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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Charakterisierung des physiologischen Einflusses der Phosphorylierung von GENOMES UNCOUPLED 4 (GUN4) auf die Tetrapyrrolbiosynthese und Untersuchung der retrograden Kommunikation zwischen Plastiden und Zellkern

Richter, Andreas Sven 03 April 2017 (has links)
Die Endprodukte der Tetrapyrrolbiosynthese sind essentiell für die Schwefel- und Stickstoffassimilation (Sirohäm), der von Photorezeptoren abhängigen Genexpression (Phytochromobilin), Elektronenübertragungsreaktionen (Häm) und der Photosynthese (Chlorophyll). Die Synthese von Chlorophyllen wird durch eine Mg-Chelatase (MgCh) eingeleitet, die durch das GENOMES UNCOUPLED 4 (GUN4) Protein stimuliert wird. GUN4 ist essentiell für die Aktivierung der MgCh und die Synthese von Chlorophyllen. Das GUN4 aus Arabidopsis thaliana wird ausschließlich an der vorletzten Aminosäure (S264) des C-Terminus phosphoryliert. Die in vitro und in vivo MgCh-Aktivität wird hingegen durch phosphoryliertes GUN4 nicht mehr stimuliert. De-phosphoryliertes GUN4 bewirkt die lichtabhängige Aktivierung der MgCh im Übergang von der Nacht zum Tag in Angiospermen. Im Laufe der Evolution photosynthetisch aktiver Organismen hat sich die in den Angiospermen hochkonservierte Phosphorylierungsstelle entwickelt. GUN4-Homologe aus Synechocystis oder Chlamydomonas werden nicht phosphoryliert. Im Rahmen der Suche nach der GUN4-spezifischen Proteinkinase wurden vier in den Plastiden lokalisierte PLASTID PROTEIN KINASE WITH UNKNOWN FUNCTION identifiziert. In dieser Arbeit wurden zusätzlich Experimente zum durch die GUN-Proteine vermittelten retrograden Signalweg durchgeführt. gun Mutanten sind durch eine defizitäre cytosolische Anthocyan-/Flavonoidbiosynthese charakterisiert. Auf der Suche nach Hinweisen für einen Zusammenhang zwischen Anthocyanen und der De-repression von PHOTOSYNTHESIS-ASSOCIATED NUCLEAR GENES wurde eine neue gun Mutante identifiziert. Der knockout der durch TRANSPARENT TESTA 4 (TT4) kodierten CHALCON SYNTHASE führte zu einer mit den gun Mutanten vergleichbaren De-repression der PHANGs nach Norflurazon-Behandlung. Pharmakologische Experimente belegen eine mögliche Funktion der Phenylpropanoidbiosynthese in der durch die GUN-Proteine vermittelten retrograden Kommunikation. / Endproducts of the tetrapyrrole biosynthesis pathway are essential for the assimilation of sulfur and nitrogen (siroheme), photoreceptor mediated control of nuclear gene expression (phytochromobilin), electron transfer reactions (heme) and photosynthesis (chlorophyll). The synthesis of chlorophyll is initiated by a Mg-chelatase (MgCh) which is stimulated by the GUN4 protein. GUN4 is essential for the activation of MgCh and synthesis of chlorophyll. GUN4 from Arabidopsis thaliana is exclusively phosphorylated at the next-to-last amino acid of the C-terminus (S264). The stimulatory impact towards MgCh is reduced upon GUN4 phosphorylation. De-phosphorylated GUN4 stimulates MgCh activity during the transition from night to daytime. The phosphorylation site of GUN4 has evolved in the clade of angiosperms. GUN4 homologs of Synechocystis or Chlamydomonas are not phosphorylated. In an attempt to isolate the GUN4-kinase four formerly unknown PLASTID PROTEIN KINASE WITH UNKNOWN FUNCTION were identified. In addition to the elucidation of the post-translational GUN4 modifications, experiments concerning the GUN-dependent retrograde signaling pathway were performed. Under conditions which lead to a block of chloroplast development the de-repression of PHOTOSYNTHESIS-ASSOCIATED NUCLEAR GENES is paralleled by a reduced accumulation of anthocyanins in the gun mutants. When searching for a correlation between anthocyanin biosynthesis and expression of PHANGs a new gun mutant was identified. The knockout of CHALCONE SYNTHASE encoded by TRANSPARENT TESTA 4 (TT4) leads to a comparable de-repression of PHANGs after norflurazon treatment as it was observed for the gun mutants. Pharmacological modification of phenylpropanoid biosynthesis revealed that an intermediate of the pathway is a component of chloroplast-to-nucleus communication. Hence, first evidences for a function of the phenylpropanoid biosynthesis pathway in mediating the GUN-dependent retrograde signal were obtained.
2

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

Atici, Elif 01 February 2012 (has links) (PDF)
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.

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