Global ETD Search

531	The significance of feedback de-excitation Külheim, Carsten January 2005 (has links) <p>During photosynthesis sunlight is absorbed by photosynthetic pigments and converted into organic compounds, such as carbohydrates. Photosynthesis needs to be highly regulated, since both too much and too little light are harmful to plant. If too little light is absorbed, a plant cannot store enough energy, which will have effects on growth and fitness of the plant. With too much light absorbed, a dangerous side reaction of photosynthesis, the production of reactive oxygen species can happen. These reactive oxygen species can damage the proteins in the chloroplast and the lipids of the chloroplast.</p><p>To avoid the production of reactive oxygen species, plants have evolved many mechanisms, which act on different time-scales and different levels of organization. As a first measure, when the absorbed light is exceeding the capacity for its utilization, is to switch the light-harvesting antenna from efficient light harvesting to energy dissipation. This process is called feedback de-excitation (FDE). The protein PsbS is essential for this process as well as a functioning xanthophylls cycle with the enzyme violaxanthin de-epoxidase (VDE).</p><p>I have investigated the effects of plants with changes in their ability to dissipate excess excitation energy in the model plants species Arabidopsis thaliana. Three genotypes with either increased or decreased capacity for FDE were used during my experiments. The first genotype over-expresses the PsbS gene, having approximately two-fold increased amounts of PsbS and FDE. The second is a PsbS deletion mutant with no PsbS protein and no FDE. The third genotype cannot perform the conversion of violaxanthin to zeaxanthin, because the enzyme VDE is missing. This mutant has some FDE left. </p><p><i>Arabidopsis thaliana</i> is an annual plant, which flowers only once in its lifetime. Therefore, when counting the seeds produced an estimation of fitness can be made from the amount of seeds produced. This was done during my experiments and shown that FDE is a trait and that plants with increased FDE have a higher fitness and vice versa. </p><p>This was also the case for a collection of plants lacking a single protein from the light harvesting antenna. All of these genotypes had a fitness reduction, proving that their function is not redundant. </p><p>In an attempt to explain why the fitness is reduced in plants with altered FDE, photosynthetic measurements, as well as a determination of the transcriptome and the metabolome was performed. Plants lacking FDE had higher levels of photoinhibition, leading both to lower rates of photosynthesis and to higher repair cost. This could in part explain the reduction in fitness. These plants also had major changes in their transcriptome and their metabolome. Primary metabolism was most effected, for example carbohydrate and amino acid metabolism. But there were also changes in secondary metabolism such as an up regulation of the biosynthesis of anthocyanins.</p> Arabidopsis thaliana photosynthesis feedback de-excitation fitness metabolomics transcriptomics Plant physiology Växtfysiologi
532	Studies on the Role of UDP-Glucose Dehydrogenase in Polysaccharide Biosynthesis Roman, Elisabet January 2004 (has links) <p>Polysaccharides are found in all forms of life and serve diverse purposes. They are enzymatically synthesised from activated monosaccharide precursors, nucleotide sugars. One such nucleotide sugar is UDP-glucuronic acid, which is formed from UDP-glucose by the UDP-glucose dehydrogenase (UGDH) enzyme. UGDH has been proposed to have a regulatory role in the biosynthesis of polysaccharides. The aim of the studies presented in this thesis was to investigate the role of UGDH in the polysaccharide biosynthesis in three different systems: human cell culture, bacterial cultures<i> </i>and growing<i> </i>plants<i>. </i>The effects of UGDH-overexpression on polysaccharide biosyntheses and, when achievable, on UDP-sugar levels, were investigated.</p><p>A mammalian UGDH was cloned from a kidney cDNA library. Transient expression of the cloned enzyme in mammalian cells led to an increased UGDH-activity. Northern blotting analyses revealed a single transcript of 2.6 kb in adult mouse tissues whereas human tissues expressed a predominant transcript of 3.2 kb and a minor transcript of 2.6 kb.</p><p>Overexpression of the bovine UGDH in mammalian cells induced increased synthesis of the glycosaminoglycans; heparan sulphate, chondroitin sulphate and hyaluronan, without changing their relative proportions. The effects on glycosaminoglycan synthesis caused by an increased demand of UDP-glucuronic acid were studied by overexpression of hyaluronan synthase (Has3), which requires UDP-glucuronic acid as substrate. Overexpression of Has3 and coexpression of Has3 and UGDH resulted in highly augmented production of hyaluronan without noticeably affecting heparan sulfate and chondroitin sulfate synthesis.</p><p>Expression of the bacterial UGDH in <i>E. coli</i> resulted in increased formation of UDP-glucuronic acid, but, unexpectedly, also to synthesis of fewer K5 polysaccharide chains. </p><p>Overexpression of UGD1, one of four <i>A. thaliana</i> UGDH genes, in <i>A. thaliana,</i> resulted in dwarfism. Analysis of the cell wall polysaccharides showed alteration in saccharide composition. Paradoxically, the UDP-sugars derived from UDP-glucuronic acid decreased in amount.</p> Biochemistry UDP-glucose dehydrogenase polysaccharide biosynthesis glycosaminoglycan A. thaliana E. coli K5 Biokemi Biochemistry Biokemi
533	The Role of the Homeobox Gene ATHB16 in Development Regulation in Arabidopsis thaliana Wang, Yan January 2001 (has links) <p>There are 42 members of the homeodomain-leucine zipper (HDZip) family of transcription factors in <i>Arabidopsis thaliana</i>. This thesis focuses on the functional analysis of one member of this family, ATHB16, and on the biochemical properties of HDZip proteins. </p><p>To assess the function of the <i>ATHB16</i> gene, the expression of <i>ATHB16</i> was altered in transgenic Arabidopsis plants by using sense and antisense RNA constructs under the control of the 35S promoter. The reciprocal phenotypic effects associated with elevated and reduced levels of <i>ATHB16</i> expression suggested that, in wild-type plants, ATHB16 acts as a mediator of blue and red light effects on the regulation of plant growth and the timing of the floral transition. </p><p>In wild-type Arabidopsis, expression of <i>ATHB16</i> is high in leaves, intermediate in adult roots and inflorescences, and low in stems and siliques. The expression of <i>ATHB16</i> in the root is markedly increased in response to exogenous abscisic acid (ABA) treatment, but is reduced in the ABA response mutants <i>abil </i>and <i>abi2</i>, suggesting that <i>ATHB16</i> may be involved in ABA signal transduction. This hypothesis was corroborated by observations of alterations in sensitivity to ABA inhibition of root growth in seedlings of a T-DNA insertion mutant of <i>ATHB16</i> and of transgenic plants with elevated <i>ATHB16</i> levels. </p><p>HDZip proteins bind DNA as dimers. DNA-binding studies showed that different HDZip proteins interact with very similar target sequences <i>in vitro</i> and that they selectively form heterodimers with each other. For example, it was demonstrated that ATHB16 can heterodimerize with ATHB6 and ATHB7 in yeast and with ATHB5 <i>in vitro</i>, suggesting that ATHB16 may interact with other HDZip proteins in Arabidopsis. This interaction may have functional significance, since it may provide a mechanism for the plant to integrate different input signals, like light of different spectral qualities and water availability in the regulation of its growth. </p> Developmental biology Arabidopsis thaliana Homeobox gene Functional genomics Plant development ATHB16 Utvecklingsbiologi Developmental biology Utvecklingsbiologi
534	LL-diaminopimelate aminotransferase: the mechanism of substrate recognition and specificity Watanabe, Nobuhiko 06 1900 (has links) Amino acid biosynthesis is an essential process in living organisms. Certain amino acids can be synthesized by some organisms but not by others. L-Lysine is one of the essential amino acids that bacteria can synthesize but humans cannot. This is somewhat inconvenient for humans as much of their L-lysine must come from their diet. However, the lack of the lysine biosynthetic pathway in humans makes the bacterial enzymes within the pathway attractive drug targets. Recently, a novel lysine biosynthetic pathway was discovered in plants, Chlamydiae and some archaea. It is called the diaminopimelate aminotransferase (DAP-AT) pathway. In this pathway, LL-DAP-AT plays a key role by directly converting L-tetrahydrodipicolinate to LL-DAP in a single step. This is a quite interesting characteristic of LL-DAP-AT as the above conversion takes three sequential enzymatic steps in the previously known lysine biosynthetic pathways. Due to its absence in humans, LL-DAP-AT would be an attractive target for the development of novel antibiotics. In order to understand the catalytic mechanism and substrate recognition of LL-DAP-AT, the structural characterization of LL-DAP-AT is of paramount importance. In this thesis, the overall architecture of LL-DAP-AT and its substrate recognition mechanism revealed by the crystal structures of LL-DAP-AT from Arabidopsis thaliana and Chlamydia trachomatis will be discussed. The crystal structure of the native LL-DAP-AT from A. thaliana (AtDAP-AT) presented in this thesis is the first structure of LL-DAP-AT to be determined. This structure revealed that LL-DAP-AT forms a functional homodimer and belongs to the type I fold family of PLP dependent aminotransferases. The subsequent determination of the substrate-bound AtDAP-AT structure showed how the two substrates, (LL-DAP and L-Glu) significantly different in size, are recognized by the same set of residues without significant conformational changes in the backbone structure. In addition, the LL-DAP-bound AtDAP-AT structure shows that the C-amino group of LL-DAP is recognized stereospecifically by the active site residues that are unique to the family of LL-DAP-AT enzymes. Lastly, the chlamydial LL-DAP-AT presented in this thesis shows a new open conformation for LL-DAP-AT. The implications of the conformational flexibility of CtDAP-AT on the differences in substrate specificities among LL-DAP-AT are discussed. Lysine biosynthesis Pyridoxal 5'-phosphate LL-diaminopimelate aminotransferase Chlamydia trachomatis Arabidopsis thaliana
535	Functional analysis of the sucrose synthase gene family in Arabidopsis thaliana Bieniawska, Zuzanna January 2006 (has links) Sucrose synthase (Susy) is a key enzyme of sucrose metabolism, catalysing the reversible conversion of sucrose and UDP to UDP-glucose and fructose. Therefore, its activity, localization and function have been studied in various plant species. It has been shown that Susy can play a role in supplying energy in companion cells for phloem loading (Fu and Park, 1995), provides substrates for starch synthesis (Zrenner et al., 1995), and supplies UDP-glucose for cell wall synthesis (Haigler et al., 2001). Analysis of the Arabidopsis genome identifies six Susy isoforms. The expression of these isoforms was investigated using promoter-reporter gene constructs (GUS) and real time RT-PCR. Although these isoforms are closely related at the protein level they have radically different spatial and temporal patterns of expression in the plant with no two isoforms showing the same distribution. More than one isoform is expressed in all organs examined. Some of them have high but specific expression in particular organs or developmental stages whilst others are constantly expressed throughout the whole plant and across various stages of development. The in planta function of the six Susy isoforms were explored through analysis of T-DNA insertion mutants and RNAi lines. Plants without the expression of individual isoforms show no differences in growth and development, and are not significantly different from wild type plants in soluble sugars, starch and cellulose contents under all growth conditions investigated. Analysis of T-DNA insertion mutant lacking Sus3 isoform that was exclusively expressed in stomata cells only had a minor influence on guard cell osmoregulation and/or bioenergetics. Although none of the sucrose synthases appear to be essential for normal growth under our standard growth conditions, they may be necessary for growth under stress conditions. Different isoforms of sucrose synthase respond differently to various abiotic stresses. It has been shown that oxygen deprivation up regulates Sus1 and Sus4 and increases total Susy activity. However, the analysis of the plants with reduced expression of both Sus1 and Sus4 revealed no obvious effects on plant performance under oxygen deprivation. Low temperature up regulates Sus1 expression but the loss of this isoform has no effect on the freezing tolerance of non acclimated and cold acclimated plants. These data provide a comprehensive overview of the expression of this gene family which supports some of the previously reported roles for Susy and indicates the involvement of specific isoforms in metabolism and/or signalling. / Saccharose spielt eine zentrale Rolle in höheren Pflanzen. Es zählt zu den wichtigsten Kohlenhydraten und wird als Nährstoff, Speicherstoff (z.B. in Zuckerrüben, Zuckerrohr, Mohrrüben) oder auch als potentielles Signalmolekül verwendet. Saccharose ist eines der primären Endprodukte der Photosynthese in den grünen Blättern der Pflanzen, kann aber auch in nicht-photosynthetisch aktiven Geweben (z.B. in keimenden Samen) synthetisiert und verstoffwechselt werden. Die Saccharosesynthase (Susy) stellt ein Schlüsselenzym im Saccharosestoffwechsel dar. Es katalysiert die reversible Umwandlung von Saccharose zu UDP-Glukose und Fruktose. Die Aktivität, die Lokalisierung und die Funktionen der Susy wurden bereits in verschiedenen Pflanzenarten untersucht. Dabei hatte sich herausgestellt, daß die Susy eine wichtige Rolle in der Bereitstellung von Energie für Transportprozesse spielt. Außerdem stellt Susy die Substrate für die Stärkesynthese in Speichergeweben, sowie fast alle Substrate für die Zellwandsynthese bereit. Eine Untersuchung des Genoms von Arabidopsis thaliana ergab, daß die Ackerschmalwand sechs Isoformen der Susy besitzt. Die Expression dieser Isoformen wurde mittels Echtzeit RT-PCR analysiert. Obwohl die verschiedenen Isoformen auf Proteinebene in ihrer Sequenz sehr ähnlich sind, zeigen sie Unterschiede in ihrem zeitlichen und räumlichen Auftreten innerhalb der Pflanze. Einige der Isoformen sind hoch exprimiert in speziellen Organen oder Entwicklungsstufen der Pflanze. Andere hingegen sind gleichmäßig in der ganzen Pflanze und über verschiedene Entwicklungsstufen hinaus exprimiert. In allen untersuchten Organen der Pflanze ist mehr als eine Isoform exprimiert. Um die spezifische Funktion der einzelnen Isoformen aufzuklären, wurden für alle sechs Saccharosesynthasen Mutanten-Linien isoliert und analysiert. Alle Pflanzen, bei denen die Expression einer bestimmten Isoform fehlte, zeigten im Vergleich zu Wildtyppflanzen keine signifikanten Unterschiede in Wachstum und Entwicklung. Des Weiteren waren die Gehalte an Stärke, Saccharose und Zellulose in Blättern und Wurzeln im Vergleich zu Wildtyppflanzen unverändert. Mutanten, denen die ausschließlich in Schließzellen lokalisierte Isoform Sus3 fehlte, zeigten nur geringe Veränderungen in der Osmoregulation und/oder der Bioenergetik der Schließzellen. Daraus kann gefolgert werden, dass in dem Ackerunkraut Arabidopsis keine der Saccharosesynthasen essentiell für normales Wachstum unter Standardbedingungen ist. Es ist jedoch möglich, dass Saccharosesynthasen unter Stressbedingungen benötigt werden. Es war bereits bekannt, dass einzelne Isoformen der Susy auf Stress reagieren und in ihrer Expression verändert sind. Es konnte gezeigt werden, daß Sauerstoffmangel zu einer Erhöhung der Expression der Isoformen Sus1 und Sus4 und zu einer Zunahme der Susy Gesamtaktivität führt. Die Analyse von Pflanzen mit reduzierter Expression von Sus1 und Sus4 zeigte jedoch, dass Sauerstoffmangel keinen offensichtlichen Einfluss auf das Wachstum dieser Pflanzen hat. Niedrige Temperaturen führen zu einer Erhöhung der Sus1 Expression, aber auch ein Verlust dieser Isoform hat keinen Einfluss auf die Gefriertoleranz von normalen oder an Kälte akklimatisierten Pflanzen. Diese Ergebnisse bieten einen umfassenden Einblick in die Expression der Genfamilie der Saccharosesynthase; sie untermauern die genannten Funktionen der Saccharosesynthase und weisen auf eine mögliche Beteiligung mehrerer Isoformen am Saccharosestoffwechsel und/oder der Signaltransduktion hin. Saccharose Synthase Genfamilie Ackerschmalwand sucrose synthase gene family Arabidopsis thaliana Life sciences
536	The Role of the Homeobox Gene ATHB16 in Development Regulation in Arabidopsis thaliana Wang, Yan January 2001 (has links) There are 42 members of the homeodomain-leucine zipper (HDZip) family of transcription factors in Arabidopsis thaliana. This thesis focuses on the functional analysis of one member of this family, ATHB16, and on the biochemical properties of HDZip proteins. To assess the function of the ATHB16 gene, the expression of ATHB16 was altered in transgenic Arabidopsis plants by using sense and antisense RNA constructs under the control of the 35S promoter. The reciprocal phenotypic effects associated with elevated and reduced levels of ATHB16 expression suggested that, in wild-type plants, ATHB16 acts as a mediator of blue and red light effects on the regulation of plant growth and the timing of the floral transition. In wild-type Arabidopsis, expression of ATHB16 is high in leaves, intermediate in adult roots and inflorescences, and low in stems and siliques. The expression of ATHB16 in the root is markedly increased in response to exogenous abscisic acid (ABA) treatment, but is reduced in the ABA response mutants abil and abi2, suggesting that ATHB16 may be involved in ABA signal transduction. This hypothesis was corroborated by observations of alterations in sensitivity to ABA inhibition of root growth in seedlings of a T-DNA insertion mutant of ATHB16 and of transgenic plants with elevated ATHB16 levels. HDZip proteins bind DNA as dimers. DNA-binding studies showed that different HDZip proteins interact with very similar target sequences in vitro and that they selectively form heterodimers with each other. For example, it was demonstrated that ATHB16 can heterodimerize with ATHB6 and ATHB7 in yeast and with ATHB5 in vitro, suggesting that ATHB16 may interact with other HDZip proteins in Arabidopsis. This interaction may have functional significance, since it may provide a mechanism for the plant to integrate different input signals, like light of different spectral qualities and water availability in the regulation of its growth. Developmental biology Arabidopsis thaliana Homeobox gene Functional genomics Plant development ATHB16 Utvecklingsbiologi Developmental biology Utvecklingsbiologi
537	Studies on the Role of UDP-Glucose Dehydrogenase in Polysaccharide Biosynthesis Roman, Elisabet January 2004 (has links) Polysaccharides are found in all forms of life and serve diverse purposes. They are enzymatically synthesised from activated monosaccharide precursors, nucleotide sugars. One such nucleotide sugar is UDP-glucuronic acid, which is formed from UDP-glucose by the UDP-glucose dehydrogenase (UGDH) enzyme. UGDH has been proposed to have a regulatory role in the biosynthesis of polysaccharides. The aim of the studies presented in this thesis was to investigate the role of UGDH in the polysaccharide biosynthesis in three different systems: human cell culture, bacterial cultures and growing plants. The effects of UGDH-overexpression on polysaccharide biosyntheses and, when achievable, on UDP-sugar levels, were investigated. A mammalian UGDH was cloned from a kidney cDNA library. Transient expression of the cloned enzyme in mammalian cells led to an increased UGDH-activity. Northern blotting analyses revealed a single transcript of 2.6 kb in adult mouse tissues whereas human tissues expressed a predominant transcript of 3.2 kb and a minor transcript of 2.6 kb. Overexpression of the bovine UGDH in mammalian cells induced increased synthesis of the glycosaminoglycans; heparan sulphate, chondroitin sulphate and hyaluronan, without changing their relative proportions. The effects on glycosaminoglycan synthesis caused by an increased demand of UDP-glucuronic acid were studied by overexpression of hyaluronan synthase (Has3), which requires UDP-glucuronic acid as substrate. Overexpression of Has3 and coexpression of Has3 and UGDH resulted in highly augmented production of hyaluronan without noticeably affecting heparan sulfate and chondroitin sulfate synthesis. Expression of the bacterial UGDH in E. coli resulted in increased formation of UDP-glucuronic acid, but, unexpectedly, also to synthesis of fewer K5 polysaccharide chains. Overexpression of UGD1, one of four A. thaliana UGDH genes, in A. thaliana, resulted in dwarfism. Analysis of the cell wall polysaccharides showed alteration in saccharide composition. Paradoxically, the UDP-sugars derived from UDP-glucuronic acid decreased in amount. Biochemistry UDP-glucose dehydrogenase polysaccharide biosynthesis glycosaminoglycan A. thaliana E. coli K5 Biokemi Biochemistry Biokemi
538	Mechanisms and genes controlling the signalling network for biotic and abiotic stress defences in Arabidopsis thaliana (L.) Heyhn : Functional cross-talk between photo-produced reactive oxygen species, photosynthesis and plant disease defence responses Chang, Christine Chi-Chen January 2005 (has links) Excess excitation energy, mechanical injury and defence against pathogens, each trigger rapid production of reactive oxygen species (ROS) in Arabidopsis thaliana leaves. ROS, such as hydrogen peroxide (H2O2), are required for the induction of systemic acquired acclimation and may lead to redox changes in photosynthetic electron transport (PET). On one hand, enhanced ROS production during stress can destroy cells, and on the other, ROS can also act as signals for the activation of stress responsive and defensive pathways. In this work, physiological and molecular analyses of Arabidopsis mutants and transgenic lines were applied to investigate the signalling network controlling biotic and abiotic stress responses. A key enzyme of the antioxidant network is encoded by ASCORBATE PEROXIDASE 2 (APX2). Wounded leaves showed low induction of APX2 expression and when exposed to excess light, APX2 expression was increased synergistically. Signalling pathways dependent upon jasmonic acid, chitosan and abscisic acid were not involved in the wound-induced expression of APX2, but PET was required, and APX2 induction was preceded by a depressed rate of CO2 fixation. Analysis of lsd1 (LESION SIMULATING DISEASE 1) strongly suggests that light acclimatory processes and pathogen defences are genetically and functionally linked. It is important to know that LSD1 type of mutants have mainly been studied with regard to pathogenesis. From this work, it reveals that association of LSD1 with hypersensitive response may only be supplementary. GLUTATHIONE PEROXIDASES (GPXs) are another major family of ROS scavenging enzymes. Analysis of the Arabidopsis genome database revealed a new open-reading frame, thus increasing the total number of AtGPX gene family to eight (AtGPX1-AtGPX8). Arabidopsis thaliana transgenic lines with reduced expression of both putative chloroplastic isoforms (AtGPX1 and AtGPX7) and AtGPX7 knock-out mutant (ko-GPX7) were more sensitive to photo-oxidative stress but had a reduced bacterial growth rate when inoculated with virulent strains Pseudomonas syringae pv. tomato DC3000 and P.s.t. maculicola strain ES4326, indicating increased resistance to pathogenesis. This, to our knowledge, is the first functional and genetic analysis of chloroplastic GPXs in plants, and confirms that light and chloroplastic ROS metabolism is important for basal resistance against virulent pathogens. The above results confirm that light sensing, light acclimatory processes and photo-produced ROS also govern pathogen defence pathways. This has a great ecological relevance for Darwinian fitness of plants growing in the natural environment, where simultaneous pathogen attack and fluctuations in light, temperature and other environmental factors make rapid acclimation a constant necessity. Molecular, biochemical and physiological analysis of pathogen responses in mutants impaired in light sensing, EEE-dissipatory mechanisms, and similar analysis of light acclimatory processes in mutants impaired in pathogen defences may prove to be seminal. reactive oxygen species Arabidopsis thaliana signalling work biotic stress abiotic stress Plant physiology Växtfysiologi
539	Meristem Maintenance in Arabidopsis thaliana Para, Alessia January 2004 (has links) The shoot apical meristem (SAM) is the structure that shapes the aerial architecture of the plant, by producing lateral organs throughout development. In the model plant Arabidopsis thaliana, the SAM is always identifiable as a characteristic dome, whether it is found in the centre of a rosette of leaves or at the tip of an inflorescence. When senescence occurs and organogenesis ceases, the now inactive SAM still retains its characteristic appearance and it is never consumed into a terminal structure, such as a flower. Mutant plants that undergo termination represent a valuable tool to understand how the SAM structure and function are maintained during plant life. The aim of this work was to investigate the dynamics of meristem development through morphological and genetic studies of three Arabidopsis mutants that exhibit distinct modes of SAM termination: distorted architecture 1 (dar1), adenosine kinase 1 (adk1) and terminal flower 2 (tfl2). The dar1 mutation is characterised by a severely distorted cellular architecture within the SAM. We propose that dar1 affects the pattern of cell differentiation and/or cell proliferation within the SAM apical dome, resulting in termination by meristem consumption. Instead, the adk1 mutation affects the organogenic potential of the SAM, without altering its structure. The adk1 mutant has increased levels of cytokinins and, as a consequence of this, cell division is enhanced and cell differentiation is prevented in the apex, causing termination by meristem arrest. Finally, tfl2 is mutated in the conserved chromatin remodelling factor HP1, a transcriptional repressor with multiple roles during plant development. The tfl2 SAM terminates by conversion into a floral structure, due to de-repression of floral identity genes. Interestingly, tfl2 mutants also show an altered response to light, an indication that TFL2 might act as a repressor also in the context of light signalling. Life sciences and physical sciences Arabidopsis thaliana development shoot apical meristem NATURVETENSKAP NATURAL SCIENCES NATURVETENSKAP
540	HDZip I Transcription Factors in Arabidopsis thaliana : Expression and Function in Relation to Environmental Stress Conditions Olsson, Anna S. B. January 2005 (has links) The homeodomain leucine zipper (HDZip) proteins constitute a plant-specific family of transcription factors, that based on sequence criteria have been grouped into four classes, HDZip I-IV. This thesis describes the phylogeny, function, expression patterns and regulation of the HDZip class I genes in the model species Arabidopsis thaliana. The phylogenetic analyses, traced duplication history and exon/intron organisation of the 17 class I genes in Arabidopsis show that the genes form six monophyletic groups, clades, with an origin in early plant evolution. All genes are expressed in broad tissue distribution patterns and the majority are responsive to water availability and/or light conditions. The expression of the genes show different patterns and dependence on environmental stress conditions, indicating evolutionary changes within and between clades. Ectopic expression of the genes suggest that they regulate genes in part by conserved mechanisms. Therefore, different functional roles seem to have evolved by a divergence mainly in the regulatory properties of the genes. Detailed expression analyses of the paralogous HDZip I genes ATHB7 and ATHB12 show that they have essentially overlapping patterns of activity in response to abscisic acid, ABA, or water deficit in leaves, stems and roots. The water deficit response of ATHB7 and -12 is mediated by ABA and depends on the protein phosphateses ABI1 and ABI2. Transgenic plants with ectopic expression of ATHB7 and/or -12, and athb7 and athb12 mutants, reveal that the genes in roots mediate the growth inhibitory effects of ABA. In this aspect of their function they do not overlap. In leaves and stems, the genes might act as growth regulators redundantly with other factors. Taken together these data suggest that ATHB7 and -12 regulate growth in response water deficit and that other HDZip I genes have related functions in response to environmental stress conditions. Biology homeodomain leucine zipper ABA transcription factor water deficit Arabidopsis thaliana Biologi Biology Biologi

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