@phdthesis{Bemm2018,
  author    = {Bemm, Felix Mathias},
  title     = {Genetic foundation of unrivaled survival strategies - Of water bears and carnivorous plants -},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-157109},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2018},
  abstract  = {All living organisms leverage mechanisms and response systems to optimize reproduction, defense, survival, and competitiveness within their natural habitat. Evolutionary theories such as the universal adaptive strategy theory (UAST) developed by John Philip Grime (1979) attempt to describe how these systems are limited by the trade-off between growth, maintenance and regeneration; known as the universal three-way trade-off. Grime introduced three adaptive strategies that enable organisms to coop with either high or low intensities of stress (e.g., nutrient deficiency) and environmental disturbance (e.g., seasons). The competitor is able to outcompete other organisms by efficiently tapping available resources in environments of low intensity stress and disturbance (e.g., rapid growers). A ruderal specism is able to rapidly complete the life cycle especially during high intensity disturbance and low intensity stress (e.g., annual colonizers). The stress tolerator is able to respond to high intensity stress with physiological variability but is limited to low intensity disturbance environments. Carnivorous plants like D. muscipula and tardigrades like M. tardigradum are two extreme examples for such stress tolerators. D. muscipula traps insects in its native habitat (green swamps in North and South Carolina) with specialized leaves and thereby is able to tolerate nutrient deficient soils. M. tardigradum on the other side, is able to escape desiccation of its terrestrial habitat like mosses and lichens which are usually covered by a water film but regularly fall completely dry. The stress tolerance of the two species is the central study object of this thesis. In both cases, high througput sequencing data and methods were used to test for transcriptomic (D. muscipula) or genomic adaptations (M. tardigradum) which underly the stress tolerance. A new hardware resource including computing cluster and high availability storage system was implemented in the first months of the thesis work to effectively analyze the vast amounts of data generated for both projects. Side-by-side, the data management resource TBro [14] was established together with students to intuitively approach complex biological questions and enhance collaboration between researchers of several different disciplines. Thereafter, the unique trapping abilities of D. muscipula were studied using a whole transcriptome approach. Prey-dependent changes of the transcriptional landscape as well as individual tissue-specific aspects of the whole plant were studied. The analysis revealed that non-stimulated traps of D. muscipula exhibit the expected hallmarks of any typical leaf but operates evolutionary conserved stress-related pathways including defense-associated responses when digesting prey. An integrative approach, combining proteome and transcriptome data further enabled the detailed description of the digestive cocktail and the potential nutrient uptake machinery of the plant. The published work [25] as well as a accompanying video material (https://www.eurekalert.org/pub_releases/ 2016-05/cshl-fgr042816.php; Video credit: S{\"o}nke Scherzer) gained global press coverage and successfully underlined the advantages of D. muscipula as experimental system to understand the carnivorous syndrome. The analysis of the peculiar stress tolerance of M. tardigradum during cryptobiosis was carried out using a genomic approach. First, the genome size of M. tardigradum was estimated, the genome sequenced, assembled and annotated. The first draft of M. tardigradum and the workflow used to established its genome draft helped scrutinizing the first ever released tardigrade genome (Hypsibius dujardini) and demonstrated how (bacterial) contamination can influence whole genome analysis efforts [27]. Finally, the M. tardigradum genome was compared to two other tardigrades and all species present in the current release of the Ensembl Metazoa database. The analysis revealed that tardigrade genomes are not that different from those of other Ecdysozoa. The availability of the three genomes allowed the delineation of their phylogenetic position within the Ecdysozoa and placed them as sister taxa to the nematodes. Thereby, the comparative analysis helped to identify evolutionary trends within this metazoan lineage. Surprisingly, the analysis did not reveal general mechanisms (shared by all available tardigrade genomes) behind the arguably most peculiar feature of tardigrades; their enormous stress tolerance. The lack of molecular evidence for individual tardigrade species (e.g., gene expression data for M. tardigradum) and the non-existence of a universal experimental framework which enables hypothesis testing withing the whole phylum Tardigrada, made it nearly impossible to link footprints of genomic adaptations to the unusual physiological capabilities. Nevertheless, the (comparative) genomic framework established during this project will help to understand how evolution tinkered, rewired and modified existing molecular systems to shape the remarkable phenotypic features of tardigrades.},
  subject      = {B{\"a}rtierchen},
  language  = {en}
}
@phdthesis{Foerster2015,
  author    = {F{\"o}rster, Sabrina},
  title     = {Regulation des Kaliumausstroms im ABA- und Jasmonatvermittelten Stomaschluss},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-115455},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2015},
  abstract  = {Stomata sind mikroskopisch kleine Poren in der Blattoberfl{\"a}che der Landpflanzen, {\"u}ber die das Blattgewebe mit CO2 versorgt wird. Als Schutz vor Austrocknung oder einer Infektion durch Pathogene entwickelte sich ein Mechanismus, um die Porenweite durch Bewegung der sie umgebenden Schließzellen an die Bed{\"u}rfnisse der Pflanze anzupassen. Ein eng gekn{\"u}pftes Signalnetzwerk kontrolliert diese Bewegungen und ist in der Lage, externe wie interne Stimuli zu verarbeiten. Der Schließvorgang wird osmotisch durch den Turgorverlust in den Schließzellen angetrieben, der durch den Efflux von Ionen wie K+ ausgel{\"o}st wird. In dieser Arbeit wurde die Regulation durch Phosphorylierung des wichtigsten K+-Effluxkanals f{\"u}r den Stomaschluss, GORK, untersucht. Folgende Erkenntnisse wurden durch elektrophysiologische Untersuchungen mit der DEVC-Methode gewonnen: GORK wird durch OST1 auf Ca2+- unabh{\"a}ngige und durch CBL1/9-CIPK5 und CBL1-CIPK23 auf Ca2+-abh{\"a}ngige Weise phosphoryliert und damit aktiviert. CBL1 muss CIPK5 an der Plasmamembran verankern und Ca2+ binden. CIPK5 ben{\"o}tigt ATP und eine Konformations{\"a}nderung, um GORK zu phosphorylieren. Im Rahmen dieser Arbeit wurde auch zum ersten Mal gezeigt, dass die PP2CPhosphatase ABI2 direkt mit einem Kanal interagiert und dessen Aktivit{\"a}t hemmt. ABI2 interagiert auch mit den Kinasen OST1, CIPK5 und CIPK23, sodass die Kontrolle der Kanalaktivit{\"a}t auf multiple Weise stattfinden kann. OST1 und ABI2 verbinden die GORKRegulation mit dem ABA-Signalweg. Schließzellen von gork1-2, cbl1/cbl9 und cipk5-2 sind insensitiv auf MeJA, nicht aber auf ABA. Dies stellt eine direkte Verbindung zwischen dem Jasmonatsignalweg und der Ca2+-Signalgebung dar. Im Rahmen dieser Arbeit konnten weitere Hinweise f{\"u}r das komplexe Zusammenspiel der Phytohormone ABA, JA und des Pseudomonas- Effektors Coronatin gefunden werden. Hier konnte zum ersten Mal gezeigt werden, dass Schließzellen je nach Inkubationszeit unterschiedlich auf MeJA und das Phytotoxin Coronatin reagieren. ABA und Coronatin verhalten sich dabei antagonistisch zueinander, wobei der Effekt der Stimuli auf die Stomaweite von der zeitlichen Abfolge der Perzeption abh{\"a}ngt. Der Jasmonat-Signalweg in Schließzellen l{\"o}st eine geringe ABA-Synthese sowie den Proteinabbau durch das Ubiquitin/26S-Proteasom-System aus und ben{\"o}tigt ABA-Rezeptoren (PYR/PYLs), um einen Stomaschluss einzuleiten. Durch diese Arbeit konnte somit die JA-gesteuerte Regulation des Kaliumefflux-Kanals GORK entschl{\"u}sselt sowie einige Unterschiede zwischen den ABA, JA und Coronatin-vermittelten Schließzellbewegungen aufgedeckt werden.},
  subject      = {Ackerschmalwand},
  language  = {de}
}
@phdthesis{Glenz2019,
  author    = {Glenz, Ren{\´e}},
  title     = {Die Rolle von Sphingobasen in der pflanzlichen Zelltodreaktion},
  doi       = {10.25972/OPUS-18790},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-187903},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2019},
  abstract  = {Sphingobasen bilden das Grundger{\"u}st und die Ausgangsbausteine f{\"u}r die Biosynthese von Sphingolipiden. W{\"a}hrend komplexere Sphingolipide einen wichtigen Bestandteil von eukaryotischen Membranen bilden, sind Sphingobasen, die auch als long-chain bases (LCBs) bezeichnet werden, als Signalmolek{\"u}le bei zellul{\"a}ren Prozessen in Eukaryoten bekannt. Im tierischen System wurden antagonistische Effekte von nicht-phosphorylierten Sphingobasen (LCBs) und ihren phosphorylierten Gegenst{\"u}cken (LCB-Ps) bei vielen Zellfunktionen, insbesondere der Apoptose, nachgewiesen und die zugrundeliegenden Signalwege umfassend aufgekl{\"a}rt. Im Gegensatz dazu sind in Pflanzen weniger Belege f{\"u}r einen antagonistischen Effekt und m{\"o}gliche Signaltransduktionsmechanismen bekannt. F{\"u}r eine regulatorische Funktion von Sphingobasen beim programmierten Zelltod (PCD) in Pflanzen existieren mehrere Hinweise: (I) Mutationen in Genen, die den Sphingobasen-Metabolismus betreffen, f{\"u}hren zum Teil zu spontanem PCD und ver{\"a}nderten Zelltodreaktionen. (II) Die Gehalte von LCBs sind bei verschiedenen Zelltod-ausl{\"o}senden Bedingungen erh{\"o}ht. (III) Nekrotrophe Pathogene produzieren Toxine, wie Fumonisin B1 (FB1), die mit dem Sphingolipid-Metabolismus der Wirtspflanze interferieren, was wiederum die Ursache f{\"u}r den dadurch ausgel{\"o}sten PCD darstellt. (IV) Die Behandlung von Pflanzen mit LCBs, nicht aber mit LCB-Ps, f{\"u}hrt zu Zelltod. In dieser Arbeit wurde die Rolle von Sphingobasen in der pflanzlichen Zelltodreaktion untersucht, wobei der Fokus auf der {\"U}berpr{\"u}fung der Hypothese eines antagonistischen, Zelltod-hemmenden Effekts von LCB-Ps lag. Anhand von Leitf{\"a}higkeit-basierten Messungen bei Blattscheiben von Arabidopsis thaliana wurde der durch Behandlung mit LCBs und separater oder gleichzeitiger Zugabe von LCB-Ps auftretende Zelltod bestimmt. Mit dieser Art der Quantifizierung wurde der an anderer Stelle publizierte inhibierende Effekt von LCB-Ps auf den LCB-induzierten Zelltod nachgewiesen. Durch parallele Messung der Spiegel der applizierten Sphingobasen im Gewebe mittels HPLC-MS/MS konnte dieser Antagonismus allerdings auf eine reduzierte Aufnahme der LCB bei Anwesenheit der LCB-P zur{\"u}ckgef{\"u}hrt werden, was auch durch eine zeitlich getrennte Behandlung mit den Sphingobasen best{\"a}tigt wurde. Dar{\"u}ber hinaus wurde der Einfluss einer exogenen Zugabe von LCBs und LCB-Ps auf den durch Pseudomonas syringae induzierten Zelltod von A. thaliana untersucht. F{\"u}r LCB-Ps wurde dabei kein Zelltod-hemmender Effekt beobachtet, ebenso wenig wie ein Einfluss von LCB-Ps auf den PCD, der durch rekombinante Expression und Erkennung eines Avirulenzproteins in Arabidopsis ausgel{\"o}st wurde. F{\"u}r LCBs wurde dagegen eine direkte antibakterielle Wirkung im Zuge der Experimente mit P. syringae gezeigt, die den in einer anderen Publikation beschriebenen inhibierenden Effekt von LCBs auf den Pathogen-induzierten Zelltod in Pflanzen relativiert. In weiteren Ans{\"a}tzen wurden Arabidopsis-Mutanten von Enzymen des Sphingobasen-Metabolismus (LCB-Kinase, LCB-P-Phosphatase, LCB-P-Lyase) hinsichtlich ver{\"a}nderter in-situ-Spiegel von LCBs/LCB-Ps funktionell charakterisiert. Der Ph{\"a}notyp der Mutanten gegen{\"u}ber Fumonisin B1 wurde zum einen anhand eines Wachstumstests mit Keimlingen und zum anderen anhand des Zelltods von Blattscheiben bestimmt und die dabei akkumulierenden Sphingobasen quantifiziert. Die Sensitivit{\"a}t der verschiedenen Linien gegen{\"u}ber FB1 korrelierte eng mit den Spiegeln der LCBs, w{\"a}hrend hohe Gehalte von LCB-Ps alleine nicht in der Lage waren den Zelltod zu verringern. In einzelnen Mutanten konnte sogar eine Korrelation von stark erh{\"o}hten LCB-P-Spiegeln mit einer besonderen Sensitivit{\"a}t gegen{\"u}ber FB1 festgestellt werden. Die Ergebnisse der vorliegenden Arbeit stellen die Hypothese eines antagonistischen Effekts von phosphorylierten Sphingobasen beim pflanzlichen Zelltod in Frage. Stattdessen konnte in detaillierten Analysen der Sphingobasen-Spiegel die positive Korrelation der Gehalte von LCBs mit dem Zelltod gezeigt werden. Die hier durchgef{\"u}hrten Experimente liefern damit nicht nur weitere Belege f{\"u}r die Zelltod-f{\"o}rdernde Wirkung von nicht-phosphorylierten Sphingobasen, sondern tragen zum Verst{\"a}ndnis der Sphingobasen-Hom{\"o}ostase und des Sphingobasen-induzierten PCD in Pflanzen bei.},
  subject      = {Sphingolipide},
  language  = {de}
}
@phdthesis{Kopic2024,
  author    = {Kopic, Eva},
  title     = {On the physiological role of post-translational regulation of the \(Arabidopsis\) guard cell outward rectifying potassium channel GORK},
  doi       = {10.25972/OPUS-34880},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-348806},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {Das streng regulierte Gleichgewicht zwischen CO2-Aufnahme und Transpiration ist f{\"u}r Pflanzen essentiell und h{\"a}ngt von kontrollierten Turgor{\"a}nderungen ab, die durch die Aktivit{\"a}t verschiedener Anionen- und Kationenkan{\"a}le verursacht werden. Diese Kan{\"a}le sind Teil von Signalkaskaden, die z. B. durch Phytohormone wie ABA (Abscisins{\"a}ure) und JA (Jasmonat) ausgel{\"o}st werden, die beide bei Trockenstress in den Schließzellen wirken. Dar{\"u}ber hinaus ist bekannt, dass JA an der Reaktion der Pflanze auf Pathogenbefall oder Verwundung beteiligt ist. GORK (guard cell outward rectifying K+ channel) ist der einzige bekannte, ausw{\"a}rts gleichrichtende K+-Kanal in Schließzellen und somit f{\"u}r den K+-Efflux beim Schließen der Stomata verantwortlich. Im Rahmen dieser Arbeit konnte nachgewiesen werden, dass GORK ein wesentlicher Bestandteil des JA-induzierten Stomatschlusses ist. Dies gilt f{\"u}r beide Ausl{\"o}ser, sowohl die Blattverwundung als auch die direkte Anwendung von JA. Patch-Clamp-Experimente an Protoplasten von Schließzellen untermauerten dieses Ergebnis, indem sie GORK-K+-Ausw{\"a}rtsstr{\"o}me als direktes Ziel von JA-Signalen entlarvten. Da bekannt ist, dass zytosolische Ca2+-Signale sowohl bei ABA- als auch bei JA-Signalen eine Rolle spielen, wurde die Interaktion von GORK mit Ca2+-abh{\"a}ngigen Kinasen untersucht. Eine antagonistische Regulation von GORK durch CIPK5-CBL1/9-Komplexe und ABI2 konnte durch DEVC (double electrode voltage clamp) sowie Protein-Protein-Interaktions-Experimente identifiziert und durch in-vitro Kinase-Assays untermauert werden. Patch-Clamp-Aufzeichnungen an Protoplasten von Schließzellen der cipk5-2 Funktions-Verlust-Mutante zeigten die Bedeutung von CIPK5 f{\"u}r den JA-induzierten Stomaschluss via Aktivierung von GORK. Die Interaktion verschiedener CDPKs (Ca2+-abh{\"a}ngige Proteinkinasen) mit GORK wurde ebenfalls untersucht. Neben der Ca2+-Signal{\"u}bertragung ist auch die Produktion von ROS (reaktive Sauerstoffspezies) f{\"u}r die ABA- und MeJA-Signal{\"u}bertragung von Bedeutung. In DEVC-Experimenten konnte ein reversibler Effekt von ROS auf die GORK-Kanalaktivit{\"a}t nachgewiesen werden, was ein Teil der Erkl{\"a}rung f{\"u}r diese ROS-Effekte bei ABA- und MeJA-Signalen sein k{\"o}nnte.},
  subject      = {Spalt{\"o}ffnung},
  language  = {en}
}
@phdthesis{Kreisz2024,
  author    = {Kreisz, Philipp},
  title     = {Group S1 bZIP transcription factors regulate sink tissue development by controlling carbon and nitrogen resource allocation in \(Arabidopsis\) \(thaliana\)},
  doi       = {10.25972/OPUS-32192},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-321925},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {The evolutionary success of higher plants is largely attributed to their tremendous developmental plasticity, which allows them to cope with adverse conditions. However, because these adaptations require investments of resources, they must be tightly regulated to avoid unfavourable trade-offs. Most of the resources required are macronutrients based on carbon and nitrogen. Limitations in the availability of these nutrients have major effects on gene expression, metabolism, and overall plant morphology. These changes are largely mediated by the highly conserved master kinase SNF1-RELATED PROTEIN KINASE1 (SnRK1), which represses growth and induces catabolic processes. Downstream of SnRK1, a hub of heterodimerising group C and S1 BASIC LEUCINE ZIPPER (bZIP) transcription factors has been identified. These bZIPs act as regulators of nutrient homeostasis and are highly expressed in strong sink tissues, such as flowers or the meristems that initiate lateral growth of both shoots and roots. However, their potential involvement in controlling developmental responses through their impact on resource allocation and usage has been largely neglected so far. Therefore, the objective of this work was to elucidate the impact of particularly S1 bZIPs on gene expression, metabolism, and plant development. Due to the high homology and suspected partial redundancy of S1 bZIPs, higher order loss-of-function mutants were generated using CRISPR-Cas9. The triple mutant bzip2/11/44 showed a variety of robust morphological changes but maintained an overall growth comparable to wildtype plants. In detail however, seedlings exhibited a strong reduction in primary root length. In addition, floral transition was delayed, and siliques and seeds were smaller, indicating a reduced supply of resources to the shoot and root apices. However, lateral root density and axillary shoot branching were increased, suggesting an increased ratio of lateral to apical growth in the mutant. The full group S1 knockout bzip1/2/11/44/53 showed similar phenotypes, albeit far more pronounced and accompanied by growth retardation. Metabolomic approaches revealed that these architectural changes were accompanied by reduced sugar levels in distal sink tissues such as flowers and roots. Sugar levels were also diminished in leaf apoplasts, indicating that long distance transport of sugars by apoplastic phloem loading was impaired in the mutants. In contrast, an increased sugar supply to the proximal axillary buds and elevated starch levels in the leaves were measured. In addition, free amino acid levels were increased in bzip2/11/44 and bzip1/2/11/44/53, especially for the important transport forms asparagine and glutamine. The increased C and N availability in the proximal tissues could be the cause of the increased axillary branching in the mutants. To identify bZIP target genes that might cause the observed shifts in metabolic status, RNAseq experiments were performed. Strikingly, clade III SUGARS WILL EVENTUALLY BE EXPORTED (SWEET) 8 genes were abundant among the differentially expressed genes. As SWEETs are crucial for sugar export to the apoplast and long-distance transport through the phloem, their reduced expression is likely to be the cause of the observed changes in sugar allocation. Similarly, the reduced expression of GLUTAMINE AMIDOTRANSFERASE 1_2.1 (GAT1_2.1), which exhibits glutaminase activity, could be an explanation for the abundance of glutamine in the mutants. Additional experiments (ATAC-seq, DAP� seq, PTA, q-RT-PCR) supported the direct induction of SWEETs and GAT1_2.1 by S1 bZIPs. To confirm the involvement of these target genes in the observed S1 bZIP mutant phenotypes, loss-of-function mutants were obtained, which showed moderately increased axillary branching. At the same time, the induced overexpression of bZIP11 in axillary meristems had the opposite effect. Collectively, a model is proposed for the function of S1 bZIPs in regulating sink tissue development. For efficient long-distance sugar transport, bZIPs may be required to induce the expression of clade III SWEETs. Thus, reduced SWEET expression in the S1 bZIP mutants would lead to a decrease in apoplastic sugar loading and a reduced supply to distal sinks such as shoot or root apices. The reduction in long� distance transport could lead to sugar accumulation in the leaves, which would then increasingly be transported via symplastic routes towards proximal sinks such as axillary branches and lateral roots or sequestered as starch. The reduced GAT1_2.1 levels lead to an abundance of glutamine, a major nitrogen transport form. The combined effect on C and N allocation results in increased nutrient availability in proximal tissues, promoting the formation of lateral plant organs. Alongside emerging evidence highlighting the power of bZIPs to steer nutrient allocation in other species, a novel but evolutionary conserved role for S1 bZIPs as regulators of developmental plasticity is proposed, while the generation of valuable data sets and novel genetic resources will help to gain a deeper understanding of the molecular mechanisms involved},
  subject      = {Molekularbiologie},
  language  = {en}
}
@phdthesis{Kumari2021,
  author    = {Kumari, Khushbu},
  title     = {The role of lipid transfer proteins (LTPs) during the fertilization process in Arabidopsis thaliana},
  doi       = {10.25972/OPUS-19961},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-199613},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {Double fertilization is a defining characteristic of flowering plants (angiosperms). As the sperm cells of higher plants are non-motile, they need to be transported to the female gametophyte via the growing pollen tube. The pollen-tube journey through the female tissues represents a highly complex process. To provide for successful reproduction it demands intricate communication between the cells of the two haploid gametophytes - the polar growing pollen tube (carrying the two non-motile sperm cells) and the ovule (hosting the egg cell/synergid cells). The polar growth of the pollen tube towards the female gamete is guided by different signaling molecules, including sugars, amino acids and peptides. Some of these belong to the family of lipid transfer proteins (LTPs), which are secreted cysteine-rich peptides. Depending on the plant species several lines of evidence have also suggested potential roles for LTPs during pollen germination or pollen-tube guidance. Although Arabidopsis thaliana has 49 annotated genes for LTPs, several of which are involved in plant immunity and cell-to-cell communication, the role of most members of this family during fertilization is unknown. The aim of this project was therefore to systematically identify LTPs which play a role in the fertilization process in A. thaliana, particularly during pollen tube guidance. To identify candidate proteins, the expression profile of LTPs in reproductive tissue was investigated. This was accomplished by in-silico bioinformatic analysis using different expression databases. Following confirmion of these results by qRT-PCR analysis, seven Type-I nsLTPs (LTP1, LTP2, LTP3, LTP4, LTP5, LTP6 and LTP12) were found to be exclusively expressed in pistils. Except for LTP12, all other pistil expressed LTPs were transcriptionally induced upon pollination. Using reporter-based transcriptional and translational fusions the temporal and spatial expression patterns together with protein localizations for LTP2, 3, 4, 5, 6, and 12 were determined in planta. Stable transgenic plants carrying PromLTP::GUS constructs of the six different LTP candidates showed that most of LTPs were expressed in the stigma/stylar region and were induced upon pollination. With respect to protein localization on the cellular level, they split into two categories: LTP2, LTP5 and LTP6 were localized in the cell wall, while LTP3, LTP4 and LTP12 were specifically targeted to the plasma membrane. For the functional characterization of the candidate LTPs, several T-DNA insertion mutant plant lines were investigated for phenotypes affecting the fertilization process. Pollen development and quality as well as their in-vitro germination rate did not differ between the different single ltp mutant lines and wildtype plants. Moreover, in-vivo cross pollination experiments revealed that tube growth and fertilization rate of the mutant plants were similar to wildtype plants. Altogether, no discernible phenotype was evident in other floral and vegetative parts between different single ltp mutant lines and wildtype plants. As there was no distinguishable phenotype observed for single ltp-ko plants, double knock out plants of the two highly homologous genes LTP2 (expressed in the female stigma, style and transmitting tract) and LTP5 (expressed in the stigma, style, pollen pollen-tube and transmitting tract) were generated using the EPCCRISPR-Cas9 genome editing technique. Two ltp2ltp5 mutant transgenic-lines (\#P31-P2 and \#P31-P3) with frameshift mutations in both the genes could be established. Further experiments showed, that the CRISPR/Cas9-mediated knock-out of LTP2/LTP5 resulted in significantly reduced fertilization success. Cell biological analyses revealed that the ltp2ltp5 double mutant was impaired in pollen tube guidance towards the ovules and that this phenotype correlated with aberrant callose depositions in the micropylar region during ovule development. Detailed analysis of in-vivo pollen-tube growth and reciprocal cross pollination assay suggested that, the severely compromised fertility was not caused by any defect in development of the pollen grains, but was due to the abnormal callose deposition in the embryo sac primarily concentrated at the synergid cell near the micropylar end. Aberrant callose deposition in ltp2ltp5 ovules pose a complete blockage for the growing pollen tube to change its polarity to enter the funiculus indicating funicular and micropylar defects in pollen tube guidance causing fertilization failure. Our finding suggests that female gametophyte expressed LTP2 and LTP5 play a crucial role in mediating pollen tube guidance process and ultimately having an effect on the fertilization success. In line with the existence of a N-terminal signal peptide, secreted LTPs might represent a well-suited mobile signal carrier in the plant's extracellular matrix. Previous reports suggested that, LTPs could act as chemoattractant peptide, imparting competence to the growing pollen tube, but the molecular mechanism is still obscure. The results obtained in this thesis further provide strong evidence, that LTP2/5 together regulate callose homeostasis and testable models are discussed. Future work is now required to elucidate the detailed molecular link between these LTPs and their potential interacting partners or receptors expressed in pollen and synergid cells, which should provide deeper insight into their functional role as regulatory molecules in the pollen tube guidance mechanism.},
  subject      = {Fertilization in angiosperm},
  language  = {en}
}
@phdthesis{Lambour2023,
  author    = {Lambour, Benjamin},
  title     = {Regulation of sphingolipid long-chain bases during cell death reactions and abiotic stress in \(Arabidopsis\) \(thaliana\)},
  doi       = {10.25972/OPUS-32591},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-325916},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2023},
  abstract  = {Sphingobasen (LCBs) sind die Bausteine der Biosynthese von Sphingolipiden. Sie werden als Strukturelemente der pflanzlichen Zellmembran definiert und spielen eine wichtige Rolle f{\"u}r das Schicksal der Zellen. Komplexe Ceramide machen einen wesentlichen Teil der gesamten Sphingolipide aus, die einen großen Teil der eukaryotischen Membranen bilden. Gleichzeitig sind LCBs bekannte Signalmolek{\"u}le f{\"u}r zellul{\"a}re Prozesse in Eukaryonten und sind an Signal{\"u}bertragungswegen in Pflanzen beteiligt. Es hat sich gezeigt, dass hohe LCB-Konzentrationen mit der Induktion des programmierten Zelltods sowie mit dem durch Pathogene ausgel{\"o}sten Zelltod in Verbindung stehen. Mehrere Studien haben die regulierende Funktion der Sphingobasen beim programmierten Zelltod (PCD) in Pflanzen best{\"a}tigt: (i) Spontaner PCD und ver{\"a}nderte Zelltodreaktionen, die durch mutierte verwandte Gene des Sphingobasen-Stoffwechsels verursacht werden. (ii) Zelltodbedingungen erh{\"o}hen den Gehalt an LCBs. (iii) PCD aufgrund eines gest{\"o}rten Sphingolipid-Stoffwechsels, der durch von nekrotrophen Krankheitserregern produzierte Toxine wie Fumonisin B1 (FB1) hervorgerufen wird. Um den Zelltod zu verhindern und die Zelltodreaktion zu kontrollieren, kann daher die Regulierung des Gehalts an freien LCBs entscheidend sein. Die Ergebnisse der vorliegenden Studie stellten das Verst{\"a}ndnis der Sphingobasen und Sphingolipidspiegel w{\"a}hrend der PCD in Frage. Wir lieferten eine detaillierte Analyse der Sphingolipidspiegel, die Zusammenh{\"a}nge zwischen bestimmten Sphingolipidarten und dem Zelltod aufzeigte. Dar{\"u}ber hinaus erm{\"o}glichte uns die Untersuchung der Sphingolipid-Biosynthese ein Verst{\"a}ndnis des Fluxes nach Akkumulation hoher LCB-Konzentrationen. Weitere Analysen von Abbauprodukten oder Sphingolipid-Mutantenlinien w{\"a}ren jedoch erforderlich, um vollst{\"a}ndig zu verstehen, wie die Pflanze mit hohen Mengen an Sphingobasen umgeht.},
  subject      = {Ackerschmalwand},
  language  = {en}
}
@phdthesis{Lange2021,
  author    = {Lange, Manuel},
  title     = {Mutanten im RES-Oxylipin Signalweg von \(Arabidopsis\) \(thaliana\)},
  doi       = {10.25972/OPUS-16608},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-166085},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {Reaktive elektrophile Spezies-Oxylipine (RES-Oxylipine) finden sich in Pflanzen- und Tierzellen und zeichnen sich durch eine f{\"u}r sie typische Anordnung von Atomen aus: einer α,β unges{\"a}ttigten Carbonyl Gruppe. In Pflanzenzellen geh{\"o}ren unter anderem 2-(E)-Hexenal und die Vorstufe der Jasmons{\"a}ure 12-Oxophytodiens{\"a}ure (OPDA) zu den RES-Oxylipinen, in Tierzellen z.B. Prostaglandin A1 (PGA). RES-Oxylipine {\"u}ben Signalfunktionen aus, wie dies in Pflanzenzellen funktioniert ist jedoch noch nicht bekannt. Ziel dieser Arbeit ist dabei einen m{\"o}glichen RES-Oxylipin Signalweg aufzukl{\"a}ren und die beteiligten Gene zu identifizieren. Es konnte aber gezeigt werden, dass die Expressionsrate von bestimmten Genen wie z.B. GST6 durch RES-Oxylipine spezifisch induziert wird. Zur Untersuchung des RES-Oxylipin Signalweges wurde der GST6 Promotor vor das Luciferase-Gen fusioniert, um so ein RES-Oxylipin spezifisches Reportersystem zu erhalten. Die Ethylmethansulfonat mutagenisierten Linien wurden auf ge{\"a}nderte Luciferase-Aktivit{\"a}t hin untersucht. Dabei wurden drei Mutanten isoliert, die in dieser Arbeit n{\"a}her untersucht wurden. Eine zeigte basal erh{\"o}hte Luciferase-Aktivit{\"a}t (constitutive overexpresser 3 = coe3) und die anderen beiden erniedrigte Luciferase-Aktivit{\"a}t nach PGA Gabe (non responsive 1 und 2 = nr1 und nr2). In dieser Arbeit konnte gezeigt werden, dass die Ph{\"a}notypen in allen 3 Mutanten rezessiv vererbt werden und die Mutanten nicht zueinander allel sind. Zudem war die ver{\"a}nderte Luciferase-Aktivit{\"a}t nicht durch ge{\"a}nderte Phytohormonspiegel oder durch Mutationen im GST6 Promotor erkl{\"a}rbar. Auf die Gabe von RES, wie Benzylisothiocyanat oder Sulforaphan, sowie auf endogene RES-Oxylipine, wie OPDA und Hexenal, reagierten die Mutanten auf {\"a}hnliche Weise, wie nach PGA Gabe. Weiterf{\"u}hrende Untersuchungen zeigten, dass sich die drei Mutanten stark voneinander unterschieden. Das Transkriptom kontrollbehandelter coe3 Pflanzen unterschied sich stark von dem der GST6::LUC Pflanzen. Die Mutante war trockenstressresistenter zudem war sie sensibler gegen{\"u}ber NaCl, was jedoch nicht von einer ver{\"a}nderten Reaktion auf Abscisins{\"a}ure herr{\"u}hrte. Des Weiteren war der Chlorophyllabbau bei dunkel inkubierten Bl{\"a}ttern geringer. Bei der Lokalisierung der Mutation, die noch nicht abgeschlossen ist, konnten Chromosom 2 und 5 als die wahrscheinlichsten Kandidaten ermittelt werden. Weitere Analysen sind n{\"o}tig um den Bereich weiter eingrenzen zu k{\"o}nnen. Die Mutante nr1, die sich durch verminderte Reaktion auf RES-Oxylipine auszeichnete, zeigte einen kleineren Wuchs und ein deutlich verz{\"o}gertes Bl{\"u}hen. Außerdem wies die Mutante erh{\"o}hte Argininspiegel in ihren Bl{\"a}ttern auf. Das Transkriptom unterschied sich sowohl bei kontrollbehandelten, als auch bei PGA behandelten nr1 Pflanzen massiv von denen der gleichbehandelten Kontrollen. Auch die nr1 schien trockenstressresistenter zu sein, sie war im Gegensatz zur coe3 aber robuster gegen{\"u}ber h{\"o}heren Konzentrationen an NaCl. Mit Hilfe eines „Next Generation Genome-Mappings" war es m{\"o}glich die Mutation am Ende von Chromosom 3 zu lokalisieren und auf f{\"u}nf m{\"o}gliche Gene einzugrenzen. Weitere Untersuchungen m{\"u}ssen nun kl{\"a}ren, welches dieser Gene urs{\"a}chlich f{\"u}r den Ph{\"a}notyp der ge{\"a}nderten Luciferase-Aktivit{\"a}t ist. Die zweite Mutante mit einer reduzierten Reaktion auf RES-Oxylipine war die nr2. {\"U}berraschender Weise unterschied sich das Transkriptom kontrollbehandelter nr2 Pflanzen deutlich st{\"a}rker von dem der gleichbehandelten GST6::LUC Pflanzen, als das nach PGA Gabe der Fall war. Sie reagierte nur mit sehr schwacher Luciferase-Aktivit{\"a}t auf Verwundung und war zudem deutlich sensibler gegen{\"u}ber Trockenheit. F{\"u}r eine zuk{\"u}nftige Lokalisation der urs{\"a}chlichen Mutation wurden entsprechende Kreuzungen durchgef{\"u}hrt aus deren Samen jederzeit mit einer Selektionierung begonnen werden kann. Mit dieser Arbeit konnte ein erster großer Schritt in Richtung Identifikation der, f{\"u}r die ge{\"a}nderte Luciferase-Aktivit{\"a}t, verantwortlichen Mutation gemacht werden, sowie erste Reaktionen der Mutanten auf abiotische Stressfaktoren untersucht werden. Somit ist man der Entdeckung von Signaltransduktionsfaktoren, die RES-Oxylipinabh{\"a}ngig reguliert werden, einen wichtigen Schritt n{\"a}her gekommen.},
  subject      = {Arabidopsis thaliana},
  language  = {de}
}
@phdthesis{Li2023,
  author    = {Li, Kunkun},
  title     = {Dissecting the interconnection of Ca\(^{2+}\) and pH signaling in plants with a novel biosensor for dual imaging},
  doi       = {10.25972/OPUS-24973},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-249736},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2023},
  abstract  = {Calcium ion (Ca2+) and protons (H+) are both regarded as second messengers, participating in plant growth and stress mechanisms. However, H+ signals in plant physiology are less well investigated compared to Ca2+ signals. If interconnections between these two second messengers exist remains to be uncovered because appropriate imaging tools to monitor Ca2+ and H+ simultaneously in the same cell as well as accurate bioinformatics analysis remain to be developed. To overcome this problem and unravel the role and possible interconnection of Ca2+ and H+ in plants, a new biosensor named CapHensor was developed and optimized to visualize intracellular Ca2+ and H+ changes simultaneously and ratiometrically in the same cell. The CapHensor consisted of an optimized green fluorescent pH sensor (PRpHluorin) and an established red fluorescent Ca2+ sensor (R-GECO1) that were combined in one construct via a P2A sequence. A P2A self-cleavage site between the two sensors allowed to express equal amounts but spatially separated sensors, which enabled artifact-free and ratiometric imaging of cellular Ca2+ and pH side-by-side. The function of the CapHensor was verified in pollen tubes, since they possess standing Ca2+ and pH gradients. We found better imaging quality and the signal-to-noise ratio to be enhanced in live-cell imaging when two R-GECO1 proteins were fused in tandem within the CapHensor construct. To guarantee exclusive subcellular localization and avoid mixed signals from different compartments, Nuclear Export Sequence (NES) and Nuclear Localization Sequence (NLS) were used to target PRpHluorin and R-GECO1 to distinct compartments. After optimization and verification its function, CapHensor was successfully expressed in different cell types to investigate the role of Ca2+ and H+ signals to control polar growth of pollen tube, stomatal movement or leaf defense signaling. Results obtained in the past indicated both Ca2+ gradients and pH gradients in pollen tubes play roles in polar growth. However, the role and temporal relationship between the growth process and changes in Ca2+ and pH have not been conclusively resolved. Using CapHensor, I found cytosolic acidification at the tip could promote and alkalization to suppress growth velocity in N. tabacum pollen tubes, indicating that cytosolic H+ concentrations ([H+]cyt) play an important role in regulation pollen tubes growth despite the accompanied changes in cytosolic Ca2+ concentrations ([Ca2+]cyt). Moreover, growth correlated much better with the tip [H+]cyt regime than with the course of the tip [Ca2+]cyt regime. However, surprisingly, tip-focused [Ca2+]cyt andII [H+]cyt oscillations both lagged behind growth oscillations approximately 33 s and 18 s, respectively, asking for a re-evaluation of the role that tip [Ca2+]cyt may play in pollen tube growth. Live-cell CapHensor imaging combined with electrophysiology uncovered that oscillatory membrane depolarization correlated better with tip [H+]cyt oscillations than with tip [Ca2+]cyt oscillations, indicative for a prominent role of [H+]cyt to also control electrogenic membrane transport. Using CapHensor, reading out cellular movement at the same time enabled to provide a precise temporal and spatial resolution of ion signaling events, pointing out a prominent role of [H+]cyt in pollen tube tip growth. For leaf cells, a special CapHensor construct design had to be developed, containing additional NES localization sequences to avoid overlapping of fluorescense signals from the nucleus and the cytosol. Once this was achieved, the role of Ca2+ and pH changes in guard cells, another typical single-cell system was investigated. Cytosolic pH changes have been described in stomatal movement, but the physiological role of pH and the interaction with changing Ca2+ signals were still unexplored. Combining CapHensor with the here developed technique to monitor stomatal movement in parallel, the role of Ca2+ and H+ in stomatal movement was studied in detail and novel aspects were identified. The phytohormone ABA and the bacterial elicitor flagellin (flg22) are typical abiotic and biotic stresses, respectively, to trigger stomatal closure. What kind of Ca2+ and H+ signals by ABA and flg22 are set-off in guard cells and what their temporal relationship and role for stomatal movement is were unknown. Similar [Ca2+]cyt increases were observed upon ABA and flg22 triggered stomatal closure, but [H+]cyt dynamics differed fundamentally. ABA triggered pronounced cytosolic alkalization preceded the [Ca2+]cyt responses significantly by 57 s while stomata started to close ca. 205 s after phytohormone application. With flg22, stomatal closure was accompanied only with a mild cytosolic alkalization but the [Ca2+]cyt response was much more pronounced compared to the ABA effects. Where the cytosolic alkalization originates from was unclear but the vacuole was speculated to contribute in the past. In this thesis, vacuolar pH changes were visualized by the dye BCECF over time, basically displaying exactly the opposite course of the concentration shift in the vacuole than observed in the cytosol. This is indicative for the vacuolar pH dynamics to be coupled strongly to the cytosolic pH changes. In stomatal closure signalling, reactive oxygen species (ROS) were proposed to play a major role, however, only very high concentration of H2O2 (> 200 µM), which resulted in the loss of membrane integrity, induced stomatal closure. Unexpectedly, physiological concentrations of ROS led to cytosolic acidificationIII which was associated with stomatal opening, but not stomatal closure. To study the role of [H+]cyt to steer stomatal movement in detail, extracellular and intracellular pH variations were evoked in N. tabacum guard cells and their behaviour was followed. The results demonstrated cytosolic acidification stimulated stomatal opening while cytosolic alkalization triggered stomatal closure accompanied by [Ca2+]cyt elevations. This demonstrated pH regulation to be an important aspect in stomatal movement and to feed-back on the Ca2+-dynamics. It was remarkable that cytosolic alkalization but not [Ca2+]cyt increase seemed to play a crucial role in stomatal closure, because more pronounced cytosolic alkalization, evoked stronger stomatal closure despite similar [Ca2+]cyt increases. Increases in [Ca2+]cyt, which are discussed as an early stomatal closure signal in the past, could not trigger stomatal closure alone in my experiments, even when extremely strong [Ca2+]cyt signals were triggered. Regarding the interaction between the two second messengers, [Ca2+]cyt and [H+]cyt were negatively correlated most of the times, which was different from pollen tubes showing positive correlation of [Ca2+]cyt and [H+]cyt regimes. [Ca2+]cyt elevations were always associated with a cytosolic alkalization and this relationship could be blocked by the presence of vanadate, a plasma membrane H+-pump blocker, indicating plasma membrane H+-ATPases to contribute to the negative correlation of [Ca2+]cyt and [H+]cyt. To compare with guard cells, cytosolic and nuclear versions of CapHensor were expressed in N. benthamiana mesophyll cells, a multicellular system I investigated. Mesophyll cell responses to the same stimuli as tested in guard cells demonstrated that ABA and H2O2 did not induce any [Ca2+]cyt and [H+]cyt changes while flg22 induced an increase in [Ca2+]cyt and [H+]cyt, which is different from the response in guard cells. I could thus unequivocally demonstrate that guard cells and mesophyll cells do respond differently with [Ca2+]cyt and [H+]cyt changes to the same stimuli, a concept that has been proposed before, but never demonstrated in such detail for plants. Spontaneous Ca2+ oscillations have been observed for a long time in guard cells, but the function or cause is still poorly understood. Two populations of oscillatory guard cells were identified according to their [Ca2+]cyt and [H+]cyt phase relationship in my study. In approximately half of the oscillatory cells, [H+]cyt oscillations preceded [Ca2+]cyt oscillations whereas [Ca2+]cyt was the leading signal in the other half of the guard cells population. Strikingly, natural [H+]cyt oscillations were dampened by ABA but not by flg22. This effect could be well explained by dampening of vacuolar H+ oscillations in the presence of ABA, but not through flg22. Vacuolar pH contributes to spontaneous [H+]cyt oscillations and ABA but not flg22 can block the interdependence of naturalIV [Ca2+]cyt and [H+]cyt signals. To study the role of [Ca2+]cyt oscillations in stomatal movement, solutions containing high and low KCl concentrations were applied aiming to trigger [Ca2+]cyt oscillations. The triggering of [Ca2+]cyt oscillations by this method was established two decades ago leading to the dogma that [Ca2+]cyt increases are the crucial signal for stomatal closure. However, I found stomatal movement by this method was mainly due to osmotic effects rather than [Ca2+]cyt increases. Fortunately, through this methodology, I found a strong correlation between cytosolic pH and the transport of potassium across the plasma membrane and vacuole existed. The plasma membrane H+-ATPases and H+-coupled K+ transporters were identified as the cause of [H+]cyt changes, both very important aspects in stomata physiology that were not visualized experimentally before. Na+ transport is also important for stomatal regulation and leaves generally since salt can be transported from the root to the shoot. Unlike well-described Ca2+- dependent mechanisms in roots, how leaves process salt stress is not at all understood. I applied salt on protoplasts from leaves, mesophyll cells and guard cells and combined live-cell imaging with Vm recordings to understand the transport and signaling for leaf cells to cope with salt stress. In both, mesophyll and guard cells, NaCl did not trigger Ca2+-signals as described for roots but rather triggered Ca2+ peaks when washing salt out. However, membrane depolarization and pronounced alkalinization were very reliably triggered by NaCl, which could presumably act as a signal for detoxification of high salt concentrations. In line with this, I found the vacuolar cation/H+ antiporter NHX1 to play a role in sodium transport, [H+]cyt homeostasis and the control of membrane potential. Overexpression of AtNHX1 enabled to diminish [H+]cyt changes and resulted in a smaller depolarization responses druing NaCl stress. My results thus demonstrated in contrast to roots, leaf cells do not use Ca2+-dependent signalling cascades to deal with salt stress. I could show Na+ and K+ induced [H+]cyt and Vm responses and Cl- transport to only have a minor impact. Summing all my results up briefly, I uncovered pH signals to play important roles to control pollen tube growth, stomatal movement and leaf detoxification upon salt. My results strongly suggested pH changes might be a more important signal than previously thought to steer diverse processes in plants. Using CapHensor in combination with electrophysiology and bioinformatics tools, I discovered distinct interconnections between [Ca2+]cyt and [H+]cyt in different cell types and distinct [Ca2+]cyt and [H+]cyt signals are initiated through diverse stimuli and environmental cues. The CapHensor will be very useful in the future to further investigate the coordinated role of Ca2+ and pH changes in controlling plant physiology.},
  subject      = {Pflanzen},
  language  = {en}
}
@phdthesis{Reichelt2024,
  author    = {Reichelt, Niklas},
  title     = {Exploring the natural variation of heat-dependent metabolic rearrangements in \(Arabidopsis\) \(thaliana\) to identify genes involved in thermotolerance},
  doi       = {10.25972/OPUS-37132},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-371324},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {Climate change and associated extreme weather events are a threat not only for agricultural yields but the plant kingdom in general. Therefore, there is a great necessity to better understand the plants' intrinsic mechanisms to combat heat stress. The plant heat stress response already has been investigated in many studies, including the role of HSFA1 transcription factors as the central regulators. Other aspects such as the initial perception of heat and the role of heat-induced changes in plant metabolism are rather unknown. In this thesis, the natural variation of 250 different accessions of Arabidopsis thaliana was investigated regarding the temperature-dependent accumulation of raffinose and triacylglycerols. A connection between these phenotypes and respective genotypes was established using genome-wide association studies. As a result, the candidate gene TREHALOSE-6-PHOSPHATE SYNTHASE 1 (TPS1), was identified. Enzymatic TPS1 is responsible for the synthesis of trehalose 6-phosphate (T6P), which serves as an indicator and regulator of sucrose homeostasis. Subsequent analyses using tps1 tilling mutants demonstrated a link between T6P metabolism and an increased accumulation of various soluble carbohydrates and starch, including raffinose both under control conditions and during heat exposure. Furthermore, the mutant lines displayed enhanced thermotolerance and survival rates following long-term heat stress. Transcriptome analyses, however, did not show any difference in the regulation of canonical heat stress-associated genes. Instead, genes related to photosynthesis were overrepresented among the differentially upregulated genes in tps1 tilling lines during heat exposure. In this work, a direct connection of T6P signaling, sucrose homeostasis, and thermotolerance is shown for the first time. In a second project, two Arabidopsis thaliana accessions (Oberursel-0, accession ID: 7276; Nieps-0, accession ID: 7268) showing distinct capacities to acquire short-term thermotolerance were compared to identify the putative causative regulators or mechanisms that lead to the different levels of thermotolerance. An examination of the transcriptomes of 7268 and 7276 showed that several hundreds of genes were already differentially regulated within 10 minutes of exposure to 32 °C or 34 °C. Among these, several genes associated with sulfur metabolism were more highly induced in the more thermotolerant accession 7268. However, experimental as well as genetic manipulation of sulfur availability and metabolism did not result in altered thermotolerance. In addition to sulfur-related genes, most of the canonical heat stress-associated genes were more highly expressed in 7268 than in 7276. While we could not identify a causative regulator or mechanism of differential thermotolerances, the data strongly suggests that 7268 either has a higher overall sensitivity, i.e., the heat stress response is initiated at lower temperatures, or stronger overall heat stress response when exposed to a certain elevated temperature.},
  subject      = {Schmalwand <Arabidopsis>},
  language  = {en}
}