Global ETD Search

731	Des Canaux Ioniques de la Membrane Plasmique lors de la Mort Cellulaire Programmée induite par l'Ozone chez A. thaliana. Tran, Quoc-tuan daniel 12 December 2011 (has links) (PDF) L'ozone troposphérique est un polluant secondaire majeur. Outre son rôle de gaz à effet de serre direct, l'ozone fait partie des polluants atmosphériques les plus toxiques et la pollution qu'elle engendre, affecte aussi bien la santé humaine que la productivité végétale. Les travaux présentés dans cette thèse porte sur l'étude du rôle des canaux ioniques de la membrane plasmique en réponse à une forte exposition à l'ozone ainsi que leurs interactions avec les évènements de signalisation mis en place lors du processus de PCD induit par ce stress sur des cellules en culture d'A. thaliana. Nous avons montré que cette mort cellulaire génétiquement contrôlée est caractérisée par une plasmolyse semblable à " l'Apoptosis Volume Decrease " (AVD) décrit en animal. Ce processus est promu par des cascades de signalisation où, dans un premier temps, les canaux anioniques sont très précocement activés potentiellement par l'acide oxalique issu de la dégradation de l'ascorbate par l'O3. Les données suggèrent une interconnexion entre les courants anioniques, l'influx cacique et une génération de ROS dépendante de la NADPH oxydase. Dans un deuxième temps, des canaux K+ rectifiants sortants sont activés de manière retardée et participent à la PCD. Cette activation retardée pourrait être due à une régulation post-transcriptionnelle des canaux GORK induite par l'O2*-. Enfin, nous avons également mis en évidence des activités enzymatiques de type caspase, au niveau cytoplasmique et nucléaire. Ces activités enzymatiques semblent être corrélées à la baisse de la teneur vacuolaire en ions K+, mais des données complémentaires sont nécessaires afin de comprendre les mécanismes sous-jacents. Ce travail souligne l'importance et la complexité de la régulation des canaux anioniques et potassiques et ce, dans les processus de signalisation et la mécanistique menant à la mort cellulaire programmée chez les plantes. Ozone ROS Canaux ioniques Mort cellulaire programmée Signalisation cellulaire Calcium Arabidopsis thaliana
732	Gene expression profiling in different stages of development of Arabidopsis thaliana leaftrichomes at the single cell level Kryvych, Sergiy January 2007 (has links) Each organ of a multicellular organism is unique at the level of its tissues and cells. Furthermore, responses to environmental stimuli or developmental signals occur differentially at the single cell or tissue level. This underlines the necessity of precise investigation of the “building block of life” -the individual cell. Although recently large amount of data concerning different aspects of single cell performance was accumulated, our knowledge about development and differentiation of individual cell within specialized tissue are still far from being complete. To get more insight into processes that occur in certain individual cell during its development and differentiation changes in gene expression during life cycle of A. thaliana leaf hair cell (trichome) were explored in this work. After onset of trichome development this cell changes its cell cycle: it starts endoreduplication (a modified cell cycle in which DNA replication continues in the absence of mitosis and cytokinesis). This makes trichomes a suitable model for studying cell cycle regulation, regulation of cell development and differentiation. Cells of interest were sampled by puncturing them with glass microcapillaries. Each sample contained as few as ten single cells. At first time trichomes in initial stage of trichome development were investigated. To allow their sampling they were specifically labelled by green fluorescent protein (GFP). In total three cell types were explored: pavement cells, trichome initials and mature trichomes. Comparison of gene expression profiles of these cells allowed identification of the genes differentially expressed in subsequent stages of trichome development. Bioinformatic analysis of genes preferentially expressed in trichome initials showed their involvement in hormonal, metal, sulphur response and cell-cycle regulation. Expression pattern of three selected candidate genes, involved in hormonal response and early developmental processes was confirmed by independent method. Effects of mutations in these genes on both trichome and plant development as well as on plant metabolism were analysed. As an outcome of this work novel components in the sophisticated machinery of trichome development and cell cycle progression were identified. These factors could integrate hormone stimuli and network interactions between characterized and as yet unknown members of this machinery. I expect findings presented in this work to enhance and complement our current knowledge about cell cycle progression and trichome development, as well as about performance of the individual cell in general. / Jedes Organ eines vielzelligen Organismus weißt einzigartige Merkmale auf seiner Gewebe und Zellebene auf. Darüber hinaus, werden entwicklungsabhängige sowie aus der Umwelt empfangene Signale zelltypspezifisch interpretiert. Aus dieser Spezialisierung einzelner Zellen ergibt sich somit unmittelbar die Notwendigkeit einzelne Zellen, als Bausteine komplexer Organe, individuell zu untersuchen. Obwohl in den letzten Jahrzehnten große Datenmengen über verschiedene Aspekte einzelner Zellen akkumuliert wurden, ist das Gesamtbild der Differenzierung und Entwicklung individueller Zellen in einem vielzelligen Organismus weitgehend unbekannt. Um der Frage nachzugehen, welche Prozesse sich in einer einzelnen Zelle während ihrer Differenzierung und Entwicklung abspielen, wurden Genexpressionsprofile einzelner Blatthaarzellen der Pflanze Arabidopsis thaliana in verschiedene Entwicklungsstadien erstellt. Nach dem Beginn der Entwicklung einer Protodermalzelle in ein Blatthaar (Trichom) kommt es zu einem Umschalten des Zellzyklus; Endoreduplikation setzt ein. Dies bedeutet, dass DNA repliziert wird, aber keine Zellteilung mehr stattfindet. Aus diesem Grunde eignen sich heranwachsende Trichome besonders gut Mechanismen zu erforschen, die in Verbindung mit der Zellzyklusregulation und Zellentwicklung stehen. Die Inhalte ausgewählter Einzelzellen wurden mit Glasmikrokapillaren extrahiert. Jeweils zehn derartige Einzelzellextrakte wurden daraufhin vereint. Als besonders hervorzuheben gilt, dass es uns in dieser Studie zum ersten mal überhaupt gelang die Inhalte einzelner Trichomzellen in ganz frühen Entwicklungsstadien zu extrahieren und anschließend zu analysieren. Um die Extraktion der Inhalte dieser frühen Zellstadien überhaupt zu ermöglichen, war es erforderlich diese mit dem grün fluoreszierenden Protein (GFP) zu markieren. Neben den Trichominitialzellen wurden ausgewachsene Trichomzellen sowie Epidermiszellen (Pavementzellen) mittels der Einzelzelltechnik untersucht. Ein Vergleich der erstellten Genexpressionsprofile dieser drei Zelltypen ermöglichte es Gene zu identifizieren, die in den ausgewählten Entwicklungsstadien der Trichombildung differentiell induziert wurden. Mittels bioinformatischer Analysemethoden gelang es, Gruppen von Genen zu identifieren, die exklusiv in Trichominitialzellen exprimiert sind und den Kategorien, Hormonregulation, Metallhomeostase, Schwefelstoffwechesol sowie Zellzyklusregulation zuzuordnen sind. Weiterhin wurde das Expressionsmuster dreier ausgewählter Kandidatengene mit alternativen Techniken verifiziert. Die ausgewählten Kandidatengene gehörten den Katergorien, Hormonrespons sowie frühe Entwicklungsprozesse, an. Darüber hinaus wurden Mutanten in allen drei Gene erzeugt und der Einfluss dieser Mutationen auf die Trichomentwicklung analysiert. Ein weiterer Aspekt der Mutantenanalyse lag in der Erstellung von Metabolitenprofilen ausgewählter Mutanten. Als ein wesentliches Ziel dieser Arbeit gelang es mir bisher unbekannte Komponenten in der Trichomentwicklung und damit der Zellzyklusregulation zu identifizieren. Diese neu identifizierten Komponenten führen zu einer Integration der hormonellen Kontrolle der Zellteilung und Entwicklung mit bisher unbekannten Faktoren. Ich erwarte, dass die von mir erbrachten Ergebnisse zu einem tieferen Verständnis der Prozesse, die an der Trichomentwicklung sowie an der Zellzyklusregulation beteiligt sind, beitragen. Insbesondere, zu einem erweiterten Verständnis des Verhaltens individueller Zellen in einem vielzelligen Organismus. Arabidopsis thaliana Single cell level Gene expression profiling Cell cycle Plant hormones Leaf trichomes Trichome initial cells Life sciences
733	Dissecting the photosystem II light-harvesting antenna Andersson, Jenny January 2003 (has links) In photosynthesis, sunlight is converted into chemical energy that is stored mainly as carbohydrates and supplies basically all life on Earth with energy. In order to efficiently absorb the light energy, plants have developed the outer light harvesting antenna, which is composed of ten different protein subunits (LHC) that bind chlorophyll a and b as well as different carotenoids. In addition to the light harvesting function, the antenna has the capacity to dissipate excess energy as heat (feedback de-excitation or qE), which is crucial to avoid oxidative damage under conditions of high excitation pressure. Another regulatory function in the antenna is the state transitions in which the distribution of the trimeric LHC II between photosystem I (PS I) and II is controlled. The same ten antenna proteins are conserved in all higher plants and based on evolutionary arguments this has led to the suggestion that each protein has a specific function. I have investigated the functions of individual antenna proteins of PS II (Lhcb proteins) by antisense inhibition in the model plant Arabidopsis thaliana. Four antisense lines were obtained, in which the target proteins were reduced, in some cases beyond detection level, in other cases small amounts remained. The results show that CP29 has a unique function as organising the antenna. CP26 can form trimers that substitute for Lhcb1 and Lhcb2 in the antenna structure, but the trimers that accumulate as a response to the lack of Lhcb1 and Lhcb2 cannot take over the LHC II function in state transitions. It has been argued that LHC II is essential for grana stacking, but antisense plants without Lhcb1 and Lhcb2 do form grana. Furthermore, LHC II is necessary to maintain growth rates in very low light. Numerous biochemical evidences have suggested that CP29 and/or CP26 were crucial for feedback de-excitation. Analysis of two antisense lines each lacking one of these proteins clearly shows that there is no direct involvement of either CP29 or CP26 in this process. Investigation of the other antisense lines shows that no Lhcb protein is indispensable for qE. A model for feedback de-excitation is presented in which PsbS plays a major role. The positions of the minor antenna proteins in the PS II supercomplex were established by comparisons of transmission electron micrographs of supercomplexes from the wild type and antisense plants. A fitness experiment was conducted where the antisense plants were grown in the field and seed production was used to estimate the fitness of the different genotypes. Based on the results from this experiment it is concluded that each Lhcb protein is important, because all antisense lines show reduced fitness in the field. Plant physiology antisense Arabidopsis thaliana chlorophyll carotenoid feedback de-excitation fitness LHC NPQ photosynthesis state transitions xanthophyll Växtfysiologi Plant physiology Växtfysiologi
734	Natural variation in cold adaptation and freezing tolerance in Arabidopsis thaliana Bos, Antoine January 2008 (has links) Plants have spread to almost everywhere in the world. As they disperse, they meet many different environments to which they may be able to adapt. For a plant species to adapt to a new environment, genetic variation is needed. The individuals differ from each other in their genetic composition, which often means differences in phenotypes. Those individuals that manage to reproduce will form the next generation. With different conditions in different environments, it will not be the same phenotypes that reproduce everywhere. In that way, plant species will form into a mosaic of locally adapted populations varying genetically as the species disperses. After the last ice age plants have started to disperse away from the equators. With increasing latitudes come increasing challenges to migrating plants. As plant species disperse northwards along this gradient of varying conditions individuals are selected for cold adaptive traits like flowering time and freezing tolerance, acquired by cold acclimation. In this way, genetic variation from the original populations for these traits becomes sorted out along a latitudinal cline. The aim of this thesis was to understand how selection along a latitudinal gradient has shaped natural variation in cold adaptive traits in plants dispersing northwards, and specifically, to investigate what variation can be observed in phenotypes for these traits and how these traits correlate with genetic variation in genes known to be involved in cold acclimation. In this study significant variation was found in a sample of the model plan Arabidopsis thaliana accessions in cold adaptive traits flowering time and freezing tolerance. A clear latitudinal cline in the cold adaptive traits freezing tolerance for A. thaliana was observed. Analysis of nucleotide polymorphism for the cold responsive ICE1 (inducer of CBF expression 1) transcription factor revealed a haplotype structure with two allelic clades as well as unusually high levels of synonymous polymorphism. Nucleotide polymorphism analysis for the transcription factors CBF1, CBF2 and CBF3 (C-repeat binding factors) that play a key role in regulating the expression of a group of target genes known as the “CBF regulon” showed a distinct geographical haplotype structure. One haplotype was dominant in southern accessions while in the other northern accessions overrepresented. There was a significant effect of CBF haplotype on both freezing tolerance and flowering time even after correcting for latitude. Significant differences in CBF expression levels were found between the different CBF genes as well as between different accessions. Sequence variation at CBF was shown to have a significant effect on expression levels of CBF2. No clear correlations were found between CBF gene expression and freezing tolerance or temperature sensitivity for any of the accessions used in the study. This highlights the complex relationship between sequence variation in candidate genes and gene expression, and the problems associated with unraveling the genetic basis of ecologically important traits. Arabidopsis thaliana cold acclimation freezing tolerance flowering time latitudinal clines genetic variation evolutionary genetics Molecular biology Molekylärbiologi
735	Mechanism of Vein Pattern Formation in Arabidopsis Thaliana Leaves: testing the Canalization Hypothesis Amin, Mira 22 August 2011 (has links) Several mechanisms have been proposed to explain the process of vein pattern formation in plant tissues. The most widely accepted amongst biologists is the canalization hypothesis, derived from pea root and stem experiments. According to this hypothesis, a signal, thought to be the phytohormone auxin, is transported polarly from cell to cell from the shoot to the root and is canalized progressively into narrow channels of high auxin fluxes that later differentiate to become vascular tissue. In this project, we set out to test whether auxin canalization drives vein pattern formation, using Arabidopsis thaliana mutants with increased auxin transport (max4-1, max3-9, max2-1 and max1-1). We predicted that the mutants would have distinct vein patterns and especially different angles between the primary and secondary veins, compared to the wild type. First rosette leaves of 15 plants per genotype were harvested for analysis each day from 7 to 17 days after sowing, giving a total of eight hundred twenty-five leaf samples to analyze. Venation patterns were extracted and analyzed using custom-made software written with Matlab. Overall, compared with the wild type, mutants with the highest auxin transport (max4-1 and max3-9) had different vein patterns at early developmental stages, confirming a role for auxin transport in vein patterning. However, veins of mutants and wild type connected at similar angles, which is not consistent with the auxin canalization hypothesis, as originally formulated. Auxin Arabidopsis thaliana Canalization hypothesis Vein pattern formation Leaves More axillary growth (MAX)
736	Rôle de la signalisation phospholipidique dans la voie de réponse à l'acide salicylique chez Arabidopsis thaliana Krinke, Ondrej 19 July 2007 (has links) (PDF) Chez les plantes, l'acide salicylique (SA) a un rôle central dans la réponse à de nombreuses contraintes environnementales et lors du développement. Cependant les événements de signalisation précoces qu'il déclenche sont peu connus. Nous montrons, par marquage métabolique au 33Pi sur une suspension cellulaire d'Arabidopsis thaliana, que le SA induit une diminution rapide et précoce d'un pool de phosphatidylinositol (PI). Celle-ci est accompagnée d'une accumulation de PI 4-phosphate et PI 4,5-bisphosphate. Ces changements sont inhibés par de la wortmannine à 30 μM mais pas à 1 μM, ce qui implique une activation de PI 4-kinase de type III. C'est pourquoi une étude des effets de la wortmannine sur les modifications de transcriptome par le SA a été menée à l'aide de la puce " Complete Arabidopsis Transcriptome MicroArray " (CATMA). Sur 773 gènes régulés par le SA, 112 sont sensibles à 30 μM de wortmannine. En parallèle, nous voyons que l'acide phosphatidique issu de la phospholipase D (PLD) est important pour la réponse génique précoce au SA. Une expérience de puces menée pour identifier les gènes régulés par la PLD en réponse au SA a révélé que parmi 1327 gènes régulés par le SA, 97 gènes sont régulés positivement, et 117 gènes négativement, par la PLD. Les régulons de la voie sensible à la wortmannine et de la voie PLD se chevauchent fortement, ce qui suggère que les deux activités agissent en synergie dans la même voie de signalisation en réponse au SA. Arabidopsis thaliana Phosphatidylinositol 4-kinase Phospholipase D Signalisation phospholipidique Acide salicylique Transcriptome
737	Functional Studies of the <i>Arabidopsis thaliana</i> Ubc13-Uev Complex Wen, Rui 20 September 2010 Ubiquitination is an important biochemical reaction found in all eukaryotic organisms and is involved in a wide range of cellular processes. Conventional ubiquitination requires the formation of polyubiquitin chains linked through Lys48 of the ubiquitin, which targets proteins for degradation, while the noncanonical Lys63-linked polyubiquitination of the proliferating cell nuclear antigen is required for error-free DNA damage tolerance (DDT or postreplication repair) in yeast. The ubiquitin-conjugating enzyme <i>Ubc13</i> and a cognate Ubc enzyme variant (Uev or Mms2) are involved in this process. Because there is less information available on either Lys63-linked ubiquitination or error-free DDT in plants, the goal of my research was to study the functions of <i>Ubc13</i> and Uev in plants using <i>Arabidopsis thaliana</i> as the model organism.<p> Four <i>UEV1</i> genes from <i>Arabidopsis thaliana</i> were isolated and characterized. All four <i>Uev1</i> proteins can form a stable complex with AtUbc13 and can promote <i>Ubc13</i> mediated Lys63 polyubiquitination. All four <i>UEV1</i> genes can replace yeast MMS2 in DDT function in vivo. Although these genes are ubiquitously expressed in most tissues, <i>UEV1D</i> appears to be expressed at a much higher level in germinating seeds and pollen. We obtained and characterized two <i>uev1d</i> null mutant T-DNA insertion lines. Compared with wild-type plants, seeds from uev1d null plants germinated poorly when treated with a DNA-damaging agent. Seeds that germinated grew slow and the majority ceased growth within 2 weeks. Pollen from uev1d plants also displayed a moderate but significant decrease in germination in the presence of DNA damage agent. These results indicate that <i>Ubc13-Uev</i> complex functions in DNA damage response in <i>Arabidopsis thaliana.</i> <i>Arabidopsis thaliana</i> contains two <i>UBC13</i> genes, AtUBC13A and AtUBC13B, that are highly conserved with respect to DNA sequence, protein sequence and genomic organization, suggesting that they are derived from a recent gene duplication event. Both <i>AtUbc13</i> proteins are able to physically interact with human and yeast Mms2, implying that plants also employ a Lys63-linked polyubiquitination reaction. Furthermore, Both <i>AtUBC13</i> genes were able to functionally complement the yeast ubc13 null mutants, suggesting the existence of an error-free DNA damage tolerance pathway in plants. The <i>AtUBC13</i> genes appear to be expressed ubiquitously and were not induced by various conditions tested.<p> The <i>ubc13a/b</i> double mutant lines were created and displayed strong phenotypic changes. The double mutant plants were delayed in seed germination as well as cotyledon and true leaf development. When seedlings were grown vertically on plates, the roots of the double mutant were shorter and grew in a zig-zag manner, compared to the straight growth of wild type roots. Root length and number of lateral roots on wild type and <i>ubc13a</i> and <i>ubc13b</i> single mutant plants were about 3 times longer than those of double mutant plants after 9 and 12 days of growth. When double mutant seeds were sown directly into soil, many did not germinate and those that germinated grew much slower than wild type. At 35 days, double mutant plants were smaller with thinner, flatter, and lighter coloured rosette leaves compared to wild type plants. These phenotypes indicate that <i>AtUbc13</i> not only plays a role in DDT to protect genome integrity but also is involved in plant development. Hence, this study set a cornerstone for future investigations into the roles of <i>Ubc13</i> and <i>Uev1</i> in plant development. error-free DNA damage tolerance Arabidopsis thaliana Ubquitin-conjugating enzyme 13 Lys63-linked ubiquitination Ubiquitin-conjugating enzyme variant
738	Regulation de transcription plastidique par des facteurs sigma et ARNs anti-sense chez Arabidopsis Thaliana. Mustafa, Malik Ghulam 15 December 2010 (has links) (PDF) Les chloroplastes, responsables de la photosynthèse chez les organismes autotrophes, possèdent un génome plastidial codant de 100 à 130 gènes dont environ 80 pour des protéines principalement impliquées dans la photosynthèse, la transcription et la traduction. L'expression de ces gènes, coordonnée entre le plaste et le noyau, implique deux types d'ARN polymérases, la NEP (Nucleus Encoded RNA Polymerase) et la PEP (plastid Encoded RNA Polymerase) laquelle s‟associe à l‟un des 6 facteurs sigma (SIG), codés dans le noyau pour la reconnaissance spécifique de promoteurs de transcription. Nous avons tout d‟abord analysé le rôle de ces facteurs sigma dans la régulation transcriptionnelle des deux opérons codant des sous-unités de l‟ATP synthase, atpI/H/F/A et atpB/E, en précisant le rôle particulier de SIG3 dans la reconnaissance spécifique du promoteur (-418) de l‟atpH. Nous avons identifié les promoteurs des transcrits polycistronique et ceux situés en amont des gènes atpH et atpE, et avons montré (1) que les gènes des deux opérons sont co-régulés par SIG3 et SIG2 sauf atpI régulé par SIG2 seul et (2), que SIG3 jouerait un rôle essentiel dans la surexpression monocistronique d‟atpH par la reconnaissance d‟un promoteur (-418) en amont de atpH. L‟analyse systématique des transcrits plastidiaux accumulés en fonction de l‟éclairement des plantes nous a permis de corréler cette surexpression à un éclairement élevé (1300 μE) de plantes matures. SIG3 reconnaît aussi spécifiquement le promoteur de psbN, gène localisé sur le brin opposé de l‟opéron psbB/T/H/petB/petD, produisant un ARN anti-sens de psbT et de la région intergénique psbT/psbH. Nos résultats montrent que l‟anti-sens de psbT couvre la région codante, le 5'UTR et la quasi-totalité 3' UTR du transcrit sens psbT, pouvant ainsi réguler la production de PSBT en interférant dans la traduction par la formation d‟un duplex ARN. L‟anti-sens pourrait aussi intervenir dans le processing dans la région 5‟ UTR de psbH. Arabidopsis thaliana Chloroplast transcription facteur sigma sigma3 ARNs anti sense operon ATP
739	Functional Studies of the <i>Arabidopsis thaliana</i> Ubc13-Uev Complex Wen, Rui 20 September 2010 (has links) Ubiquitination is an important biochemical reaction found in all eukaryotic organisms and is involved in a wide range of cellular processes. Conventional ubiquitination requires the formation of polyubiquitin chains linked through Lys48 of the ubiquitin, which targets proteins for degradation, while the noncanonical Lys63-linked polyubiquitination of the proliferating cell nuclear antigen is required for error-free DNA damage tolerance (DDT or postreplication repair) in yeast. The ubiquitin-conjugating enzyme <i>Ubc13</i> and a cognate Ubc enzyme variant (Uev or Mms2) are involved in this process. Because there is less information available on either Lys63-linked ubiquitination or error-free DDT in plants, the goal of my research was to study the functions of <i>Ubc13</i> and Uev in plants using <i>Arabidopsis thaliana</i> as the model organism.<p> Four <i>UEV1</i> genes from <i>Arabidopsis thaliana</i> were isolated and characterized. All four <i>Uev1</i> proteins can form a stable complex with AtUbc13 and can promote <i>Ubc13</i> mediated Lys63 polyubiquitination. All four <i>UEV1</i> genes can replace yeast MMS2 in DDT function in vivo. Although these genes are ubiquitously expressed in most tissues, <i>UEV1D</i> appears to be expressed at a much higher level in germinating seeds and pollen. We obtained and characterized two <i>uev1d</i> null mutant T-DNA insertion lines. Compared with wild-type plants, seeds from uev1d null plants germinated poorly when treated with a DNA-damaging agent. Seeds that germinated grew slow and the majority ceased growth within 2 weeks. Pollen from uev1d plants also displayed a moderate but significant decrease in germination in the presence of DNA damage agent. These results indicate that <i>Ubc13-Uev</i> complex functions in DNA damage response in <i>Arabidopsis thaliana.</i> <i>Arabidopsis thaliana</i> contains two <i>UBC13</i> genes, AtUBC13A and AtUBC13B, that are highly conserved with respect to DNA sequence, protein sequence and genomic organization, suggesting that they are derived from a recent gene duplication event. Both <i>AtUbc13</i> proteins are able to physically interact with human and yeast Mms2, implying that plants also employ a Lys63-linked polyubiquitination reaction. Furthermore, Both <i>AtUBC13</i> genes were able to functionally complement the yeast ubc13 null mutants, suggesting the existence of an error-free DNA damage tolerance pathway in plants. The <i>AtUBC13</i> genes appear to be expressed ubiquitously and were not induced by various conditions tested.<p> The <i>ubc13a/b</i> double mutant lines were created and displayed strong phenotypic changes. The double mutant plants were delayed in seed germination as well as cotyledon and true leaf development. When seedlings were grown vertically on plates, the roots of the double mutant were shorter and grew in a zig-zag manner, compared to the straight growth of wild type roots. Root length and number of lateral roots on wild type and <i>ubc13a</i> and <i>ubc13b</i> single mutant plants were about 3 times longer than those of double mutant plants after 9 and 12 days of growth. When double mutant seeds were sown directly into soil, many did not germinate and those that germinated grew much slower than wild type. At 35 days, double mutant plants were smaller with thinner, flatter, and lighter coloured rosette leaves compared to wild type plants. These phenotypes indicate that <i>AtUbc13</i> not only plays a role in DDT to protect genome integrity but also is involved in plant development. Hence, this study set a cornerstone for future investigations into the roles of <i>Ubc13</i> and <i>Uev1</i> in plant development. error-free DNA damage tolerance Arabidopsis thaliana Ubquitin-conjugating enzyme 13 Lys63-linked ubiquitination Ubiquitin-conjugating enzyme variant
740	Mechanism of Vein Pattern Formation in Arabidopsis Thaliana Leaves: testing the Canalization Hypothesis Amin, Mira 22 August 2011 (has links) Several mechanisms have been proposed to explain the process of vein pattern formation in plant tissues. The most widely accepted amongst biologists is the canalization hypothesis, derived from pea root and stem experiments. According to this hypothesis, a signal, thought to be the phytohormone auxin, is transported polarly from cell to cell from the shoot to the root and is canalized progressively into narrow channels of high auxin fluxes that later differentiate to become vascular tissue. In this project, we set out to test whether auxin canalization drives vein pattern formation, using Arabidopsis thaliana mutants with increased auxin transport (max4-1, max3-9, max2-1 and max1-1). We predicted that the mutants would have distinct vein patterns and especially different angles between the primary and secondary veins, compared to the wild type. First rosette leaves of 15 plants per genotype were harvested for analysis each day from 7 to 17 days after sowing, giving a total of eight hundred twenty-five leaf samples to analyze. Venation patterns were extracted and analyzed using custom-made software written with Matlab. Overall, compared with the wild type, mutants with the highest auxin transport (max4-1 and max3-9) had different vein patterns at early developmental stages, confirming a role for auxin transport in vein patterning. However, veins of mutants and wild type connected at similar angles, which is not consistent with the auxin canalization hypothesis, as originally formulated. Auxin Arabidopsis thaliana Canalization hypothesis Vein pattern formation Leaves More axillary growth (MAX)

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