Identificação de genes diferencialmente expressos em árvores de Eucalyptus grandis susceptíveis e resistentes à Puccinia psidii / Identification of differentially expressed genes in susceptivel and resistant Eucalyptus grandis trees exposed to Puccinia psidii

Guillermo Rafael Salvatierra

29 May 2006

A atividade florestal apresenta-se como um vetor de desenvolvimento social, ambiental e econômico no Brasil. Em 2004 as exportações ligadas ao setor renderam US$ 7 bilhões e contribuíram com US$ 5,5 bilhões em impostos. No mesmo ano, no Brasil, dos 6 milhões de hectares de reflorestamento comercial, mais de 50% dos hectares são ocupados por eucalipto. Esta cultura pode ser utilizada para diversas funções, desde à produção de papel e celulose, até a produção de carvão vegetal. Mas a produtividade desta cultura atualmente tem uma série de fatores limitantes. Destes fatores, um dos mais severos é uma doença denominada ferrugem, causada pelo fungo Puccinia psiddii Winter. Este patógeno entre tanto, não é conhecido nos centros de origem do gênero Eucalyptus, mas, utiliza como hospedeiros vários gêneros das Mirtáceas, infectando folhas, flores e frutos em desenvolvimento. O controle da doença é normalmente realizado mediante o uso de fungicidas. Porém, a utilização de plantas resistentes é o método mais aconselhável por diversos motivos, como o baixo custo, a praticidade e o menor impacto ambiental. Neste trabalho a metodologia do SAGE - Serial Analysis of Gene Expression foi utilizada, para a análise da expressão gênica uma vez que permite detectar e quantificar, de maneira global, a expressão de genes conhecidos e desconhecidos, envolvidos no processo de resistência à ferrugem. Neste trabalho analisou-se a expressão do conjunto de genes diferencialmente expressos e 200 genes sem diferenças no padrão de expressão, em Eucalyptus grandis infectado com Puccinia psidii. Utilizou-se para esta análise, indivíduos susceptíveis e resistentes à infecção por Puccinia psidii Winter. A população amostrada constituída por meios irmãos, apresentava segregação para o carácter de resistência à ferrugem. Os resultados produzidos permitiram identificar 421 genes com expressão diferencial (p ≤ 0,05) nos dois fenótipos. Vários destes genes estavam relacionados a diversos mecanismos de defesa da planta, tais como genes envolvidos na formação de barreiras físicas e na resposta hipersensível, resistência sistêmica adquirida, bem como genes relacionados à polarização celular e resposta ao estresse oxidativo. Os dados em conjunto, corroboram a idéia de que são vários os mecanismos que atuam simultaneamente produzindo o fenótipo resistente. Estes genes apresentam-se para serem utilizados futuramente como marcadores moleculares na seleção de indivíduos resistentes, em cruzamentos naturais ou dirigidos e como fonte de genes para experimentos de transformação em estudos mais profundos de fitopatogênese. / In Brazil the forest activities represent a vector for social, ambiental and economic development. In 2004 the exportations produced US$ 7 billions and contributed with US$ 5,5 billion in taxes. In the same year, in Brasil, of 6 million hectares of commercial reforestation, around 50% is occupied by eucalyptus. This crop can be used as the raw material for several industrial processes, from cellulose and paper production to vegetable charcoal production. However, eucalyptus productivity has several limiting factors. One of the most severe diseases is called rust, caused by the fungus Puccinia psiddii Winter. This pathogen is unknown in the Eucalyptus center of origin; however, it has several Myrtaceae genera as its host, infecting leaves, flowers and developing fruits. Rust management normally involves the use of fungicides, but the use of resistant plants is a much better alternative due the lower costs and minimal ambient impact. In the current study SAGE - Serial Analysis of Gene Expression was used for gene expression analysis because it is a quantitative genome-wide method and that obtains expression profiles from known and unknown genes involved in the rust resistant process. This thesis analyzed the expression profile of the differentially expressed genes and 200 genes without significant statistical differences in their expression patterns, in Eucalyptus grandis infected with Puccinia psidii. For this analysis we used susceptible and resistant individuals to Puccinia psidii Winter infection taken from a population half siblings, which showed segregation for fust resistance. The results indicated 421 genes with differential expression (p ≤ 0.05), 239 were preferentially expressed in the susceptible library and 232 in the resistant. Several of these genes were associated with plant defense mechanisms, such as genes involved in formation of physical barriers, hypersensitive response, systemic adquired resistance, genes related to cellular polarization and oxidative stress responses. All the data support the idea that not one but several mechanisms are acting at the same time producing the resistant phenotype. These genes are future candidates for molecular markers useful in the selection of resistant individuals in breeding programs and a source of genes for transformation experiments or as molecular tools to dissect the phytopathogenic process.

eucalipto

expressão gênica

ferrugem – doença de planta

fungo fitopatogênico

genes

resistência genética vegetal

Eucalyptus grandis

Puccinia psidii

rust

SAGE

transcriptional profile

TRANSCRIPTOMIC ANALYSES OF <em>CATHATRANTHUS ROSEUS</em> HAIRY ROOTS OVEREXPRESSING CRMYC2 AND ORCA3 AND ROLES OF CROSS-FAMILY TRANSCRIPTION FACTOR INTERACTION IN TERPENOID INDOLE ALKALOID BIOSYNTHESIS

Sui, Xueyi

01 January 2017

Catharanthus roseus (Madagascar periwinkle), is a well-known medicinal plant that produces a vast array of terpenoid indole alkaloids (TIAs), including two anticancer compounds vinblastine and vincristine. Industrial scale production of TIAs is hampered by the difficulties of total chemical synthesis of these compounds and the fragmented knowledge on TIA pathway. Transcriptional regulation of the TIA biosynthetic pathway has not been thoroughly investigated in Catharanthus and only a few structural genes have been identified as the targets of two master regulators: the basic helix-loop-helix (bHLH) transcription factor (TF) CrMYC2 and APETALA2/ETHYLENE RESPONSE FACTOR (AP2/ERF), ORCA3. Next generation sequencing (NGS) has been used as a tool to isolate novel genes encoding enzymes and regulators of TIA pathway in Catharanthus. In this dissertation, I have performed the transcriptomic analysis of transgenic Catharanthus hairy roots ectopically expressing a dominant repressive form of CrMYC2 or ORCA3 in order to understand their potential impact on the TIA transcriptional regulatory network and to identify and characterize novel target(s) of these two key TFs. MYC2 acts as regulatory hub involved in diverse aspects of plant growth, development, and specialized metabolite biosynthesis by coordinating the crosstalk among different phytohormone signals. CrMYC2 was initially identified in Catharanthus as a regulator of ORCA3. CrMYC2 transactivates ORCA3 by binding to the T/G-box in jasmonate-responsive element (JRE) of ORCA3 promoter. RNA interference (RNAi) mediated knockdown of CrMYC2 strongly reduced TIA accumulation in Catharanthus cell suspension culture. However, the potential influence of CrMYC2 on the expression of other regulatory and structural genes in the TIA pathway remains poorly understood. Transcriptomic analyses revealed that CrMYC2 plays an essential role in JA-induced gene expression and the differentially expressed genes are involved in diverse aspects of growth and development as well as abiotic and biotic stress responses in Catharanthus. Additionally, the expression of genes related to auxin, ethylene, and abscisic acid signaling cascades were affected in hairy roots with modified CrMYC2 expression, suggesting this TF mediates cross-talk between JA and other phytohormones. Surprisingly, overexpression of CrMYC2 resulted in repressed expression of TIA pathway genes in transgenic hairy roots. Expressions of key activators of indole and iridoid pathway were downregulated whereas expression of repressors were upregulated in CrMYC2 hairy roots. Activators (i.e. CrMYC2 and ORCA3) and repressors (i.e. G-box binding factors; GBFs) have been isolated and characterized for their role in regulation of TIA pathway. However, the interconnection between those regulators and the underlying molecular mechanism has not been throughly studied. I identified (i) the interaction of CrMYC2 with CrGBFs and (ii) how this cross-family transcription factor interactions fine-tunes TIA biosynthesis in Catharanthus. The expression profiles of CrMYC2 and CrGBFs were highly correlated in different tissues and in response JA. Moreover, CrMYC2 interacted with CrGBF1 and CrGBF2 in both yeast and plant cells. CrGBF1 and CrGBF2 could form homo- and hetero-dimer which bound T/G-box elements of TIA pathway gene promoters. In plant cells, CrGBF1 antagonizes the activity of CrMYC2 on target promoters in a dosage dependent-manner. Similarly, CrMYC2 can overcome CrGBF1-mediated repression of target promoters in a dosage dependent manner. ORCA3 is another major regulator of TIA biosynthesis in Catharanthus. The transcriptomic analysis of ORCA3 transgenic hairy roots revealed (i) the effect of ORCA3 on newly identified TIA pathway biosynthetic enzymes; (ii) identify the potential effect of ORCA3 on three biological processes: abiotic stress response, plant secondary metabolic process, and response to hormonal stimulus; and (iii) the identification of potential regulator(s) of TIA biosynthesis using ORCA3 based co-expression analysis.

Transcriptomic analysis

CrMYC2

ORCA3

Transcriptional regulation

Terpenoid indole alkaloid pathway

Catharanthus roseus

Bioinformatics

Biotechnology

Molecular Biology

Molecular Genetics

Rôle de la transcription pervasive antisens chez Saccharomyces cerevisiae dans la régulation de l'expression des gènes / Role of pervasive transcription in gene expression regulation in Saccharomyces cerevisiae

Chery, Alicia

04 October 2017

L'expression des gènes est finement régulée dans la cellule et soumise à de multiples contrôles-qualité. Cette régulation intervient à différents niveaux, de façon à garantir une synthèse efficace des produits fonctionnels de l'expression génique, et pour assurer une adaptation à un changement environnemental. Notamment, les régulations transcriptionnelles sont cruciales pour contrôler la cinétique et le niveau d'expression des gènes. La transcription pervasive est une transcription généralisée non-codante et instable qui fut révélée chez la levure Saccharomyces cerevisiae. Bien que son potentiel régulateur ait été démontré de façon ponctuelle, la question de sa fonctionnalité globale restait ouverte. Lors de ma thèse, j'ai pu montrer l'existence de phénomènes multiples d'interférence transcriptionnelle liés à la transcription pervasive, pour co-réguler un ensemble de gènes entre la phase exponentielle et la quiescence. En effet, la transcription non-codante en antisens des gènes concernés conduit à leur répression, dans des conditions où ils ne doivent pas être exprimés. Le mécanisme de répression fait intervenir des modifications de la chromatine. La levure bourgeonnante, dépourvue de la machinerie d'ARN interférence, présente donc un système fin de régulation de l'expression génique utilisant la transcription pervasive. / In the cell, gene expression is finely tuned and is submitted to different quality-controls. Gene are regulated at different expression levels in order to guarantee a proper synthesis of functional products, and to ensure an optimal adaptation to environmental changes. In particular, transcriptional regulations are critical for gene expression level and kinetics.Pervasive transcription, defined as a generalized non-coding and unstable transcription, was discovered in the yeast Saccharomyces cerevisiae. Although its regulatory potential was punctually shown, the question of its global functionality still remained. During my PhD, I could show the existence of numerous transcriptional interference mechanisms involved in the co-regulation of a group of genes between exponential phase and quiescence. Indeed, non-coding transcription in antisense to genes promoter leads to its repression in conditions where they have to be switched off. The repression mechanism is allowed by chromatin modifications.Hence, budding yeast that lacks RNA interference machinery has developed a fine regulation system using pervasive transcription.

Transcription non-codante

Long ARN non-codant

Transcription antisens

Interférence transcriptionnelle

Chromatine

Transcription génique

Pervasive transcription

Transcriptional interference

Chromatin

572.8

Etude structurale du co-activateur transcriptionnel SAGA et de son module d'acétylation des histones / Structural study of transcriptional coactivator SAGA and its histone acetylation module

Sharov, Grigory

18 September 2015

L’initiation de la transcription chez les eucaryotes nécessite le recrutement de l'ARN polymérase II (Pol II) et des facteurs de transcription généraux sur les promoteurs de gènes formant le complexe de préinitiation (PIC). Des activateurs se lient en amont du promoteur et stimulent l’ouverture de la chromatine et la formation du PIC en recrutant des complexes coactivateurs. SAGA est un tel coactivateur, conservé chez les eucaryotes, connu pour modifier les histones de tous les gènes et impliqué dans la transcription par Pol II. Dans ce travail, j’ai analysé l'organisation moléculaire de SAGA par microscopie électronique. J'ai (i) étudié l'architecture et les interactions des sous unités du module d’acétylation des histones et l’ai localisé dans SAGA; (ii) obtenu la première carte cryo-EM du complexe SAGA chez la levure et analysé sa flexibilité; (iii) défini le site d'interaction entre TBP et SAGA et montré que le complexe subit un changement conformationnel lors de cette liaison. / Transcription initiation in eukaryotes requires the recruitment of RNA polymerase II (Pol II) and general transcription factors to the promoters of protein coding genes in order to form a PreInitiation Complex (PIC). Sequence specific activators bind up stream of the promoter, stimulating chromatin opening and PIC formation via recruitment of coactivator complexes. SAGA is such a coactivator, conserved in all eukaryotes, known to modify the histones on all expressed genes in yeast and human and involved in Pol II transcription. In this work I have analyzed SAGA’s molecular organization mostly by electron microscopy. I have (i) studied the architecture and sub unit interactions of SAGA histone acetylation (HAT) module and localized it in the full SAGA complex; (ii) obtained the first cryo-EM map of yeast SAGA and analyzed its flexibility; (iii) defined the interaction site of SAGA with TBP protein and shown that the complex under goes a large conformational change upon TBP binding.

Coactivateur de transcription

SAGA

Microscopie électronique

Biologie structurale

Acétylation des histones

Transcriptional coactivator

SAGA

Electron microscopy

Structural biology

Histone acetylation

571.4

572.8

Role of the post-transcriptional regulators Pumilio1 and Pumilio2 in murine hematopoietic stem cells / Rôle des régulateurs post-transcriptionnels Pumilio 1 et Pumilio 2 dans les cellules souches hématopoïétiques murines

Michelet, Fabio

07 November 2013

Les propriétés centrales des cellules souches sont la pluripotence et la capacité d'auto-renouvellement. Les cellules souches hématopoïétiques (CSHs) sont dotées de ces caractéristiques qui leur permettent de générer toutes les cellules du compartiment hématopoïétique, tout en maintenant en parallèle leur compartiment. Nous menons des approches visant à amplifier ex vivo les CSHs en les activant par HOXB4 exogène (CSHs humaines) ou via la signalisation Notch/DLL-4 (CSHs murines). Or deux analyses transcriptomiques indépendantes de ces deux modes d'activation ont de manière étonnante convergé sur une augmentation de l'expression de deux gènes jamais identifiés auparavant comme étant impliqués dans le maintien des CSHs : Pumilio1 (Pum1) et Pumilio2 (Pum2). Pum1 et Pum2 sont des régulateurs post-transcriptionnels appartenant à la famille Pumilio-FBF (PUF) des protéines liant l'ARN. Bien qu'il ait été établi que le rôle princeps de ces protéines PUF est de soutenir la prolifération des cellules souches chez les Invertébrés, jusqu'à présent on ne sait rien du rôle de Pum1 et Pum2 dans les CSH humaines et murines.Pour toutes ces raisons, nous avons étudié le rôle et les mécanismes d'action de Pum1 et Pum2 dans les CSH murines et humaines en utilisant l'interférence ARN (ARNi). L'invalidation de Pum1 ou de Pum2 dans les CSHs murines conduit à une réduction de l'expansion et du potentiel clonogénique ex vivo, associée à une apoptose accrue et l'arrêt du cycle cellulaire en phase G0/G1. L'invalidation concomitante de Pum1 et Pum2 majore ces effets ce qui suggère un effet coopératif entre les deux protéines. L'expansion et le potentiel clonogénique des CSH invalidées pour Pum1 sont restaurés suite à l'expression forcée de Pum1 (insensible au shRNA utilisé), validant ainsi la spécificité de nos shRNAs. Par contre la surexpression de Pum1 dans les CSHs invalidées pour Pum2 ne restaure pas leurs fonctions, soulignant le rôle non redondant de chaque protéine. En outre, lorsque les CSHs invalidées pour Pum1 ou Pum2 sont inoculées à des souris irradiées létalement de suivre le potentiel hématopoïétique à long terme, seules quelques rares cellules de la moelle osseuse issues des CSH KD pour Pum1 ou Pum2 sont mises en évidence après 4 mois de reconstitution, contrairement aux CSH contrôles. Des résultats identiques ont été obtenus en invalidant Pum1 ou Pum2 dans les CSH humaines.En conclusion, nos résultats démontrent l'implication des facteurs Pumilio dans le maintien du potentiel souche, l'expansion et la survie des CSHs murines et humaines. L'identification des facteurs Pumilio et de leurs cibles comme nouveaux régulateurs des CSHs permettra d'envisager de nouveaux outils en vue de perspectives thérapeutiques. / The central properties of stem cells are the pluripotency and the capacity of self-renewal. Hematopoietic stem cells (HSCs) posses such common features that allows them to generate all the cells of the hematopoietic compartments, maintaining in the same time the HSC pool. We develop approaches focused on ex vivo HSC expansion through activation by exogenous HOXB4 (human HSCs) or Notch/Dll-4 ligand (murine HSCs). Two independent transcriptomic analyses surprisingly converged toward an increased expression of two genes never identified sofar as crucial for HSC functions: Pumilio1 (Pum1) and Pumilio2 (Pum2). Pum1 and Pum2 are posttranscriptional regulators belonging to the Pumilio-FBF (PUF) family of RNA-binding proteins. Although it was established that the primordial role of PUF proteins is to sustain mitotic proliferation of stem cells in Invertebrates, so far nothing is known about the role of Pum1 and Pum2 in human and murine HSCs.For these reasons, we have investigated the roles and mechanisms of action of Pum1 and Pum2 in murine and human HSCs through shRNA strategy. Pum1 and Pum2 knockdown (KD) in murine HSCs led to a decreased HSC expansion and clonogenic potential ex vivo, associated with an increased apoptosis and a cell cycle arrest in G0/G1 phase. KD of both Pum1 and Pum2 enhanced these effects, suggesting a cooperative effect. Expansion and clonogenic potential of KD Pum1 HSCs were rescued by enforced expression of Pum1 (insensitive to our shRNA), thus validating the specificity of our shRNA. Enforced expression of Pum1 could not rescue the functions of Pum2 KD HSCs, highlighting the non-redundant role of these proteins. Furthermore, when Pum1 or Pum2 KD HSCs were inoculated into lethally irradiated mice to follow the long-term hematopoietic potential, only rare bone marrow cells derived from Pum1 and Pum2 KD HSCs were evidenced after 4 months, contrary to control HSCs. Identical results were obtained with human Pum1 or Pum2 KD HSCs.In conclusion, our results demonstrate the involvement of Pumilio factors in stemness maintenance, expansion and survival of murine and human HSCs. Identification of Pumilio factors and their targets as new regulators of HSCs expansion will allow consider them as new tools for therapeutic perspectives.

Cellules souches hématopoïétiques

Pumilio

Stem cells

Hematopoietic stem cells

HSC

Pumilio

Pum1

Pum2

Notch

Delta4

Post transcriptional regulation

616.027 74

NF1 tumor suppressor in skin:expression in response to tissue trauma and in cellular differentiation

Ylä-Outinen, H. (Heli)

19 April 2002

Abstract Type 1 neurofibromatosis (NF1) syndrome is caused by a mutation of the NF1 gene. NF1 protein (neurofibromin) contains a domain which is related to the GTPase activating protein (GAP) and accelerates the switch of active Ras-GTP to inactive Ras-GDP. The clinical symptoms of NF1 patients include e.g. the formation of benign neurofibroma tumors and hyperpigmented lesions of the skin. The NF1 protein has been referred to as a tumor suppressor since cells of malignant schwannomas of NF1 patients may display loss of heterozygosity of the NF1 gene. In the present study, the expression of the NF1 gene was investigated during tissue repair in human skin. Elevated NF1 protein levels were seen in a fibroblastic cell population of healing wounds. In vitro studies were designed to investigate NF1 expression in dermal fibroblasts under the influence of growth factors that are operative during wound healing. Platelet-derived growth factor (PDGF) isoforms AB and BB and transforming growth factor β1 (TGFβ1) elevated NF1 mRNA levels in cultured dermal fibroblasts. In further studies, histological examination on apparently healthy skin of NF1 patients revealed frequently small masses of neurofibromatous tissue at the vicinity of hair follicles. Thus, action of the NF1 gene appears to be an integral part of normal tissue repair. Enhanced NF1 tumor suppressor expression may serve to limit excessive fibrosis in wound healing. As Ras proteins play a role in the regulation of cell differentiation and formation of cell junctions, the functional expression of NF1 protein was elucidated using differentiating keratinocytes as an in vitro model system. The results demonstrate that an intense NF1 tumor suppressor signal on intermediate filaments was temporally limited to the period in which the formation of desmosomes takes place. In analogy to NF1 protein, a rapid elevation of NF1 mRNA level was detected following initiation of differentiation. Interestingly, NF1 mRNA hybridization signal polarized towards cell-cell contact zones. This finding recognizes a potential way for post-transcriptional modification of NF1 expression and targeting of translation to subplasmalemmal location. The results demonstrate that the function of NF1 protein is associated with the formation of cell junctions, and thus to cellular communication.

cell adhesion

cell differentiation

cytoskeleton

intercellular junctions

neurofibroma

neurofibromatosis 1

post-transcriptional RNA processing

skin

wound healing

TRANSCRIPTIONAL AND POST-TRANSLATIONAL REGULATION OF TERPENOID INDOLE ALKALOID BIOSYNTHESIS IN <em>CATHARANTHUS ROSEUS</em>

Paul, Priyanka

01 January 2017

Catharanthus roseus (Madagascar periwinkle) is the exclusive source of an array of terpenoid indole alkaloids (TIAs) that are used in the treatments of hypertension and certain types of cancer. TIA biosynthesis is under stringent spatiotemporal control and is induced by jasmonate (JA) and fungal elicitors. Tryptamine, derived from the indole branch, and secologanin from the iridoid branch are condensed to form the first TIA, strictosidine. Biosynthesis of TIA is regulated at the transcriptional level and several transcription factors (TFs) regulating the expression of genes encoding key enzymes in the pathway have been isolated and characterized. The JA-responsive APETALA2/ETHYLENE RESPONSE FACTOR (AP2/ERF), ORCA3, and the basic helix-loop-helix (bHLH) factor, CrMYC2, are the key activators of the TIA biosynthesis. Recently, two other TFs, the bHLH IRIDOID SYNTHESIS 1 (BIS1) and BIS2 were also identified as regulators of TIA pathway. Analysis of C. roseus genome sequence has revealed that ORCA3 forms a physical cluster with two uncharacterized AP2/ERFs, ORCA4 and ORCA5. In plants, physically linked clusters of TFs are less characterized. Moreover, the regulation of TF clusters is relatively unexplored. My research uncovered that the ORCA gene cluster is differentially regulated. ORCA4 and ORCA5, while functionally overlapping with ORCA3, regulate an additional set of TIA pathway genes. ORCA4 or ORCA5 overexpression has resulted in significant increase of TIA accumulation in C. roseus hairy roots. In addition, ORCA5 directly regulates the expression of ORCA4 and indirectly regulates ORCA3, likely via unknown factor(s). Interestingly, ORCA5 also activates the expression of ZCT3, a negative regulator of the TIA pathway. In addition CrMYC2 is capable of activating ORCA3 and co-regulating pathway genes concomitantly with ORCA3. Several lines of evidence suggest that, in addition to the transcriptional control, biosynthesis of TIAs is also controlled at the posttranslational level, such as protein phosphorylation. Available literature indicates that a mitogen-activated protein kinase (MAPK) cascade is involved in this process. Analysis of C. roseus MAP kinome, identified two independent MAPK cascades regulating the indole and iridoid branches of the TIA pathway. We showed that the ORCA cluster and CrMYC2 act downstream of a MAP kinase cascade consisting of CrMAPKK1, CrMAPK3 and CrMAPK6. Overexpression of CrMAPKK1 in C. roseus hairy roots upregulates TIA pathway genes expressions and boosts TIA accumulation. The other cascade, consisting of CrMAPKK6 and CrMAPK13, mostly regulates the iridoid branch of the TIA pathway. Overexpression of CrMAPK13 in C. roseus hairy roots significantly upregulates iridoid pathway genes and boosts tabersonine accumulation. Moreover, we recently identified the third MAPK cascade, consisting of CrMAPKK1 and CrMAPK20, that negatively regulates the indole branch of the TIA pathway. Overexpression of CrMAPK20 in C. roseus hairy roots represses the genes regulated by CrMYC2-ORCAs and reduces catharanthine accumulation. These findings significantly advance our understanding of transcriptional and post-translational regulatory mechanisms that govern TIA biosynthesis in C. roseus.

AP2/ERF gene cluster

Catharanthus roseus

MAP kinome

terpenoid indole alkaloids

Biotechnology

Physiology

Plant Biology

Régulation de la transcription des gènes de virulence bactériens : dynamique des complexes nucléoprotéïques / Dynamics of nucleoprotein complexes in the transcriptional regulation of bacterial virulence genes

Duprey, Alexandre

03 November 2016

Les bactéries sont en permanence confrontées à des changements d'environnements. La régulation transcriptionnelle joue alors un rôle majeur dans l'adaptation des bactéries. En particulier, la bactérie phytopathogène D. dadantii s'est récemment adaptée à l'hôte végétal. Elle produit en particulier des pectate lyases (Pel) qui dégradent la pectine, ciment des parois végétales, et jouent un rôle majeur dans le développement de la maladie. Les gènes pelD et pelE, malgré la forte divergence dans leur expression, sont issus d'un transfert horizontal suivi d'une duplication récente. La question de l'intégration de ces gènes avec les régulations préexistantes s'est alors posée.Dans un premier temps, les mécanismes moléculaires détaillés de la régulation de pelD ont été étudiés. Il a été montré que cette régulation s'appuie sur un promoteur divergent de forte affinité pour l'ARN polymérase mais de faible efficacité pour la transcription et sur un arrangement stratégique de quatre sites de fixation de répresseur FIS et deux sites de l'activateur CRP. Tous ces éléments interagissent entre eux pour produire une régulation fine de l'expression de pelD. L'origine de la divergence régulatrice entre les paralogues pelD et pelE a par la suite été explorée. De manière surprenante, la divergence entre ces deux gènes et leur sélection s'appuie presque exclusivement sur un décalage de la position du promoteur de pelE (« TSS turnover ») qui l'a transformé en initiateur de la dégradation de la pectine. Ce mécanisme très fréquent chez les eucaryotes pluricellulaires (homme, drosophile, souris…) n'avait jamais encore été décrit chez les bactéries.A travers l'étude des promoteurs pelD et pelE de D. dadantii, de nouveaux mécanismes renforçant l'importance de la régulation transcriptionnelle dans les processus adaptatifs ont ainsi été découverts / Bacteria face frequent environmental changes. Transcriptional regulation plays a major role in the adaptation to these changes. In particular, the phytopathogen bacteria Dickeya have recently adapted to vegetal hosts. They produce Pecate lyases (Pel), among others, to degrade pectin in plant cell walls, which is necessary for disease development. The pelD and pelE genes, despite the strong divergence in their expression, originate from a horizontal gene transfer followed by a recent duplication. This raises the question of their integration into the preexisting regulatory networks.Detailed molecular mechanisms of the transcriptional regulation of pelD were studied first. It was shown that this regulation relies on a high-affinity but low transcription efficiency divergent promoter and a strategic arrangement of four FIS repressor binding sites and two CRP activator binding sites. These elements interact together to fine-tune the expression of pelD. Next, the origin of the regulatory divergence between the paralogous genes pelD and pelE was explored. Surprisingly, their divergence and selection relies mostly on a TSS turnover which happened on the pelE regulatory region and transformed pelE into an initiator of pectin degradation. This widespread phenomenon in multicellular eukaryotes (human, fly, mouse…) had not yet been seen in bacteria. To conclude, through the study of D. dadantii pelD and pelE promoters, new mechanisms highlighting the relevance of transcriptional regulation in adaptation were discovered in this work

Pectate lyase

Dickeya

FIS

CRP

Pel

Régulation transcriptionnelle

Pectate lyase

Dickeya

FIS

CRP

Pel

Transcriptional regulation

TSS turnover

579

Rôle du régulateur post-transcriptionnel CSR dans l'adaptation métabolique de la bactérie modèle Escherichia coli / Function of the post-transcriptional regulator CSR during the metabolic adaptation of the model bacteria Escherichia coli

Morin, Manon

10 November 2015

Dans son environnement, la bactérie Escherichia coli (E. coli) fait face à d’importantes fluctuations des ressources carbonées. Une capacité d’adaptation métabolique lui permet de coloniser ou de subsister en fonction des substrats disponibles. Cette adaptation est régie par un réseau complexe de régulations de l’expression génique. Le régulateur global post-transcriptionnel CSR (Carbon Storage Regulator) régule la stabilité et/ou l’initiation de la traduction d’ARNm par l’intermédiaire de la protéine CsrA. Ce système, essentiel en présence de glucose et est également supposé être impliqué dans la régulation d’une transition métabolique glycolyse vers gluconéogenèse. Le caractère essentiel de CSR est à ce jour inexploré, tout comme son implication dans la régulation d’une adaptation métabolique. Une approche de biologie intégrative menée pour différents mutants du système CSR a permis d’avancer pour la première fois, une explication de l’essentialité de CSR lors d’une croissance exponentielle sur glucose et de caractériser son implication dans la régulation de la transition métabolique glucose-acétate. Des approches de transcriptomique et de stabilomique utilisées pour une souche sauvage au cours d’une adaptation métabolique ont mis en évidence l’importance des régulations de la stabilité des ARNm au cours de l’adaptation. En conclusion, ces travaux approfondissent grandement les connaissances concernant le système CSR et son implication dans la régulation du métabolisme d’E. coli. Ce système, indispensable à la régulation du métabolisme durant une phase de croissance sur glucose s’ajoute de façon indéniable au réseau déjà complexe de régulations du métabolisme d’E. coli / In its natural environment, Escherichia coli (E. coli) faces strong fluctuations of the nutrient availability. A complex gene regulatory network makes the bacterium able to switch between a state of growth in the presence of an appropriate carbon source and a non-growth state in its absence. Within this network, the global post-transcriptional regulator CSR (Carbon Storage Regulator) modifies mRNA stability and/or translation initiation by the CsrA protein. This system has been shown to be essential for cells to grow on glucose and is hypothesized to be involved in the regulation of metabolic transitions. However both observations remained unexplored so far. An integrative approach has been used to investigate for the first time the essentiality of CSR on glucose as well as its involvement in the regulation of the glucose-acetate transition. Molecular and phenotypic data for different mutants of the CSR system have been produced and integrated into mathematical models. Transcriptomic and Stabilomic approaches have been used eventually to characterize the importance of the control of mRNA stability during the metabolic adaptation. mRNA stability regulations appear to be of particular importance in gene expression regulation during metabolic adaptation. To conclude, this work shed a new light upon CSR’s involvement in the regulation of E. coli’s metabolism. CSR is definitely essential to regulate glycolysis and thus constitutes another regulator to be integrated into the already complex regulations network of E.coli’s metabolism

Escherichia coli

CSR

Adaptation métabolique

Modélisation

Régulation post-transcriptionnelles

Escherichia coli

CSR system

Metabolic adaptation

Modeling

Post-transcriptional regulation

572

Transcriptomic and Secretomic Profiling of Isolated Leukocytes Exposed to Alpha-Particle and Photon Radiation - Applications in Biodosimetry

Howland, Matthew

January 2013

The general public is at risk of ionising-radiation exposure. The development of high-throughput methods to triage exposures is warranted. Current biodosimetry techniques are low-throughput and encumbered by time and technical expertise. Although there has been an emergence of gene-profiling tools for the purpose of photon biodosimetry, similar capacities do not exist for alpha-particle radiation. Herein is the first genomic study useful for alpha-particle radiation biodosimetric triage. This work has identified robust alpha-particle induced gene-based biomarkers in isolated, ex-vivo irradiated leukocytes from multiple donors. It was found that alpha-particle and photon radiation elicited similar transcriptional responses, which could potentially be distinguished by aggregate-signature analysis. Although no distinct genes were sole indicators of exposure type, clustering algorithms and principal component analysis were able to demarcate radiation type with some success. By comparing the biological effects elicited by photon and alpha-particle radiation, significant contributions have been made to the field of radiation biodosimetry.

alpha-particle

ionising radiation

ionizing radiation

gene response

transcriptional response

photon

radiation

biodosimetry

dosimetry

gene profiling

miRNA profiling

bio-plex