Characterisation of the Clp Proteins in Arabidopsis thaliana

Zheng, Bo

January 2003

<p>Unlike in the greenhouse, plants need to cope with many environmental stresses under natural conditions. Among these conditions are drought, waterlogging, excessive or too little light, high or low temperatures, UV irradiation, high soil salinity, and nutrient deficiency. These stress factors can affect many biological processes, and severely retard the growth and development of higher plants, resulting in massive losses of crop yield and wood production. Plants have developed many protective mechanisms to survive and acclimate to stresses, such as the rapid induction of specific molecular chaperones and proteases at the molecular level. Molecular chaperones mediate the correct folding and assembly of polypeptides, as well as repair damaged protein structures caused by stress, while proteases remove otherwise non-functional and potentially cytotoxic proteins. </p><p>The Clp/Hsp100 family is a new group of chaperones that consists of both constitutive and stress-inducible members. Besides being important chaperones, many Clp/Hsp100 also participate in protein degradation by associating with the proteolytic subunit ClpP to form the Clp protease complex. Higher plants have the greatest number and complexity of Clp proteins than any other group of organisms, and more than 20 different Clp isomers in plants have been identified (Paper I). Because of this diversity, we have adopted a functional genomics approach to characterise all Clp proteins in the model plant Arabidopsis thaliana. Our ongoing research strategy combines genetic, biochemical and molecular approaches. Central to these has been the preparation of transgenic lines for each of the chloroplast Clp isomers. These transgenic lines will be analysed to understand the function and regulation of each chloroplast Clp protein for plant growth and development.</p><p>In Paper II, an Arabidopsis thaliana cDNA was isolated that encodes a homologue of bacterial ClpX. Specific polyclonal antibodies were made and used to localise the ClpX homologue to plant mitochondria, consistent with that predicted by computer analysis of the putative transit peptide. In addition to ClpX, a nuclear-encoded ClpP protein, termed ClpP2, was identified from the numerous ClpP isomers in Arabidopsis and was also located in mitochondria. Relatively unchanged levels of transcripts for both clpX and clpP2 genes were detected in various tissues and under different growth conditions. Using β-casein as a substrate, plant mitochondria possessed an ATP-stimulated, serine-type proteolytic activity that could be strongly inhibited by antibodies specific for ClpX or ClpP2, suggesting an active ClpXP protease.</p><p>In Paper III, four nuclear-encoded Clp isomers were identified in Arabidopsis thaliana: ClpC1 and ClpP3-5. All four proteins are localized within the stroma of chloroplasts, along with the previously identified ClpD, ClpP1 and ClpP6 proteins. Potential differential regulation among these Clp proteins was analysed at both the mRNA and protein level. A comparison between different tissues showed increasing amounts of all plastid Clp proteins from roots to stems to leaves. The increases in protein were mirrored at the mRNA level for most ClpP isomers but not for ClpC1, ClpC2 and ClpD and ClpP5, which exhibited little change in transcript levels. Potential stress induction was also tested for all chloroplast Clp proteins by a series of brief and prolonged stress conditions. The results reveal that these proteins, rather than being rapidly induced stress proteins, are primarily constitutive proteins that may also be involved in plant acclimation to different physiological conditions. </p><p>In Paper IV, antisense repression transgenic lines of clpP4 were prepared and then later characterised. Within the various lines screened, up to 90% of ClpP4 protein content was specifically repressed, which also led to the down-regulation of ClpP3 and ClpP5 protein contents. The repression of clpP4 mRNA retarded the development of chloroplasts and the differentiation of leaf mesophyll cells, resulting in chlorotic phenotypes. The chlorosis was more severe in young than in mature leaves due likely to the developmental expression pattern of the ClpP4 protein. Chlorotic plants eventually turned green upon aging, accompanied by a recovery in the amount of the ClpP4 protein. The greening process could be affected by the light quantity, either by altering the photoperiod or light intensity.</p>

Plant physiology

Arabidopsis

molecular chaperone

protein degradation

protease

Clp/Hsp100

ClpP

stress response

antisense repression

chloroplast development

Växtfysiologi

Plant physiology

Växtfysiologi

Characterisation of the Clp Proteins in Arabidopsis thaliana

Zheng, Bo

January 2003

Unlike in the greenhouse, plants need to cope with many environmental stresses under natural conditions. Among these conditions are drought, waterlogging, excessive or too little light, high or low temperatures, UV irradiation, high soil salinity, and nutrient deficiency. These stress factors can affect many biological processes, and severely retard the growth and development of higher plants, resulting in massive losses of crop yield and wood production. Plants have developed many protective mechanisms to survive and acclimate to stresses, such as the rapid induction of specific molecular chaperones and proteases at the molecular level. Molecular chaperones mediate the correct folding and assembly of polypeptides, as well as repair damaged protein structures caused by stress, while proteases remove otherwise non-functional and potentially cytotoxic proteins. The Clp/Hsp100 family is a new group of chaperones that consists of both constitutive and stress-inducible members. Besides being important chaperones, many Clp/Hsp100 also participate in protein degradation by associating with the proteolytic subunit ClpP to form the Clp protease complex. Higher plants have the greatest number and complexity of Clp proteins than any other group of organisms, and more than 20 different Clp isomers in plants have been identified (Paper I). Because of this diversity, we have adopted a functional genomics approach to characterise all Clp proteins in the model plant Arabidopsis thaliana. Our ongoing research strategy combines genetic, biochemical and molecular approaches. Central to these has been the preparation of transgenic lines for each of the chloroplast Clp isomers. These transgenic lines will be analysed to understand the function and regulation of each chloroplast Clp protein for plant growth and development. In Paper II, an Arabidopsis thaliana cDNA was isolated that encodes a homologue of bacterial ClpX. Specific polyclonal antibodies were made and used to localise the ClpX homologue to plant mitochondria, consistent with that predicted by computer analysis of the putative transit peptide. In addition to ClpX, a nuclear-encoded ClpP protein, termed ClpP2, was identified from the numerous ClpP isomers in Arabidopsis and was also located in mitochondria. Relatively unchanged levels of transcripts for both clpX and clpP2 genes were detected in various tissues and under different growth conditions. Using β-casein as a substrate, plant mitochondria possessed an ATP-stimulated, serine-type proteolytic activity that could be strongly inhibited by antibodies specific for ClpX or ClpP2, suggesting an active ClpXP protease. In Paper III, four nuclear-encoded Clp isomers were identified in Arabidopsis thaliana: ClpC1 and ClpP3-5. All four proteins are localized within the stroma of chloroplasts, along with the previously identified ClpD, ClpP1 and ClpP6 proteins. Potential differential regulation among these Clp proteins was analysed at both the mRNA and protein level. A comparison between different tissues showed increasing amounts of all plastid Clp proteins from roots to stems to leaves. The increases in protein were mirrored at the mRNA level for most ClpP isomers but not for ClpC1, ClpC2 and ClpD and ClpP5, which exhibited little change in transcript levels. Potential stress induction was also tested for all chloroplast Clp proteins by a series of brief and prolonged stress conditions. The results reveal that these proteins, rather than being rapidly induced stress proteins, are primarily constitutive proteins that may also be involved in plant acclimation to different physiological conditions. In Paper IV, antisense repression transgenic lines of clpP4 were prepared and then later characterised. Within the various lines screened, up to 90% of ClpP4 protein content was specifically repressed, which also led to the down-regulation of ClpP3 and ClpP5 protein contents. The repression of clpP4 mRNA retarded the development of chloroplasts and the differentiation of leaf mesophyll cells, resulting in chlorotic phenotypes. The chlorosis was more severe in young than in mature leaves due likely to the developmental expression pattern of the ClpP4 protein. Chlorotic plants eventually turned green upon aging, accompanied by a recovery in the amount of the ClpP4 protein. The greening process could be affected by the light quantity, either by altering the photoperiod or light intensity.

Plant physiology

Arabidopsis

molecular chaperone

protein degradation

protease

Clp/Hsp100

ClpP

stress response

antisense repression

chloroplast development

Växtfysiologi

Plant physiology

Växtfysiologi

Transcription Level Determination Of Candidate Genes Upon Infections Of Powdery Mildew On Barley

Atici, Elif

01 February 2012

Immune systems are fundamentally based on the differentiation of self and non-self. Unlike mammals, plants have an innate immune system responding to the pathogen only at the site of attack. One of these pathogens is Blumeria graminis f. sp. hordei which is an obligate biotrophic pathogen causing powdery mildew disease and resulting in up to 30% yield loss for both cultivated and wild barley. In this study, Pallas-01 (P-01) and Pallas-03 (P-03) barley lines were inoculated with powdery mildew race Bgh103 (64/01) resulting incompatible and compatible interactions, respectively. 6, 12, 24, 48 and 72 hour-post-inoculation (hpi) samples were used in order to define the differential gene expression of NAD malic enzyme, chloroplast lipocalin, phosphoglyceromutase (PGM), Mg chelatase and 26S protease regulatory subunit 6B homolog. In the proteomics study previously conducted in the laboratory, except for the NAD-dependent malic enzyme, the other four proteins were shown to be involved in the incompatible interaction of P-01 and Bgh103 at protein level, whereas NAD-dependent malic enzyme was changing in the compatible interaction. The expression level for both proteomics and transcriptomics were assumed to be similar. However, the level of transcript would not always reflect its protein level or correlate with the level of proteins, due to complex cellular regulation processes. Post-transcriptional modifications such as synthesis, processing, degradation and post-translational modifications are changing the level of proteins expressed, thus a parallel correlation between the protein and mRNA levels can be lost. Other possible reasons for this variation can be changes in mRNA and protein stability, efficiency of translation and protein&rsquo / s turnover rate. The transcription level changes of the genes investigated in this study are found to be differentially expressed, supporting the proteomics data indicating that these genes are possibly involved in resistance. For further investigations, genetic tools such as gene silencing with RNAi and knockout experiments are required in order to elucidate the mechanism of these candidate genes in the plant-pathogen interaction.

QH Genetics 426-470

Homéostasie du cuivre dans le chloroplaste : étude comparée de deux transporteurs de la famille des ATPases de type PIB / Copper homeostasis in chloroplasts : comparative study of two transporters belonging to the PIB- type ATPases family

Sautron, Emeline

14 October 2015

Le cuivre est un métal de transition essentiel pour le fonctionnement des organismes vivants. Chez la plante Arabidopsis thaliana, la moitié du contenu en cuivre est localisé dans le chloroplaste. Cet organite, spécifique des cellules végétales, est constitué d'une enveloppe délimitant le stroma, un compartiment aqueux au sein duquel se trouve un système membranaire complexe, les thylacoïdes. Dans les chloroplastes d'Arabidopsis, le cuivre est le cofacteur de deux protéines essentielles : la superoxyde dismutase Cu/Zn, impliquée dans la défense contre des espèces réactives de l'oxygène au niveau du stroma et la plastocyanine, une protéine du lumen des thylacoïdes, impliquée dans la chaine de transfert des électrons photosynthétiques. Des études de génétique inverse ont démontré que le transport du cuivre à la plastocyanine impliquait deux protéines membranaires appartenant à la famille des ATPases-PIB-1 : HMA6, localisée dans l'enveloppe et HMA8, localisée dans la membrane des thylacoïdes. Une étude fonctionnelle in vitro a montré que HMA6 était un transporteur de haute affinité de cuivre monovalent présentant les caractéristiques générales des ATPases-P. Afin de comparer les propriétés enzymatiques de ces deux ATPases-PIB-1 et de mieux comprendre leur rôle respectif dans l'homéostasie du cuivre au sein du chloroplaste, nous avons déterminé in vitro les propriétés enzymatiques de HMA8.La stratégie employée pour la caractérisation de HMA8 a été similaire à celle utilisée pour la caractérisation de HMA6. Dans un premier temps, la sélectivité ionique de HMA8 a été évaluée à l'aide de tests phénotypiques dans la levure Saccharomyces cerevisiae. Les propriétés enzymatiques de HMA8 ont ensuite été déterminées in vitro après expression dans la bactérie Lactoccocus lactis, par des expériences de phosphorylation par l'ATP. Cette analyse a permis de démontrer que HMA8 présentait une plus forte affinité apparente pour le cuivre mais une activité catalytique plus lente que HMA6. L'analyse de modèles tridimensionnels de HMA6 et HMA8 a montré que ces différences pourraient être expliquées par des différences de charges au niveau de la cavité où le métal est libéré et/ou par la nature des partenaires interagissant avec ces ATPases. Ces différences pourraient expliquer les fonctions distinctes de ces deux transporteurs dans le chloroplaste : HMA6 régulerait la concentration en cuivre dans le stroma en interagissant avec différentes protéines cibles (notamment des chaperonnes à cuivre), alors que HMA8 aurait un rôle plus précis pour la distribution du cuivre à la plastocyanine.Pour mieux comprendre le mécanisme de libération du cuivre par HMA6 et HMA8, nous avons effectué une étude fonctionnelle de mutants de la région reliant les deux premières hélices transmembranaires (TMA et TMB). Dans cette étude, nous avons ciblé les cystéines et histidines qui de par leurs propriétés chimiques sont les résidus les plus à même d'interagir avec le métal. Les mutants d'intérêts ont été sélectionnés par criblage phénotypique dans la levure puis exprimés dans la bactérie L. lactis. La caractérisation biochimique in vitro de leurs propriétés enzymatiques a été réalisée par des tests de phosphorylation par l'ATP et le Pi. Cette étude nous a permis d'identifier deux résidus, une cystéine et une histidine, impliqués la libération du cuivre et de proposer un modèle de cheminement du métal dans la partie extracytoplasmique du site de transport de HMA6 / Copper is an essential transition metal for living organisms. In the plant Arabidopsis thaliana, half the copper content is localized in the chloroplast. This organelle specific of plant cells, consists of an envelope delimiting the stroma, an aqueous compartment within which there is a complex membrane system, the thylakoids. In chloroplasts of Arabidopsis, copper is the cofactor of two essential proteins: the superoxide dismutase Cu / Zn, involved in defense against reactive oxygen species in the stroma and plastocyanin, a protein of the thylakoid lumen involved in the chain transfer photosynthetic electron. Reverse genetics studies have demonstrated that copper transport in plastocyanin involved two membrane proteins belonging to the family of ATPases-PIB-1: HMA6, located in the envelope and HMA8, localized in the thylakoid membranes. A functional in vitro study showed that HMA6 was a monovalent high affinity copper transporter showing the general characteristics of P-ATPases. To compare the enzymatic properties of these two ATPases and better understand their respective role in copper homeostasis in the chloroplast, we in vitro determined the enzymatic properties of HMA8.The strategy employed for the characterization of HMA8 was similar to that used for the characterization of HMA6. Initially, the ion selectivity of HMA8 was evaluated using phenotypic tests in the yeast Saccharomyces cerevisiae. The enzymatic properties of HMA8 were then determined in vitro after expression in the bacterium Lactoccocus lactis, by phosphorylation experiments by ATP. This analysis demonstrated that HMA8 had a stronger apparent affinity for copper but a slower catalytic activity than HMA6. The analysis of three-dimensional models of HMA6 and HMA8 showed that these differences could be explained by differences in the electrostatic potential at the cavity where the metal is released and/or by the nature of the partners interacting with these ATPases. These differences might explain the distinct functions of the two carriers in the chloroplast: HMA6 would regulate the copper concentration in the stroma by interacting with various target proteins (including copper chaperone), while HMA8 would have a more specific role for the distribution of copper plastocyanin.To better understand the mechanism of copper release by HMA6 and HMA8, we conducted a functional study of mutants of the region connecting the first two transmembrane helices (TMA and TMB). In this study, we specifically targeted cysteines and histidines because of their chemical properties that make them very strong metal ligands. The mutants of interest were selected by phenotypic screening in yeast and then expressed in the bacterium L. lactis. The in vitro biochemical characterization of their enzymatic properties was carried out by phosphorylation tests by ATP and Pi. This study allowed us to identify two residues, one cysteine and one histidine, involved the release of copper and to propose a metal path model in extracytoplasmic part of the transport site of HMA6

ATPase-P1B

Chloroplaste

Caractérisation biochimique

Homéostasie du cuivre

Structure

Protéine membranaire

P1B-ATPase

Chloroplast

Biochemical characterization

Copper homeostasis

Structure

Membrane protein

570

580

CaracterizaÃÃo bioquÃmica e molecular da oxidase terminal da plastoquinona (PTOX) em Zea mays / Molecular and biochemical characterization of plastoquinone terminal oxidase (PTOX) in Zea mays

Francisco Yuri Maia de Sousa

28 October 2008

Conselho Nacional de Desenvolvimento CientÃfico e TecnolÃgico / CoordenaÃÃo de AperfeiÃoamento de Pessoal de NÃvel Superior / O cloroplasto à uma organela caracterÃstica dos organismos fotossintetizantes sendo seu papel primordial na geraÃÃo de energia a partir de gÃs carbÃnico e Ãgua. Essa organela pode ter seu funcionamento comprometido quando submetida a estresses ambientais devido a fragilidade e complexidade do sistema. Para evitar perdas provocadas pelo estresse existem vÃrios mecanismos de adaptaÃÃo e regulaÃÃo das reaÃÃes que ocorrem no cloroplasto. Recentemente caracterizou-se mais um desses provÃveis mecanismos que foi chamado de clororespiraÃÃo. A clororespiraÃÃo foi esclarecida com a descoberta de uma enzima similar a oxidase alternativa da mitocondria que chamou-se de oxidase terminal do plastÃdeo (PTOX). A funÃÃo dessa respiraÃÃo do cloroplasto permanece incerta, mas uma das hipÃteses mais aceitas à que o funcionamento da clororespiraÃÃo poderia prevenir a formaÃÃo de espÃcies reativas de oxigÃnio atravÃs da reciclagem dos intermediÃrios redutores do cloroplasto. No presente trabalho foi caracterizado a presenÃa de dois genes que codificam para a oxidase terminal do plastÃdeo em plantas de Zea mays. Estudou-se tambÃm a expressÃo diferencial de ambos genes da PTOX em resposta ou estresse hÃdrico, alÃm da caracterizaÃÃo da clororespiraÃÃo atravÃs da atividade da NADH desidrogenase plastidial (NDH) em gel de poliacrilamida. A caracterizaÃÃo molecular dos genes da PTOX mostrou homologia de 60% quando comparadas as sequÃncias dos genes e de 79% quando comparadas as prÃ-proteÃnas traduzidas. Os genes dessa proteÃna tÃm estruturas similares, sendo compostos por oito introns e 9 Ãxons. Um estudo das regiÃes dos promotores dos genes mostrou que existiam elementos comuns porÃm a presenÃa de elementos diferentes como, o elementos cis MBS que à responssivo à seca, poderia revelar uma regulaÃÃo diferencial dos genes. A resposta diferencial foi confirmada atravÃs de RT-PCR semiquantitativo. O gene chamado de ptox1 teve sua expressÃo estÃvel, podendo ser considerado um gene constitutivo, enquanto que o gene chamado de ptox2 teve um aumento da expressÃo proporcional ao estresse aplicado tanto em folhas como em raÃzes de plantas de milho. A anÃlise da atividade da NDH em gel (zimograma) revelou a presenÃa dessa enzima em cloroplastos de milho confirmando a presenÃa das enzimas da clororespiraÃÃo. O estudo filogenÃtico de sequencias de cDNA de bancos de dados mostraram que milho e sorgo pertencentes ao grupo das monocotiledÃneas, sÃo espÃcies muito prÃximas e que compartilham dois genes ortÃlogos da PTOX identificados como ptox1 e ptox2. Concluiu-se pela primeira vez a presenÃa de dois genes da PTOX no genoma do milho, uma monocotiledÃena de metabolismo C4. Os genes foram denominados de ptox1 e ptox2. Eles foram encontrados em raÃzes e folhas e apenas o gene da ptox2 pareceu ser induzido em resposta ao estresse osmÃtico. / The chloroplast is an organelle characteristic of photosynthetic organisms and their role in generating energy from carbon dioxide and water. This organelle may be functionally compromised when subjected to environmental stress due to the fragility and complexity of the system. To avoid losses caused by stresses plants have evolved various coping mechanisms, as well as, regulation of the reactions that occur in the chloroplast. Most recently it was characterized one of these mechanisms that was called chlororespiration. The chlororespiration was bring to light with the discovery of an enzyme, similar to the alternative oxidase of mitochondria, that was called the plastid terminal oxidase (PTOX). The function of this chloroplast respiration remains uncertain, but one of the most accepted hypothesis is that the operation of chlororespiration could prevent the formation of reactive oxygen species by recycling the reducing intermediates of the chloroplast. The present study characterized the presence of two genes encoding the plastid terminal oxidase in plants of Zea mays., and its differential expression in response to water stress. It was also characterized the chlororespiration through the activity of plastidial NADH dehydrogenase (NDH) in polyacrylamide gel. The molecular characterization of PTOX genes showed 60% homology when compared sequences of genes, but 79% when compared to pretranslated proteins. The genes of this protein have similar structures, being composed of nine exons and eight introns. A study of regions of the promoters of the genes showed that there were common elements, but the presence of different elements such as the cis elements that MBS responsive to drought, could reveal a differential regulation of genes. The differential response was confirmed by semiquantitative RT-PCR. The gene called ptox1 had its expression level stable and could be considered a constitutive gene, while the gene called ptox2 had an increased expression proportional to the applied stress in both leaves and roots of maize plants. The analysis of NDH activity gel (zimograms) revealed the presence of this enzyme in maize chloroplasts suggesting the existence of the chlororespiratory pathway. The phylogenetic analysis of cDNA sequences from NCBI databases showed that maize and sorghum, being closely related species, share two genes )identified as orthologs of PTOX (ptox1 and ptox2). It was confirmed for the first time the presence of two PTOX genes in the genome of maize, a C4-metabolism monocotyledon and its differential expression under drought stress.

proteÃna desacopladora do cloroplasto

clororespiraÃÃo

oxidase terminal do plastideo (PTOX)

Zea mays L.

estresse de seca

chloroplast uncoupling protein

chlororespiration

plastid terminal oxidase(PTOX)

Zea mays L.

drought stress

BIOQUIMICA

Origines, domestication et diversification variétale chez l’olivier (Olea europaea L.) à l’ouest de la Méditerranée / Origins, domestication and varietal diversification in Olive (Olea europaea L.) in western Mediterranean area.

Haouane, Hicham

22 December 2012

Les oliviers cultivés et leurs parents sauvages (oléastres), représentent deux variétés botaniques de l'espèce Olea europaea, subsp. var. europaea et var. sylvestris, respectivement. Selon des études génétiques et archéobotaniques antérieures, l'existence de populations d'oléastres dans l'est et l'ouest du bassin méditerranéen remonte à avant le néolithique. La domestication de l'olivier aurait eu lieu au moins dans ces deux zones. Néanmoins, la lignée maternelle qui caractérise les oléastres de l'est de la Méditerranée est majoritaire au sein des variétés méditerranéennes. Une telle signature génétique est probablement le résultat de migrations humaines essentiellement d'est en ouest. En dépit de ces travaux, les origines et les processus de diversification à l'ouest de la méditerranée demeurent méconnus. L'objectif de cette thèse est d'étudier les origines et les processus de diversification chez l'olivier à l'ouest de la Méditerranée. Deux hypothèses sont formulées: (i) une co-existence entre variétés sélectionnées localement et variétés introduites à partir de l'est de la Méditerranée et maintenues par clonage, (ii) une sélection à partir des formes de l'est introgressées par les populations locales à l'ouest de la Méditerranée. Dans une première partie, nous avons examiné les processus de diversification par une analyse des pratiques paysannes à une échelle localisée et dans une zone d'extrême diffusion : le Maroc. Il s'agissait de comprendre comment les paysans traitent la diversité variétale dans un contexte fortement impacté par une seule et même variété, la ‘Picholine marocaine'. Sur la base d'enquêtes semi-dirigées menées auprès des paysans dans les agro-écosystèmes traditionnels et selon une approche d'ethnobiologie, nous avons mis en évidence l'importance des logiques de classifications locales (usage, origine, âge, conservation de l'huile, méthode de propagation…) dans le traitement, le maintien et la gestion de la diversité variétale. Nos résultats montrent la présence d'un système de dénomination basée sur des catégories englobantes où les types d'oliviers sont regroupés sous des noms génériques en fonction des critères socioculturels et techniques plutôt que sur des critères morphologiques. Nous avons montré que ces catégories sont définies par des contours permissifs permettant aux types d'oliviers d'être classées dans plusieurs catégories. Nous soutenons l'hypothèse que ce système de classification permet de maintenir la diversité et est une force motrice pour la diversification variétale dans ces agro-écosystèmes caractérisés par une faible diversité d'oliviers. Dans une seconde partie, nous avons examiné les processus de diversification variétale par une approche basée sur la phylogéographie à l'échelle de la Méditerranée. Les analyses génétiques des variétés méditerranéennes d'olivier basées sur l'utilisation des marqueurs microsatellites nucléaires et chloroplastiques selon une approche bayésienne montrent une structure génétique est-ouest. La plupart des variétés de l'ouest de la méditerranée ont une lignée maternelle de l'est mais un génome nucléaire proche du "pool" génétique de l'ouest de la Méditerranée, ce qui indique une sélection à partir des formes de l'est introgressées par le "pool" génétique ouest et suggère que la sélection des oliviers à partir du semis n'a pas cessé aux premières étapes de domestication. Nos analyses sur les pratiques paysannes montrant que l'oléastre issu de semis fait partie intégrante de l'agro-écosystème et fait l'objet de sélection et d'usage (greffage sur oléastre, utilisation de l'huile de l'oléastre), ce qui plaide en faveur de l'hypothèse de l'introgression. En adoptant l'approche ABC (Approximative Bayesianne Computation), nous montrons que le scénario basé sur l'introgression des oliviers de l'est par les oléastres de l'ouest est le plus probable avec une introgression. / Olive cultivars and their wild relatives (also named oleasters) represent two botanical varieties of Olea europaea subsp. europaea, respectively var. europaea and var. sylvestris. Archaeobotanical and genetic studies showed the occurrence of Oleasters populations in east and west Mediterranean areas before the Neolithic. The domestication of the olive tree has taken place at least in these two areas. However, the maternal lineage that characterizes the eastern Mediterranean oleasters predominates among Mediterranean olive varieties. Such genetic signature is probably the result of human migrations mainly from east to west. Nevertheless, the origins and processes of olive diversification in the western Mediterranean remain unknown. The objective of this thesis is to study the origins and processes of olive diversification in the western Mediterranean areas. Two assumptions are formulated: (i) a co-existence between locally selected and introduced olive varieties from the eastern Mediterranean and maintained by cloning, (ii) a selection from the eastern olive varieties and their introgression by local populations of the western Mediterranean pool. Firstly, we examined the process of olive diversification through analysis of farming practices on a localized scale and in an area of extreme diffusion, in Morocco. Our aim is to understand how farmers treat the olive varietal diversity in a highly impacted context by a single variety, the ‘Picholine marocaine'. Based on semi-structured surveys conducted with farmers in traditional agro-ecosystems and using an approach of ethnobiology, we highlighted the importance of local classification logic (use, origin, age, conservation oil, propagation methods ...) in the treatment, maintenance and management of the varietal diversity. Our results show the presence of a naming system based on inclusive categories which olives types are grouped under generic names based on cultural and technical criteria rather than morphological criteria. We have shown that these categories are defined by permissive contours allowing the olive types to be classified in several categories. We support the hypothesis that this classification system helps to maintain diversity and is a driving force for varietal diversification in these agro-ecosystems characterized by a low diversity of olive trees. Secondly, we examined the varietal olive diversification process by an approach based on a phylogeographic study at a Mediterranean scale. Genetic analyses of Mediterranean olive varieties based on the nuclear and chloroplast microsatellites markers and a Bayesian approach show an east-west genetic structure. Most of western olive varieties have a maternal lineage of the oleasters Mediterranean east, but a nuclear genome close to the gene pool of western Mediterranean, indicating a selection from the eastern forms that were introgressed by the western Mediterranean gene pool and suggests that selection from seedling has not ceased in the early stages of domestication. Our analyzes on the farmers' practices show that oleasters from seedling is an integral part of the agroecosystem and are subject to selection and use (grafting, use of oil oleasters), which argues in favor of the introgression hypothesis. By adopting the ABC approach (Approximate Computation Bayesianne), we show that the scenario based on the introgression of olive varieties of the east by the western oleasters is the most likely scenario. We enrich the knowledge about the domestication process in the western Mediterranean by crossing analysis of farmers' practices and phylogeographic study of olive trees in the Mediterranean basin. Results were discussed with respect to ex-situ versus in-situ conservation and with the questions raised by the evolution of plant diversity involving clonal and sexual propagation.

Olea europaea L.

Marqueurs SSR markers

Domestication

Ethnobiologie

ADN chloroplastique

Diversification

Olea europaea L.

SSR markers

Domestication

Ethnobiology

Chloroplast DNA polymorphisme

Diversification

Caractérisation du chromoplaste de tomate par approche protéomique / Characterization of tomato fruit chromoplasts by proteomic approach

Barsan, Cristina Ioana

10 November 2010

La maturation des fruits est un processus complexe, principalement régulé par l'hormone végétal éthylène, qui entraîne d'importants changements métaboliques et physiologiques, ayant pour résultat la dispersion des graines. Le changement le plus visible qui se produit pendant la maturation des fruits est le changement de couleur. L'organite responsable de ce phénomène est le chromoplaste, lieu d’accumulation des caroténoïdes. Toutefois, ce n'est pas son unique rôle. Il a été montré qu’il est aussi impliqué dans la biosynthèse des lipides, de l’amidon, des vitamines et des arômes. Parce que la plupart des protéines (95%) qui composent le protéome du chromoplaste sont codées par le noyau, l’approche génomique n'est pas suffisante pour connaître les fonctions de chromoplaste dans la synthèse des métabolites d'intérêt. La protéomique de haut débit associée à la bio- nformatique a été utilisée pour caractériser le chromoplaste de tomate. L’analyse du protéome de chromoplastes de fruits de tomate rouges a révélé la présence de 988 protéines correspondantes à 802 unigènes d’Arabidopsis, dont 209 n’ont pas été répertoriés jusqu'à présent dans des banques de données plastidiales. Ces données ont révélé plusieurs caractéristiques du chromoplaste. Les protéines du métabolisme des lipides et de trafic sont bien représentées, y compris toutes les protéines de la voie de la lipoxygénase nécessaire à la synthèse des arômes volatiles dérivés de lipides. Les protéines impliquées dans la synthèse de l'amidon coexistent avec plusieurs protéines qui dégradent l'amidon. Les chromoplastes ne contiennent plus les protéines de biosynthèse de la chlorophylle mais contiennent des protéines impliquées dans la dégradation de la chlorophylle. Aucun des protéines impliquées dans le mécanisme de transport thylacoïdal n’ont été trouvées. Étonnamment, les chromoplastes contiennent l'ensemble des protéines du cycle de Calvin, y compris la Rubisco, ainsi que la voie des pentoses phosphates (OxPPP). L'analyse de l'évolution du transcriptome des gènes codant pour des protéines chromoplastiques a été réalisée. Ces données ont confirmé la réduction de la photosynthèse et le maintien du cycle de Calvin, ainsi que la biosynthèse de l'amidon et des lipides. Des analyses biochimiques complémentaires ont montré dans des chromoplastes isolés la présence d’une activité de deux enzymes importantes dans la biosynthèse des arômes (lipoxygénase et l'alcool déshydrogénase). Par ailleurs, à l’aide du couplage de protéines à la GFP et à leur expression dans des protoplastes, nous avons montré que des protéines ne présentant pas de peptide signal peuvent être localisées dans le chromoplaste. Enfin, un protocole d'isolement des plastes de fruits de tomate à différents stades de maturation a été mis au point et les fractions plastidiales ainsi obtenues ont été caractérisées par la microscopie confocale à balayage laser. La transition du chloroplaste à chromoplaste est un processus qui n'a jamais été décrit par la protéomique. Ce travail est en cours et devrait répondre à certaines questions concernant les changements qui ont lieu dans l'organite, et apporter des informations nouvelles pour la compréhension de la maturation des fruits. / Fruit ripening is a complex process, mainly regulated by the fruit hormone ethylene, resulting in significant metabolic and physiological changes, having as outcome seed dispersal. The most flagrant change taking place during ripening is the change in color. The organelle responsible for this is the chromoplast, the place of carotenoids accumulation. However this is not its unique role. It was found to be involved in lipid, starch, vitamins and aroma biosynthesis. Due to the fact that most proteins (95%) composing the chromoplast are codified by the nucleus knowledge on gene expression and genome sequences is not useful in the investigation of the functions of chromoplast in the synthesis of the metabolites of interest. High- hroughput proteomics associated with bio-informatics was used to characterize the tomato chromoplast and to reveal its intimate structure. Analysis of the proteome of red fruit chromoplasts revealed the presence of 988 proteins corresponding to 802 Arabidopsis unigenes, among which 209 had not been listed so far in plastidial data banks. These data revealed several features of the chromoplast. Proteins of lipid metabolism and trafficking were well represented, including all the proteins of the lipoxygenase pathway required for the synthesis of lipid-derived aroma volatiles. Proteins involved in starch synthesis co- xisted with several starch-degrading proteins and starch excess proteins. Chromoplasts lacked proteins of the chlorophyll biosynthesis branch and contained proteins involved in chlorophyll degradation. None of the proteins involved in the thylakoid transport machinery were discovered. Surprisingly, chromoplasts contain the entire set of Calvin cycle proteins including Rubisco, as well as the oxidative pentose phosphate pathway (OxPPP). The analysis of the evolution of the transcriptome of chromoplastic protein-encoding genes was performed. This data confirmed the reduction of the photosynthesis and the maintenance of the Calvin cycle, and of the lipid and starch biosynthesis. Further analysis is performed showing the activity of two important actors in the aroma biosynthesis (lipoxygenase and alcohol dehydrogenase). Several proteins with possible chromoplastic location were coupled with the GFP and expressed in the single cell system. A protocol for isolating tomato fruit chloroplasts and immature chromoplasts was described along with the characterization of the plastidial fractions by confocal microscopy. The transition of the chloroplast to chromoplast is a process that was never described by means of proteomics. This work answers some questions regarding the changes that take place in the organelle, and brings novel information for the understanding of fruit ripening process

Tomate

Isolement

Chromoplaste

Protéomique

Transition chloroplaste-chromoplaste

Microscopie confocale et de fluorescence

Tomato

Isolation

Chromoplast

Proteomics

Chloroplast to chromoplast transition

Confocal and fluorescence microscopy

Der Einfluss von Tetratricopeptide Repeat Proteinen auf die Chlorophyllbiosynthese und Chloroplastenbiogenese

Herbst, Josephine

06 December 2019

Chlorophyll spielt eine unabdingbare Rolle für die lichtabhängige Reaktion der Photosynthese. Die adäquate Versorgung mit Chlorophyll wird dabei durch die Tetrapyrrolbiosynthese (TBS) gewährleistet. In den letzten Jahrzehnten wurde eine Vielzahl von Proteinen identifiziert, welche an der Anpassung der TBS an wechselnde (a)biotische Wachstumsbedingungen der Pflanze beteiligt sind. Allerdings konnte bislang nicht zweifelsfrei geklärt werden, wie die TBS mit der Integration von Chlorophyllen in die Photosysteme koordiniert wird. Vor einigen Jahren wurde ein Interaktionspartner der Protochlorophyllid-Oxidoreduktase (POR) in Synechocystis identifiziert, welcher als potenzieller Faktor dieser Koordination in Frage kommt. Das POR-INTERACTING TPR-Protein (Pitt) stabilisiert POR an der Thylakoidmembran und interagiert auch mit dem Vorstufenprotein des D1. Pitt gehört zur Familie der tetratricopeptide repeat (TPR) Proteine, deren Vertreter vorrangig für die Vermittlung von Protein-Protein-Interaktionen zuständig sind. Aus diesem Grund war, neben der Identifikation des potenziellen Pitt-Homologs im Modelorganismus Arabidopsis thaliana, die Analyse von anderen Vertretern dieser Proteinklasse ein vielversprechender Ansatz bei der Identifikation von weiteren Regulatoren der TBS oder Photosynthese. Von den fünf ausgewählten TPR-Proteinen aus Arabidopsis thaliana mit einer hohen Sequenzähnlichkeit zu Pitt waren vier in der Lage, physisch mit POR zu interagieren. Von diesen vier Kandidaten ist das durch das Gen At1g78915 kodierte, membranintegrale TPR-Protein (TPR1) der beste Kandidat des putativen Pitt-Homologs in Arabidopsis. Vergleichbar zu Pitt interagiert TPR1 mit POR und stabilisiert das Enzym an den plastidären Membranen. Die Stabilisierung von POR durch TPR1 spielt eine entscheidende Rolle während der Etiolierung und Ergrünung von Keimlingen. Darüber hinaus steht TPR1 im Zusammenhang mit der schnellen Inaktivierung der 5-Aminolävulinsäuresynthese. / Chlorophyll plays an indispensable role in the light reaction of the photosynthesis. The adequate supply of chlorophyll is ensured by tetrapyrrole biosynthesis (TBS). Within the last decades, multiple proteins were identified, which are involved in adjusting the TBS-pathway to changing (a)biotic plant growth conditions. Nevertheless, it is not fully understood how the TBS-pathway is coordinated parallel to the assembly of the photosystems and the integration of chlorophylls into the pigment-binding subunits of the photosystems. Several years ago, an interaction partner of the protochlorophyllide-oxidoreductase (POR) was identified in Synechocystis which was proposed to be involved in the coordination of these mechanisms. The POR-INTERACTING TPR-Protein (Pitt) binds and stabilizes POR at the thylakoid membranes and interacts with the precursor protein of D1. Therefore, Pitt could facilitate the incorporation of chlorophylls into the plastid-encoded nascent photosynthetic subunits. Pitt belongs to the tetratricopeptide repeat (TPR) protein family, whose members mediate protein-protein-interactions. Besides the identification of the potential Pitt-homolog in the model organism Arabidopsis thaliana, analysis of additional members of the TPR-protein superfamily was a promising approach for the identification of further posttranslational regulators of TBS and photosynthesis. Five Arabidopsis thaliana TPR-proteins with a high sequence similarity to Pitt were selected. Four of those proteins are able to interact physically with POR. Among them, the TPR-protein encoded by the gene At1g78915 (TPR1) was the best candidate to represent a putative Pitt homolog in Arabidopsis. Similar to Pitt, TPR1 is a plastid-localized integral membrane protein, which interacts with POR at the thylakoid membranes. The stabilizing effect of TPR1 on POR is especially needed during etioliation and greening. Additionally, TPR1 is required for a inactivation of the 5'-aminolevulinic acid synthesis.

Tetrapyrrolbiosynthese

tetratricopeptide repeat Proteine

Chloroplastenbiogenese

Chlorophyllbiosynthese

tetratricopeptide repeat proteins

tetrapyrrole biosynthesis

chlorophyll biosynthesis

chloroplast biogenesis

570 Biowissenschaften; Biologie

WN 3100

ddc:570

Ultrastruktura chloroplastů buku pod vlivem zvýšené koncentrace CO2 a různé ozářenosti / Ultrastrucutre of beech chloroplasts under the elevated CO2 concentration and different irradiation

Vrbová, Anna

January 2014

Forest stands may act as important carbon storage places - sinks, due to carbon allocation into both the plant biomass in the process of photosynthesis and the soil. Enhancement of CO2 concentration affects a whole range of plant physiological processes and, thus, it is necessary to study its effect on photosynthetic apparatus - leaf anatomical structure and chloroplast ultrastructure. The first aim of the Thesis was to evaluate changes in chloroplast ultrastructure of common beech (Fagus sylvatica L.) under the effects of both elevated CO2 concentration and different irradiance. The second aim was to evaluate if the anatomical parameters obtained from the middle part of the leaf are representative for the whole leaf blade. The trees were grown in glass domes at the Bílý Kříž experimental site in the Beskids Mountains (Czech Republic), owned by the CzechGlobe Institute. Leaves were sampled in 2010 from juvenile trees, which were planted in 2005 being 5-year old and cultivated since then in ambient (AC; 390 micromol/mol) and elevated (EC; 700 micromol/mol) CO2 concentrations. The EC effect was recorded to be an increased proportion of starch grains in the chloroplast median section and decreased proportion of of intergranal thylakoids (IGT) while the ratio of granal to intergranal thylakoids...

Subcellular Localization of Tobacco Salicylic Acid Binding Protein 2 in Plants.

Fai, Leonard Yenwong

07 May 2011

Salicylic Acid Binding Protein 2 (SABP2) is a 29kDa protein present in extremely low amounts in tobacco leaves. SABP2 processes the mobile defense signal, methyl salicylic acid generated in plants resisting microbial infection. The precise localization of SABP2 in plants is not known. SABP2 has not been shown to have any targeting signal peptides. This study was designed to determine localization of SABP2 in tobacco plants. Biochemical and immunological studies using antibodies against SABP2 suggest that it is localized to the chloroplast, associating with chloroplast envelope membranes. Chloroplast import assays confirm that SABP2 is associated with the chloroplast envelope membrane. Solubilization and analysis of chloroplast membrane proteins show that imported SABP2 associates with the chloroplast envelope membrane by weak hydrophobic and/or ionic interactions. Cellular localization and understanding mechanisms of SABP2 import to the chloroplast will be important from a metabolic engineering standpoint to enhance plant natural defense against microbial pathogens.

Plant defense

salicylic acid

systemic acquired resistance

salicylic acid binding protein 2

sub-cellular localization

chloroplast import

Life Sciences

Plant Biology

Plant Sciences