@phdthesis{Welsch2022,
  author    = {Welsch, Maryna},
  title     = {Investigation of the stress tolerance regulatory network integration of the NAC transcription factor JUNGBRUNNEN1 (JUB1)},
  doi       = {10.25932/publishup-54731},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-547310},
  school      = {Universit{\"a}t Potsdam},
  pages     = {XIII, 116},
  year      = {2022},
  abstract  = {The NAC transcription factor (TF) JUNGBRUNNEN1 (JUB1) is an important negative regulator of plant senescence, as well as of gibberellic acid (GA) and brassinosteroid (BR) biosynthesis in Arabidopsis thaliana. Overexpression of JUB1 promotes longevity and enhances tolerance to drought and other abiotic stresses. A similar role of JUB1 has been observed in other plant species, including tomato and banana. Our data show that JUB1 overexpressors (JUB1-OXs) accumulate higher levels of proline than WT plants under control conditions, during the onset of drought stress, and thereafter. We identified that overexpression of JUB1 induces key proline biosynthesis and suppresses key proline degradation genes. Furthermore, bZIP63, the transcription factor involved in proline metabolism, was identified as a novel downstream target of JUB1 by Yeast One-Hybrid (Y1H) analysis and Chromatin immunoprecipitation (ChIP). However, based on Electrophoretic Mobility Shift Assay (EMSA), direct binding of JUB1 to bZIP63 could not be confirmed. Our data indicate that JUB1-OX plants exhibit reduced stomatal conductance under control conditions. However, selective overexpression of JUB1 in guard cells did not improve drought stress tolerance in Arabidopsis. Moreover, the drought-tolerant phenotype of JUB1 overexpressors does not solely depend on the transcriptional control of the DREB2A gene. Thus, our data suggest that JUB1 confers tolerance to drought stress by regulating multiple components. Until today, none of the previous studies on JUB1´s regulatory network focused on identifying protein-protein interactions. We, therefore, performed a yeast two-hybrid screen (Y2H) which identified several protein interactors of JUB1, two of which are the calcium-binding proteins CaM1 and CaM4. Both proteins interact with JUB1 in the nucleus of Arabidopsis protoplasts. Moreover, JUB1 is expressed with CaM1 and CaM4 under the same conditions. Since CaM1.1 and CaM4.1 encode proteins with identical amino acid sequences, all further experiments were performed with constructs involving the CaM4 coding sequence. Our data show that JUB1 harbors multiple CaM-binding sites, which are localized in both the N-terminal and C-terminal regions of the protein. One of the CaM-binding sites, localized in the DNA-binding domain of JUB1, was identified as a functional CaM-binding site since its mutation strongly reduced the binding of CaM4 to JUB1. Furthermore, JUB1 transactivates expression of the stress-related gene DREB2A in mesophyll cells; this effect is significantly reduced when the calcium-binding protein CaM4 is expressed as well. Overexpression of both genes in Arabidopsis results in early senescence observed through lower chlorophyll content and an enhanced expression of senescence-associated genes (SAGs) when compared with single JUB1 overexpressors. Our data also show that JUB1 and CaM4 proteins interact in senescent leaves, which have increased Ca2+ levels when compared to young leaves. Collectively, our data indicate that JUB1 activity towards its downstream targets is fine-tuned by calcium-binding proteins during leaf senescence.},
  language  = {en}
}
@phdthesis{MatallanaRamirez2012,
  author    = {Matallana-Ram{\´i}rez, Lilian Paola},
  title     = {Unraveling the ORE1 regulon in Arabidopsis thaliana : molecular and functional characterization of up- and down-stream components},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus-62646},
  school      = {Universit{\"a}t Potsdam},
  year      = {2012},
  abstract  = {Leaf senescence is an active process required for plant survival, and it is flexibly controlled, allowing plant adaptation to environmental conditions. Although senescence is largely an age-dependent process, it can be triggered by environmental signals and stresses. Leaf senescence coordinates the breakdown and turnover of many cellular components, allowing a massive remobilization and recycling of nutrients from senescing tissues to other organs (e.g., young leaves, roots, and seeds), thus enhancing the fitness of the plant. Such metabolic coordination requires a tight regulation of gene expression. One important mechanism for the regulation of gene expression is at the transcriptional level via transcription factors (TFs). The NAC TF family (NAM, ATAF, CUC) includes various members that show elevated expression during senescence, including ORE1 (ANAC092/AtNAC2) among others. ORE1 was first reported in a screen for mutants with delayed senescence (oresara1, 2, 3, and 11). It was named after the Korean word "oresara," meaning "long-living," and abbreviated to ORE1, 2, 3, and 11, respectively. Although the pivotal role of ORE1 in controlling leaf senescence has recently been demonstrated, the underlying molecular mechanisms and the pathways it regulates are still poorly understood. To unravel the signaling cascade through which ORE1 exerts its function, we analyzed particular features of regulatory pathways up-stream and down-stream of ORE1. We identified characteristic spatial and temporal expression patterns of ORE1 that are conserved in Arabidopsis thaliana and Nicotiana tabacum and that link ORE1 expression to senescence as well as to salt stress. We proved that ORE1 positively regulates natural and dark-induced senescence. Molecular characterization of the ORE1 promoter in silico and experimentally suggested a role of the 5'UTR in mediating ORE1 expression. ORE1 is a putative substrate of a calcium-dependent protein kinase named CKOR (unpublished data). Promising data revealed a positive regulation of putative ORE1 targets by CKOR, suggesting the phosphorylation of ORE1 as a requirement for its regulation. Additionally, as part of the ORE1 up-stream regulatory pathway, we identified the NAC TF ATAF1 which was able to transactivate the ORE1 promoter in vivo. Expression studies using chemically inducible ORE1 overexpression lines and transactivation assays employing leaf mesophyll cell protoplasts provided information on target genes whose expression was rapidly induced upon ORE1 induction. First, a set of target genes was established and referred to as early responding in the ORE1 regulatory network. The consensus binding site (BS) of ORE1 was characterized. Analysis of some putative targets revealed the presence of ORE1 BSs in their promoters and the in vitro and in vivo binding of ORE1 to their promoters. Among these putative target genes, BIFUNCTIONAL NUCLEASE I (BFN1) and VND-Interacting2 (VNI2) were further characterized. The expression of BFN1 was found to be dependent on the presence of ORE1. Our results provide convincing data which support a role for BFN1 as a direct target of ORE1. Characterization of VNI2 in age-dependent and stress-induced senescence revealed ORE1 as a key up-stream regulator since it can bind and activate VNI2 expression in vivo and in vitro. Furthermore, VNI2 was able to promote or delay senescence depending on the presence of an activation domain located in its C-terminal region. The plasticity of this gene might include alternative splicing (AS) to regulate its function in different organs and at different developmental stages, particularly during senescence. A model is proposed on the molecular mechanism governing the dual role of VNI2 during senescence.},
  language  = {en}
}
@phdthesis{Hochrein2017,
  author    = {Hochrein, Lena},
  title     = {Development of a new DNA-assembly method and its application for the establishment of a red light-sensing regulation system},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-404441},
  school      = {Universit{\"a}t Potsdam},
  pages     = {146},
  year      = {2017},
  abstract  = {In der hier vorgelegten Doktorarbeit wurde eine Strategie zur schnellen, einfachen und zuverl{\"a}ssigen Assemblierung von DNS-Fragmenten, genannt AssemblX, entwickelt. Diese kann genutzt werden, um komplexe DNS-Konstrukte, wie beispielsweise komplette Biosynthesewege, aufzubauen. Dies dient der Produktion von technisch oder medizinisch relevanten Produkten in biotechnologisch nutzbaren Organismen. Die Vorteile der Klonierungsstrategie liegen in der Schnelligkeit der Klonierung, der Flexibilit{\"a}t bez{\"u}glich des Wirtsorganismus, sowie der hohen Effektivit{\"a}t, die durch gezielte Optimierung erreicht wurde. Die entwickelte Technik erlaubt die nahtlose Assemblierung von Genfragmenten und bietet eine Komplettl{\"o}sung von der Software-gest{\"u}tzten Planung bis zur Fertigstellung von DNS-Konstrukten, welche die Gr{\"o}ße von Mini-Chromosomen erreichen k{\"o}nnen. Mit Hilfe der oben beschriebenen AssemblX Strategie wurde eine optogenetische Plattform f{\"u}r die B{\"a}ckerhefe Saccharomyces cerevisiae etabliert. Diese besteht aus einem Rotlicht-sensitiven Photorezeptor und seinem interagierenden Partner aus Arabidopsis thaliana, welche in lichtabh{\"a}ngiger Weise miteinander agieren. Diese Interaktion wurde genutzt, um zwei Rotlicht-aktivierbare Proteine zu erstellen: Einen Transkriptionsfaktor, der nach Applikation eines Lichtpulses die Produktion eines frei w{\"a}hlbaren Proteins stimuliert, sowie eine Cre Rekombinase, die ebenfalls nach Bestrahlung mit einer bestimmten Wellenl{\"a}nge die zufallsbasierte Reorganisation bestimmter DNS-Konstrukte erm{\"o}glicht. Zusammenfassend wurden damit drei Werkzeuge f{\"u}r die synthetische Biologie etabliert. Diese erm{\"o}glichen den Aufbau von komplexen Biosynthesewegen, deren Licht-abh{\"a}ngige Regulation, sowie die zufallsbasierte Rekombination zu Optimierungszwecken.},
  language  = {en}
}
@phdthesis{Czechowski2005,
  author    = {Czechowski, Tomasz},
  title     = {Nitrogen signalling in Arabidopsis thaliana},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus-5445},
  school      = {Universit{\"a}t Potsdam},
  year      = {2005},
  abstract  = {Nitrogen is an essential macronutrient for plants and nitrogen fertilizers are indispensable for modern agriculture. Unfortunately, we know too little about how plants regulate their use of soil nitrogen, to maximize fertilizers-N use by crops and pastures. This project took a dual approach, involving forward and reverse genetics, to identify N-regulators in plants, which may prove useful in the future to improve nitrogen-use efficiency in agriculture. To identify nitrogen-regulated transcription factor genes in Arabidopsis that may control N-use efficiency we developed a unique resource for qRT-PCR measurements on all Arabidpsis transcription factor genes. Using closely spaced, gene-specific primer pairs and SYBR® Green to monitor amplification of double-stranded DNA, transcript levels of 83\% of all target genes could be measured in roots or shoots of young Arabidopsis wild-type plants. Only 4\% of reactions produced non-specific PCR products, and 13\% of TF transcripts were undetectable in these organs. Measurements of transcript abundance were quantitative over six orders of magnitude, with a detection limit equivalent to one transcript molecule in 1000 cells. Transcript levels for different TF genes ranged between 0.001-100 copies per cell. Real-time RT-PCR revealed 26 root-specific and 39 shoot-specific TF genes, most of which have not been identified as organ-specific previously. An enlarged and improved version of the TF qRT-PCR platform contains now primer pairs for 2256 Arabidopsis TF genes, representing 53 gene families and sub-families arrayed on six 384-well plates. Set-up of real-time PCR reactions is now fully robotized. One researcher is able to measure expression of all 2256 TF genes in a single biological sample in a just one working day. The Arabidopsis qRT-PCT platform was successfully used to identify 37 TF genes which transcriptionaly responded at the transcriptional level to N-deprivation or to nitrate per se. Most of these genes have not been characterized previously. Further selection of TF genes based on the responses of selected candidates to other macronutrients and abiotic stresses allowed to distinguish between TFs regulated (i) specifically by nitrogen (29 genes) (ii) regulated by general macronutrient or by salt and osmotic stress (6 genes), and (iii) responding to all major macronutrients and to abiotic stresses. Most of the N-regulated TF genes were also regulated by carbon. Further characterization of sixteen selected TF genes, revealed: (i) lack of transcriptional response to organic nitrogen, (ii) two major types of kinetics of induction by nitrate, (iii) specific responses for the majority of the genes to nitrate but not downstream products of nitrate assimilation. All sixteen TF genes were cloned into binary vectors for constitutive and ethanol inducible over expression, and the first generation of transgenic plants were obtained for almost all of them. Some of the plants constitutively over expressing TF genes under control of the 35S promoter revealed visible phenotypes in T1 generation. Homozygous T-DNA knock out lines were also obtained for many of the candidate TF genes. So far, one knock out line revealed a visible phenotype: retardation of flowering time. A forward genetic approach using an Arabidopsis ATNRT2.1 promoter : Luciferase reporter line, resulted in identification of eleven EMS mutant reporter lines affected in induction of ATNRT2.1 expression by nitrate. These lines could by divided in the following classes according to expression of other genes involved in primary nitrogen and carbon metabolism: (i) lines affected exclusively in nitrate transport, (ii) those affected in nitrate transport, acquisition, but also in glycolysis and oxidative pentose pathway, (iii) mutants affected moderately in nitrate transport, oxidative pentose pathway and glycolysis but not in primary nitrate assimilation. Thus, several different N-regulatory genes may have been mutated in this set of mutants. Map-based cloning has begun to identify the genes affected in these mutants.},
  subject      = {Stickstoff},
  language  = {en}
}
@phdthesis{Banning2005,
  author    = {Banning, Antje},
  title     = {Selenabh{\"a}ngige Glutathionperoxidasen als Mediatoren und Ziele der intrazellul{\"a}ren Redoxregulation : Identifizierung der GI-GPx als Ziel f{\"u}r Nrf2 und der PHGPx ...},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus-5436},
  school      = {Universit{\"a}t Potsdam},
  year      = {2005},
  abstract  = {Das 1817 erstmals schriftlich erw{\"a}hnte Selen galt lange Zeit nur als toxisch und sogar als procancerogen, bis es 1957 von Schwarz und Foltz als essentielles Spurenelement erkannt wurde, dessen biologische Funktionen in S{\"a}ugern durch Selenoproteine vermittelt werden. Die Familie der Glutathionperoxidasen nimmt hierbei eine wichtige Stellung ein. F{\"u}r diese sind konkrete Funktionen und die dazugeh{\"o}rigen molekularen Mechanismen, welche {\"u}ber die von ihnen katalysierte Hydroperoxidreduktion und damit verbundene antioxidative Kapazit{\"a}t hinausgehen, bislang nur unzureichend beschrieben worden. Die Funktion der gastrointestinalen Glutathionperoxidase (GI-GPx) wird als Barriere gegen eine Hydroperoxidabsorption im Gastrointestinaltrakt definiert. Neuen Erkenntnissen zufolge wird die GI-GPx aber auch in verschiedenen Tumoren verst{\"a}rkt exprimiert, was weitere, bis dato unbekannte, Funktionen dieses Enzymes wahrscheinlich macht. Um m{\"o}gliche neue Funktionen der GI-GPx, vor allem w{\"a}hrend der Cancerogenese, abzuleiten, wurde hier die transkriptionale Regulation der GI-GPx detaillierter untersucht. Die Sequenzanalyse des humanen GI-GPx-Promotors ergab das Vorhandensein von zwei m{\"o}glichen "antioxidant response elements" (ARE), bei welchen es sich um Erkennungssequenzen des Transkriptionsfaktors Nrf2 handelt. Die meisten der bekannten Nrf2-Zielgene geh{\"o}ren in die Gruppe der Phase-II-Enzyme und verf{\"u}gen {\"u}ber antioxidative und/oder detoxifizierende Eigenschaften. Sowohl auf Promotorebene als auch auf mRNA- und Proteinebene konnte die Expression der GI-GPx durch typische, in der Nahrung enthaltene, Nrf2-Aktivatoren wie z.B. Sulforaphan oder Curcumin induziert werden. Eine direkte Beteiligung von Nrf2 wurde durch Cotransfektion von Nrf2 selbst bzw. von Keap1, das Nrf2 im Cytoplasma festh{\"a}lt, demonstriert. Somit konnte die GI-GPx eindeutig als Nrf2-Zielgen identifiziert werden. Ob sich die GI-GPx in die Gruppe der antiinflammatorischen und anticancerogenen Phase-II-Enzyme einordnen l{\"a}sst, bleibt noch zu untersuchen. Die Phospholipidhydroperoxid Glutathionperoxidase (PHGPx) nimmt aufgrund ihres breiten Substratspektrums, ihrer hohen Lipophilie und ihrer F{\"a}higkeit, Thiole zu modifizieren, eine Sonderstellung innerhalb der Familie der Glutathionperoxidasen ein. Mit Hilfe eines PHGPx-{\"u}berexprimierenden Zellmodells wurden deshalb Beeinflussungen des zellul{\"a}ren Redoxstatus und daraus resultierende Ver{\"a}nderungen in der Aktivit{\"a}t redoxsensitiver Transkriptionsfaktorsysteme und in der Expression atheroskleroserelevanter Adh{\"a}sionsmolek{\"u}le untersucht. Als Transkriptionsfaktoren wurden NF-kB und Nrf2 ausgew{\"a}hlt. Die Bindung von NF-kB an sein entsprechendes responsives Element in der DNA erfordert das Vorhandensein freier Thiole, wohingegen Nrf2 durch Thiolmodifikation von Keap1 freigesetzt wird und in den Kern transloziert. Eine erh{\"o}hte Aktivit{\"a}t der PHGPx resultierte in einer Erh{\"o}hung des Verh{\"a}ltnisses von GSH zu GSSG, andererseits aber in einer verminderten Markierbarkeit freier Proteinthiole. PHGPx-{\"U}berexpression reduzierte die IL-1-induzierte NF-kB-Aktivit{\"a}t, die sich in einer verminderten NF-kB-DNA-Bindef{\"a}higkeit und Transaktivierungsaktivit{\"a}t ausdr{\"u}ckte. Auch war die Proliferationsrate der Zellen vermindert. Die Expression des NF-kB-regulierten vaskul{\"a}ren Zelladh{\"a}sionsmolek{\"u}ls, VCAM-1, war ebenfalls deutlich verringert. Umgekehrt war in PHGPx-{\"u}berexprimierenden Zellen eine erh{\"o}hte Nrf2-Aktivit{\"a}t und Expression der Nrf2-abh{\"a}ngigen H{\"a}moxygenase-1 zu verzeichnen. Letzte kann f{\"u}r die meisten der beobachteten Effekte verantwortlich gemacht werden. Die hier dargestellten Ergebnisse verdeutlichen, dass eine Modifizierung von Proteinthiolen als wichtige Determinante f{\"u}r die Regulation der Expression und Funktion von Glutathionperoxidasen angesehen werden kann. Entgegen fr{\"u}heren Vermutungen, welche oxidative Vorg{\"a}nge generell mit pathologischen Ver{\"a}nderungen assoziierten, scheint ein moderater oxidativer Stress, bedingt durch eine transiente Thiolmodifikation, durchaus g{\"u}nstige Auswirkungen zu haben, da, wie hier dargelegt, verschiedene, miteinander interagierende, cytoprotektive Mechanismen ausgel{\"o}st werden. Hieran wird deutlich, dass sich "antioxidative Wirkung" oder "oxidativer Stress" keineswegs nur auf "gute" oder "schlechte" Vorg{\"a}nge beschr{\"a}nken lassen, sondern im Zusammenhang mit den beeinflussten (patho)physiologischen Prozessen und dem Ausmaß der "St{\"o}rung" des physiologischen Redoxgleichgewichtes betrachtet werden m{\"u}ssen.},
  subject      = {Selen},
  language  = {de}
}