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Throughout their lifetime plants need to adapt to temperature changes. Plants adapt to nonfreezing cold temperatures in a process called cold priming (cold acclimation) and lose the acquired freezing tolerance during warmer temperatures through deacclimation. The alternation of both processes is essential for plants to achieve optimal fitness in response to different temperature conditions. Cold acclimation has been extensively studied, however, little is known about the regulation of deacclimation. This thesis elucidates the process of deacclimation on a physiological and molecular level in Arabidopsis thaliana. Electrolyte leakage measurements during cold acclimation and up to four days of deacclimation enabled the identification of four knockout mutants (hra1, lbd41, mbf1c and jub1) with a slower rate of deacclimation compared to the wild type. A transcriptomic study using RNA-Sequencing in A. thaliana Col-0, jub1 and mbf1c identified the importance of the inhibition of stress responsive and Jasmonate-ZIM-domain genes as well as the regulation of cell wall modifications during deacclimation. Moreover, measurements of alcohol dehydrogenase activity and gene expression changes of hypoxia markers during the first four days of deacclimation evidently showed that a hypoxia response is activated during deacclimation. Epigenetic regulation was observed to be extensively involved during cold acclimation and 24 h of deacclimation in A. thaliana. Further, both deacclimation studies showed that the previous hypothesis that heat stress might play a role in early deacclimation, is not likely. A number of DNA- and histone demethylases as well as histone variants were upregulated during deacclimation suggesting a role in plant memory. Recently, multiple studies have shown that plants are able to retain memory of a previous cold stress even after a week of deacclimation. In this work, transcriptomic and metabolomic analyses of Arabidopsis during 24 h of priming (cold acclimation) and triggering (recurring cold stress after deacclimation) revealed a uniquely significant and transient induction of DREB1D, DREB1E and DREB1F transcription factors during triggering contributing to fine-tuning of the second cold stress response. Furthermore, genes encoding Late Embryogenesis Abundant (LEA) and antifreeze proteins and proteins detoxifying reactive oxygen species were higher induced during late triggering (24 h) compared to primed samples, while cell wall remodelers of the class xyloglucan endotransglucosylase/hydrolase were early responders of triggering. The high induction of cell wall remodelers during deacclimation as well as triggering proposes that these proteins play an essential role in the stabilization of the cells during growth as well as the response to recurring stresses. Collectively this work gives new insights on the regulation of deacclimation and cold stress memory in A. thaliana and opens the door to future targeted studies of essential genes in this process.
Synthetische Transkriptionsfaktoren bestehen wie natürliche Transkriptionsfaktoren aus einer DNA-Bindedomäne, die sich spezifisch an die Bindestellensequenz vor dem Ziel-Gen anlagert, und einer Aktivierungsdomäne, die die Transkriptionsmaschinerie rekrutiert, sodass das Zielgen exprimiert wird. Der Unterschied zu den natürlichen Transkriptionsfaktoren ist, sowohl dass die DNA-Bindedomäne als auch die Aktivierungsdomäne wirtsfremd sein können und dadurch künstliche Stoffwechselwege im Wirt, größtenteils chemisch, induziert werden können. Optogenetische synthetische Transkriptionsfaktoren, die hier entwickelt wurden, gehen einen Schritt weiter. Dabei ist die DNA-Bindedomäne nicht mehr an die Aktivierungsdomäne, sondern mit dem Blaulicht-Photorezeptor CRY2 gekoppelt. Die Aktivierungsdomäne wurde mit dem Interaktionspartner CIB1 fusioniert. Unter Blaulichtbestrahlung dimerisieren CRY2 und CIB1 und damit einhergehend die beiden Domänen, sodass ein funktionsfähiger Transkriptionsfaktor entsteht. Dieses System wurde in die Saccharomyces cerevisiae genomisch integriert. Verifiziert wurde das konstruierte System mit Hilfe des Reporters yEGFP, welcher durchflusszytometrisch detektiert werden konnte. Es konnte gezeigt werden, dass die yEGFP Expression variabel gestaltet werden kann, indem unterschiedlich lange Blaulichtimpulse ausgesendet wurden, die DNA-Bindedomäne, die Aktivierungsdomäne oder die Anzahl der Bindestellen, an dem sich die DNA-Bindedomäne anlagert, verändert wurden. Um das System für industrielle Anwendungen attraktiv zu gestalten, wurde das System vom Deepwell-Maßstab auf Photobioreaktor-Maßstab hochskaliert. Außerdem erwies sich das Blaulichtsystem sowohl im Laborstamm YPH500 als auch im industriell oft verwendeten Hefestamm CEN.PK als funktional. Des Weiteren konnte ein industrierelevante Protein ebenso mit Hilfe des verifizierten Systems exprimiert werden. Schlussendlich konnte in dieser Arbeit das etablierte Blaulicht-System erfolgreich mit einem Rotlichtsystem kombiniert werden, was zuvor noch nicht beschrieben wurde.
Plants can be primed to survive the exposure to a severe heat stress (HS) by prior exposure to a mild HS. The information about the priming stimulus is maintained by the plant for several days. This maintenance of acquired thermotolerance, or HS memory, is genetically separable from the acquisition of thermotolerance itself and several specific regulatory factors have been identified in recent years.
On the molecular level, HS memory correlates with two types of transcriptional memory, type I and type II, that characterize a partially overlapping subset of HS-inducible genes. Type I transcriptional memory or sustained induction refers to the sustained transcriptional induction above non-stressed expression levels of a gene for a prolonged time period after the end of the stress exposure. Type II transcriptional memory refers to an altered transcriptional response of a gene after repeated exposure to a stress of similar duration and intensity. In particular, enhanced re-induction refers to a transcriptional pattern in which a gene is induced to a significantly higher degree after the second stress exposure than after the first.
This thesis describes the functional characterization of a novel positive transcriptional regulator of type I transcriptional memory, the heat shock transcription factor HSFA3, and compares it to HSFA2, a known positive regulator of type I and type II transcriptional memory. It investigates type I transcriptional memory and its dependence on HSFA2 and HSFA3 for the first time on a genome-wide level, and gives insight on the formation of heteromeric HSF complexes in response to HS. This thesis confirms the tight correlation between transcriptional memory and H3K4 hyper-methylation, reported here in a case study that aimed to reduce H3K4 hyper-methylation of the type II transcriptional memory gene APX2 by CRISPR/dCas9-mediated epigenome editing. Finally, this thesis gives insight into the requirements for a heat shock transcription factor to function as a positive regulator of transcriptional memory, both in terms of its expression profile and protein abundance after HS and the contribution of individual functional domains.
In summary, this thesis contributes to a more detailed understanding of the molecular processes underlying transcriptional memory and therefore HS memory, in Arabidopsis thaliana.