontrados em outras espécies filogeneticamente distantes com funções similares. O seqüenciamento do genoma de Arabidopsis thaliana indicou a presença de quatro genes que codificam homólogos ao PUMILIO de Drosophila. Três deles estão no cromossomo II (APUM-1, 2 e 3), com alto grau de identidade e situados muito próximos uns dos outros. A terceira cópia está no cromossomo IV (APUM-4) e sua seqüência tem menor similaridade em relação aos três anteriores. Neste trabalho, foi clonado e caracterizado APUM-2. Ensaios de northern blot e RT-PCR indicaram que o mensageiro de Apum-2 pode ser encontrado em amostras de raiz, caule, folha, flores e frutos. Entretanto, sistemas repórteres, APUM-2::GUS e APUM-2::GFP, foram introduzidos no vegetal e a expressão foi observada nos ápices do caule e raízes, especificamente nas regiões meristemáticas. Também foram feitas construção para ensaios de genética reversa e as plantas contendo construções constitutivas (35S::APUM-2) se desenvolveram sem dominância apical e com grande quantidade de ramos, folhas e raízes secundárias, mostrando perturbações nos meristemas. Os resultados obtidos sugerem que APUM-2 possui papel relevante durante o desenvolvimento meristemático, possivelmente através de interações com mRNAs. / RNA-binding proteins often regulate the stability, localization, and translation of mRNAs by interaction with specific motifs in the 3-UTR. The PUMILIO protein from Drosophila was shown to control translation of specific mRNAs during development. PUMILIO homologs were found in several species and constitute the PUF family. The Arabidopsis thaliana sequencing project revealed four genes homolougs to PUMILIO. Three are situated in chromosome II (APUM-1, 2, and 3) that are nearly identical among themselves, and that contain a region that is 52% homologous to the PUMILIO. RNA-binding domain. The fourth is in chromosome IV (APUM-4), and shows low similarity to the other three. In this work, we characterized APUM-2 in further detail. Northern blots indicated that Apum-2 is expressed in shoot and root apices. Reporter transgenic plants were made that contained either APUM-2::GUS or Apum2::GFP constructs. Reporter gene expression confirmed that APUM-2 is active in shoot and root apices, specifically in the meristematic regions. Finally transgenic plants containing the 35S::APUM-2 construct were created. Constitutive APUM-2 expression resulted in plants with no apical dominance and a high number of leaves, stems and lateral roots. These results suggest that APUM-2 plays an important role during meristem development, possibly through a mRNA interaction.

Arabidopsis thaliana

Arabidopsis thaliana

Clonagem

Cloning

Desenvolvimento vegetal

Meristem

Meristemas

Plant proteins (study)

Proteínas de plantas (estudo)

Vegetable development

Thi1, uma proteína envolvida na síntese de tiamina em Arabidopsis thaliana: análises estruturais do mutante Thi1 (A140V) / Thi1, a protein involved on biosynthesis of thiamin in Arabidopsis thaliana: structural analysis of Thi1(A140V) mutant

Garcia, Assuero Faria

12 August 2011

A forma ativa da vitamina B1, tiamina pirofosfato (TPP), é um cofator indispensável para certas enzimas que atuam no metabolismo de carboidratos e aminoácidos. Sua biossíntese se dá pela formação independente de suas partes componentes pirimidina e tiazol. Em procariotos a via de síntese para vitamina B1 já foi esclarecida, entretanto em eucariotos ainda existem ainda algumas lacunas a serem preenchidas. Em Arabidopsis thaliana a proteína Thi1 é possivelmente a responsável pela síntese do motivo tiazólico, uma vez que um composto relacionado a TPP foi encontrado em sua estrutura. Neste trabalho, Thi1 e seu mutante natural Thi1(A140V), o qual é responsável pela auxotrofia para tiamina numa linhagem mutante de A. thaliana, foram estudados com intuito de verificar a influência da mutação pontual na estrutura e na atividade de Thi1. As proteínas foram produzidas em E. coli e análises biofísicas usando anisotropia de fluorescência e Dicroísmo Circular (CD) mostraram diferenças consideráveis na estabilidade protéica. Estudos de desnaturação mostraram diferenças na temperatura de transição (Tm), de cerca de 4 ºC maior para Thi1, e na concentração de guanidina na qual metade das proteínas estavam desnaturadas, de 0,42 M para Thi1 e 0,24 M para Thi1(A140V). Os dados de anisotropia de fluorescência obtidos a partir da desnaturação térmica também confirmaram a maior instabilidade de Thi1(A140V) frente a Thi1. Para avaliar a presença e caracterizar o provável precursor de TPP em Thi1(A140V), foram também realizados ensaios de absorção, CD e infra-vermelho dos ligantes intrínsecos. Os resultados destas análises mostraram que as moléculas poderiam apresentar diferenças em seus grupos constituintes. Entretanto, os experimentos complementares de Ressonância Magnética Nuclear (RMN 1D 1H e 2D TOCSY) revelaram que as diferenças observadas nas amostras dos ligantes, provenientes de Thi1 e de Thi1(A140V), tratavam-se na verdade de diferenças nas proporções de quatro populações distintas de compostos, compondo um pool de ligantes. Na amostra proveniente de Thi1(A140V), a população dominante correspondeu à molécula de adenosina difosfato, ADP. Ainda, embora em ambas as amostras o ADT tenha sido encontrado, aquela derivada de Thi1(A140V) apresentou uma população significativamente menor deste composto. Concluindo, os resultados demonstraram que a mutação A140V levou a uma maior instabilidade conformacional em Thi1 e, além disso, a presença de quantidades reduzidas de ADT em Thi1(A140V) sugerem que esta alteração tenha contribuído de alguma forma para a redução de sua atividade. / The active form of vitamin B1, Thiamine pyrophosphate (TPP), is an indispensable cofactor for some enzymes that act on carbohydrates and amino acids metabolism. Its biosynthesis requires the independent formation of its compounds, pyrimidine and thiazole. In prokaryotes, the vitamin B1 biosynthetic way has already been elucidated, but in eukaryotes there are some gaps to be filled. In Arabidopsis thaliana, the Thi1 protein is possibly responsible for the synthesis of the thiazole moiety, since a related compound to TPP was found in its structure. In this work, we have investigated Thi1 and its natural mutant Thi1(A140V), which is responsible for the thiamin auxotrophy in A. thaliana mutant line, to identify the role this mutation plays in the structure and activity of Thi1. The proteins were produced in E. coli and the results of biophysical analysis using fluorescence and Circular Dichroism (CD) showed considerable differences in the protein stability. Thermal and chemical unfolding studies have shown a difference in the melting temperature (around 4 ºC higher for Thi1) and concentration of guanidine at which half of the protein had unfolded (0,42 M for Thi1 and 0,24 M for Thi1(A140V)). The fluorescence anisotropy data obtained from thermal unfolding showed Thi1(A140V) is more unstable compared to Thi1. We have also carried out tests of absorption, CD and infra-red to assess the presence and to characterize the possible precursor of TPP in Thi1 (A140V). The results showed that the ligants could have different compositions. However, complementary results from NMR (1D 1H e 2D TOCSY) revealed that the difference observed in the ligant samples from both proteins were actually related to the proportion of four distinct compound population, representing a ligant pool. In the sample from Thi1(A140V), the dominant population corresponded to ADP. Besides, although both samples contained ADT, it was significantly less abundant in that one derived from Thi1(A140V). Concluding, the results demonstrated that the A140V mutation leaded to a more unstable conformation of Thi1 and, additionally, the presence of smaller amounts of ADT in Thi1(A140V) suggests this change might have contributed to reducing its activity.

Arabidopsis thaliana

Arabidopsis thaliana

Circular dichroism

Dicroísmo circular

Fluorescence

Fluorescência

Thiamine pyrophosphate

Thiazole Synthase (Thi1)

Tiamina

Tiazol Sintase (Thi1)

A functional and genetic analysis of novel signaling molecules regulating embryo surface formation in Arabidopsis thaliana / Analyse fonctionnelle et génétique de nouvelles molécules de signalisation impliquées dans la régulation de la formation de la surface de l’embryon d’Arabidopsis thaliana

Moussu, Steven

16 December 2016

Le développement de la graine est une étape cruciale du cycle de vie des Angiospermes. La graine est composée de trois compartiments : (1) Le tégument, assurant un rôle protecteur, (2) l’albumen, qui a un rôle principalement nourricier pour (3) l’embryon, qui donnera la future plante. Ainsi, ces trois tissus se développent de concert pour former une graine viable. Une telle coordination présuppose que les différents compartiments communiquent entre eux. Dans ce contexte, j’ai étudié les gènes impliqués dans la formation de la cuticule embryonnaire, une structure hydrophobe recouvrant la plante et essentielle pour limiter les pertes d’eau, assurant ainsi sa survie. Au début de ma thèse, différents gènes étaient déjà connus, certains spécifiques de l’embryon, et d’autres spécifiques de l’albumen, renforçant l’idée de l’existence d’une communication moléculaire entre les deux tissus. Côté albumen, le facteur de transcription ZOU contrôle l’expression d’ALE1, une protéase. Côté embryon, deux récepteurs, GSO1 et GSO2, sont impliqués. L’étude de l’interaction génétique de ces différents gènes a permis de prouver leur appartenance à la même voie de signalisation. L’identité de ces gènes nous a amené à supposer l’existence d’un ou plusieurs peptides agissant comme messagers entre l’embryon et l’albumen. Ainsi, mes travaux de thèse ont permis de caractériser de nouveaux gènes impliqués dans ce processus, ainsi que certaines propriétés de la cuticule. Le principal est CERBERUS, dont l’expression est contrôlée par ZOU, un peptide sécrété par l’albumen qui est nécessaire pour la mise en place d’une cuticule fonctionnelle et la mise en place d’une structure non encore décrite à ce jour, la gaine embryonnaire. Un nouveau rôle pour GSO1 et GSO2 a aussi été démontré. Des résultats préliminaires suggèrent que TPST, une enzyme impliquées dans la sulfation des peptides, est impliquée dans la voie de signalisation étudiée. Enfin, mes travaux ont identifiés un autre gène, FRIABLE1, qui est aussi essentiel à la mise en place de la cuticule et joue dans la même voie de signalisation. Les découvertes associées à mes travaux de thèse ont permis de compléter et d’approfondir les connaissances sur les gènes impliqués dans la formation de la surface de l’embryon chez Arabidopsis. / Seed development is a crucial step in Angiosperms life cycle. The seed is composed of three distinct compartments: (1) The testa, ensuring a protective function, (2) the endosperm, which plays a key nutritive role supporting (3) the embryo, the fate of which is to become the future plant. These three tissues develop concomitantly to form a viable seed. Such developmental coordination necessitates the involvement of communication between the compartments. In this context, I have studied genes involved in the establishment of the embryonic cuticle, a hydrophobic structure that surrounds the embryo, plays an essential post-germination function in regulating water loss and is thus critical for plant survival. At the beginning of my PhD, several proteins were known to be involved in the process of cuticle establishment, some of which were expressed in the endosperm and others in the embryo, hinting at the existence of molecular communication between the two tissues. On the endosperm side, the transcription factor ZOU controls the expression of ALE1, a subtilisin-like serine protease. On the embryo side, two receptors, GSO1 and GSO2, are involved. Genetic interaction between the genes encoding these proteins had confirmed their involvement the same signalling pathway. The molecular identities of these proteins led us to propose the existence of one or more unidentified peptides acting as messengers between the embryo and the endosperm. My research has allowed the characterization of novel proteins involved in the process of embryonic surface formation. The principal subject of my research has been CERBERUS, a peptide produced in the endosperm, the expression of which is controlled by ZOU, and which is necessary both for the formation of an intact embryonic cuticle and the production of a previously uncharacterised structure, the embryo sheath. I have demonstrated novel roles for GSO1 and GSO2 in embryo sheath deposition. Furthermore, I have generated preliminary data suggesting that a protein involved in peptide sulfation, TPST, is involved in the GSO1 GSO2 signalling pathway. Finally, I have shown that another protein involved in posttranslational protein modification, FRIABLE1 is involved in this same pathway. My results have advanced knowledge of the molecular mechanisms controlling embryonic surface formation in Arabidopsis.

Développement

Graine

Cuticule

Signalisation

Peptide

Arabidopsis thaliana

Embryon

Albumen

Development

Seed

Cuticle

Signalling

Peptide

Arabidopsis thaliana

Embryo

Endopserm