@phdthesis{Isasa2024, author = {Isasa, Emilie}, title = {Relationship between wood properties, drought-induced embolism and environmental preferences across temperate diffuse-porous broadleaved trees}, doi = {10.25972/OPUS-30356}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-303562}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2024}, abstract = {In the scope of climate warming and the increase in frequency and intensity of severe heat waves in Central Europe, identification of temperate tree species that are suited to cope with these environmental changes is gaining increasing importance. A number of tree physiological characteristics are associated with drought-stress resistance and survival following severe heat, but recent studies have shown the importance of plant hydraulic and anatomical traits for predicting drought-induced tree mortality, such as vessel diameter, and their potential to predict species distribution in a changing climate. A compilation of large global datasets is required to determine traits related to drought-induced embolism and test whether embolism resistance can be determined solely by anatomical traits. However, most measurements of plant hydraulic traits are labour-intense and prone to measurement artefacts. A fast, accurate and widely applicable technique is necessary for estimating xylem embolism resistance (e.g., water potential at 50\% loss of conductivity, P50), in order to improve forecasts of future forest changes. These traits and their combination must have evolved following the selective pressure of the environmental conditions in which each species occurs. Describing these environmental-trait relationships can be useful to assess potential responses to environmental change and mitigation strategies for tree species, as future warmer temperatures may be compounded by drier conditions.}, subject = {Pflanzen{\"o}kologie}, language = {en} } @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{Lu2024, author = {Lu, Jinping}, title = {The vacuolar TPC1 channel and its luminal calcium sensing site in the luminal pore entrance}, doi = {10.25972/OPUS-25135}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-251353}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2024}, abstract = {The slowly activating vacuolar SV/TPC1 channel is ubiquitously expressed in plants and provides a large cation conductance in the vacuolar membrane. Thereby, monovalent (K+, Na+) and in principle also divalent cations, such as Ca2+, can pass through the channel. The SV/TPC1 channel is activated upon membrane depolarization and cytosolic Ca2+ but inhibited by luminal calcium. With respect to the latter, two luminal Ca2+ binding sites (site 1 Asp240/Asp454/Glu528, site 2 Glu239/Asp240/Glu457) were identified to coordinate luminal Ca2+. In this work, the characteristics of the SV/TPC1 channels in terms of regulation and function were further elucidated, focusing on the TPC1s of Arabidopsis thaliana and Vicia faba. For electrophysiological analysis of the role of distinct pore residues for channel gating and luminal Ca2+ sensing, TPC1 channel variants were generated by site-directed mutagenesis and transiently expressed as eGFP/eYFP-fusion constructs in Arabidopsis thaliana mesophyll protoplasts of the TPC1 loss-of-function mutant attpc1-2. 1. As visualized by confocal fluorescence laser-scanning microscopy, all AtTPC1 (WT, E605A/Q, D606N, D607N, E605A/D606N, E605Q/D606N/D607N, E457N/E605A/D606N) and VfTPC1 channel variants (WT, N458E/A607E/ N608D) were correctly targeted to the vacuole membrane. 2. Patch-clamp studies revealed that removal of one of the negative charges at position Glu605 or Asp606 was already sufficient to promote voltage-dependent channel activation with higher voltage sensitivity. The combined neutralization of these residues (E605A/D606N), however, was required to additionally reduce the luminal Ca2+ sensitivity of the AtTPC1 channel, leading to hyperactive AtTPC1 channels. Thus, the residues Glu605/Asp606 are functionally coupled with the voltage sensor of AtTPC1 channel, thereby modulating channel gating, and form a novel luminal Ca2+ sensing site 3 in AtTPC1 at the luminal entrance of the ion transport pathway. 3. Interestingly, this novel luminal Ca2+ sensing site 3 (Glu605/Asp606) and Glu457 from the luminal Ca2+ sensing site 2 of the luminal Ca2+-sensitive AtTPC1 channel were neutralized by either asparagine or alanine in the TPC1 channel from Vicia faba and many other Fabaceae. Moreover, the VfTPC1 was validated to be a hyperactive TPC1 channel with higher tolerance to luminal Ca2+ loads which was in contrast to the AtTPC1 channel features. As a result, VfTPC1 but not AtTPC1 conferred the hyperexcitability of vacuoles. When AtTPC1 was mutated for the three VfTPC1-homologous polymorphic site residues, the AtTPC1 triple mutant (E457N/E605A/D606N) gained VfTPC1-like characteristics. However, when VfTPC1 was mutated for the three AtTPC1-homologous polymorphic site residues, the VfTPC1 triple mutant (N458E/A607E/N608D) still sustained VfTPC1-WT-like features. These findings indicate that the hyperactivity of VfTPC1 is achieved in part by the loss of negatively charged amino acids at positions that - as part of the luminal Ca2+ sensing sites 2 and 3 - are homologous to AtTPC1-Glu457/Glu605/Asp606 and are likely stabilized by other unknown residues or domains. 4.The luminal polymorphic pore residues (Glu605/Asp606 in AtTPC1) apparently do not contribute to the unitary conductance of TPC1. Under symmetrical K+ conditions, a single channel conductance of about 80 pS was determined for AtTPC1 wild type and the AtTPC1 double mutant E605A/D606A. This is in line with the three-fold higher unitary conductance of VfTPC1 (232 pS), which harbors neutral luminal pore residues at the homologous sites to AtTPC1. In conclusion, by studying TPC1 channel from Arabidopsis thaliana and Vicia faba, the present thesis provides evidence that the natural TPC1 channel variants exhibit differences in voltage gating, luminal Ca2+ sensitivity and luminal Ca2+ binding sites.}, language = {en} } @phdthesis{SchliermanngebStratmann2023, author = {Schliermann [geb. Stratmann], Anna Theresa}, title = {The Role of FGF Receptor 2 in GDF5 mediated Signal Transduction}, doi = {10.25972/OPUS-19288}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-192889}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {Bone morphogenetic proteins (BMPs) are involved in various aspects of cell-cell communication in complex life forms. They act as morphogens, help differentiate different cell types from different progenitor cells in development, and are involved in many instances of intercellular communication, from forming a body axis to healing bone fractures, from sugar metabolism to angiogenesis. If the same protein or protein family carries out many functions, there is a demand to regulate and fine-tune their biological activities, and BMPs are highly regulated to generate cell- and context-dependent outcomes. Not all such instances can be explained yet. Growth/differentiation factor (GDF)5 (or BMP14) synergizes with BMP2 on chondrogenic ATDC5 cells, but antagonizes BMP2 on myoblastic C2C12 cells. Known regulators of BMP2/GDF5 signal transduction failed to explain this context-dependent difference, so a microarray was performed to identify new, cell-specific regulatory components. One identified candidate, the fibroblast growth factor receptor (FGFR)2, was analyzed as a potential new co-receptor to BMP ligands such as GDF5: It was shown that FGFR2 directly binds BMP2, GDF5, and other BMP ligands in vitro, and FGFR2 was able to positively influence BMP2/GDF5-mediated signaling outcome in cell-based assays. This effect was independent of FGFR2s kinase activity, and independent of the downstream mediators SMAD1/5/8, p42/p44, Akt, and p38. The elevated colocalization of BMP receptor type IA and FGFR2 in the presence of BMP2 or GDF5 suggests a signaling complex containing both receptors, akin to other known co-receptors of BMP ligands such as repulsive guidance molecules. This unexpected direct interaction between FGF receptor and BMP ligands potentially opens a new category of BMP signal transduction regulation, as FGFR2 is the second receptor tyrosine kinase to be identified as BMP co-receptor, and more may follow. The integration of cell surface interactions between members of the FGF and BMP family especially may widen the knowledge of such cellular communication mechanisms which involve both growth factor families, including morphogen gradients and osteogenesis, and may in consequence help to improve treatment options in osteochodnral diseases.}, subject = {Molekularbiologie}, language = {en} } @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{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{Fei2023, author = {Fei, Lin}, title = {Optogenetic regulation of osmolarity and water flux}, doi = {10.25972/OPUS-32309}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-323092}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {Optogenetics is a powerful technique that utilizes light to precisely regulate physiological activities of neurons and other cell types. Specifically, light-sensitive ion channels, pumps or enzymes are expressed in cells to enable their regulation by illumination, thus allowing for precise control of biochemical signaling pathways. The first part of my study involved the construction, optimization, and characterization of two optogenetic tools, KCR1 and NCR1. Elena Govorunova et al. discovered a lightgated potassium channel, KCR1, in the protozoan Hyphochytrium catenoides. Traditional potassium ion channels are classified as either ligand-gated or voltage-gated and possess conserved pore-forming domains and K+ -selective filters. However, KCR1 is unique in that it does not contain the signature sequence of previously known K+ channels and is a channelrhodopsin. We synthesized the KCR1 plasmid according to the published sequence and expressed it in Xenopus oocytes. Due to the original KCR1 current being too small, I optimized it into KCR1 2.0 to improve its performance by fusing LR (signal peptide LucyRho, enhances expression) at the N-terminal and T (trafficking signal peptide) and E (ER export signal peptide) at the C-terminal. Additionally, I investigated the light sensitivity, action spectrum, and kinetics of KCR1 2.0 in Xenopus oocytes. The potassium permeability of KCR1 2.0, PK/Pna  24, makes KCR1 2.0 a powerful hyperpolarizing tool that can be used to inhibit neuronal firing in animals. Inspired by KCR1, we used the KCR1 sequence as a template for gene sequence alignment with the sequences in H. catenoides. We found that NCR1 and KCR1 have similar gene sequences. NCR1 was characterized by us as a light-gated sodium channel. This NCR1 was also characterized and published by Govorunova et al. very recently, with the name HcCCR. Due to the original NCR1 current being too small, I optimized it into NCR1 2.0 to improve its performance by fusing LR at the N-terminal and T and E at the C-terminal, which significantly improved the expression level and greatly increased the current amplitude of NCR1. Full-length NCR1 2.0 contains 432 amino acids. To test whether the number of amino acids changes the characteristics of NCR1 2.0, we designed NCR1 2.0 (330), NCR1 2.0 (283), and NCR1 2.0 (273) by retaining the number of amino acids at 330, 280, and 273 in NCR1 2.0, respectively. As the number of amino acids decreased, the current in NCR1 2.0 increased. I also investigated the light sensitivity, action spectrum, and kinetics of NCR1 2.0 (273) in the Xenopus Abstract 2 oocytes. We performed four point mutations at amino acid positions 133 and 116 of NCR1 2.0 and analyzed the reversal potentials of the mutants. The mutations were as follows: NCR1 2.0 (273 D116H), NCR1 2.0 (273 D116E), NCR1 2.0 (283 V133H), and NCR1 2.0 (283 D116Q). The second part of this study focuses on light-induced water transport using optogenetic tools. We explored the use of optogenetic tools to regulate water flow by changing the osmolarity in oocytes. Water flux through AQP1 is driven by the osmotic gradient that results from concentration differences of small molecules or ions. Therefore, we seek to regulate ion concentrations, using optogenetic tools to regulate the flux of water noninvasively. To achieve this, I applied the light-gated cation channels XXM 2.0 and NCR1 2.0 to regulate the concentration of Na+ , while K + channel KCR1 2.0 was used to regulate K + concentration. As Na+ flows into the Xenopus oocytes, the membrane potential of the oocytes becomes positive, and Clcan influx through the light-gated anion channel GtACR1. By combining these optogenetic tools to regulate NaCl or KCl concentrations, I can change the osmolarity inside the oocytes, thus regulating the flux of water. I co-expressed AQP1 with optogenetic tools in the oocytes to accelerate water flux. Overall, I designed three combinations (1: AQP1, XXM 2.0 and GtACR1. 2: AQP1, NCR1 2.0 and GtACR1. 3: AQP1, KCR1 2.0 and GtACR1) to regulate the flow of water in oocytes. The shrinking or swelling of the oocytes can only be achieved when AQP1, light-gated cation channels (XXM 2.0/NCR1 2.0/KCR1 2.0), and light-gated anion channels (GtACR1) are expressed together. The illumination after expression of either or both alone does not result in changes in oocyte morphology. In sum, I demonstrated a novel strategy to manipulate water movement into and out of Xenopus oocytes, non-invasively through illumination. These findings provide a new avenue to interfere with water homeostasis as a means to study related biological phenomena across cell types and organisms.}, subject = {Osmolarit{\"a}t}, language = {en} } @phdthesis{Jaślan2023, author = {Jaślan, Justyna Joanna}, title = {R-type currents in \(Arabidopsis\) guard cells: properties and molecular nature}, doi = {10.25972/OPUS-18883}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-188836}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {In contrast to the well described molecular basis for S-type anion currents, the genes underlying R-type anion currents were unknown until 2010. Meyer S. and colleagues (2010) showed that, localized in the guard cell plasma membrane, AtALMT12 is an R-type anion channel involved in stomatal closure. However, knocking out AtALMT12 did not fully shut down R-type currents; the almt12 loss-of-function mutant has residual R-type-like currents indicating that ALMT12 is not the only gene encoding Arabidopsis thaliana R-type channels (Meyer S. et al., 2010). This PhD thesis is focussed on understanding the properties, regulation and molecular nature of the R-type channels in Arabidopsis thaliana plants. To fulfil these aims, the patch clamp technique was used to characterize electrical features of R-type currents in various conditions such as the presence/absence of ATP, variation in cytosolic calcium concentration or the presence of cytosolic chloride. Electrophysiological study revealed many similarities between the features of Arabidopsis thaliana R-type currents (Col0) and residual R-type currents (the almt12 loss-of-function mutant). Strong voltage dependency, channel activity in the same voltage range, position of maximal recorded current and blockage by cytosolic ATP all pointed to a shared phylogenetic origin of the channels underlying these R-type currents. Expression patterns of the ALMT family members for Col0 and the almt12 mutant revealed ALMT13 and AMT14 as potential candidates of the R-type channels. Electrical characterization of Col0, almt12 and the two double loss-of-function mutants (almt12/almt13 and almt12/almt14) strongly suggest that ALMT13 mediates the calcium-dependent R-type current component that is directly regulated by cytosolic calcium. Additionally, similarly to ALMT12, ALMT14 could participate as a calcium-independent R-type anion channel. Differences in response to the cytosolic calcium concentration between ALMT12, ALMT13 and ALMT14 suggest their possible involvement in different signalling pathways leading to stomatal closure. Moreover, a study performed for the two Arabidopsis thaliana ecotypes Col0 and WS showed drastically increased ALMT13 expression for WS, which is related to R-type current properties. The WS ecotype has calcium-dependent R-type current behaviour, while it is calcium-independent in Col0. Furthermore, this plant line showed lower peak current densities compared to Col0 and almt mutants. These facts strongly suggest interaction between ALMT12 and ALMT13, with ALMT13 as a repressor of the ALMT12. Acquired patch clamp data revealed sulphate-dependent increases in ALMT13 current. This could be caused by changes in absolute open probability and/or permeability for sulphate and possibly chloride and links ALMT13 with sulphate-mediated stomatal closure under drought stress. It was then confirmed that ATP affects R-type currents. In contrast to Vicia faba, ATP was identified as a negative regulator of the Arabidopsis thaliana R-type anion channels. The effect of ATP is ambiguous but there is a high probability that it is a result of direct block and phosphorylation. However, the phosphorylation site and place of ATP binding needs further investigation. The story of the ALMT family, as examined in this thesis, sheds light on the complexity of the stomatal closure process.}, language = {en} } @phdthesis{Kunz2023, author = {Kunz, Marcel}, title = {Diffusion kinetics of organic compounds and water in plant cuticular model wax under the influence of diffusing barrier-modifying adjuvants}, doi = {10.25972/OPUS-27487}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-274874}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {To reach their target site, systemic pesticides must enter the plant from a spray droplet applied in the field. The uptake of an active ingredient (AI) takes place via the barrier-forming cuticular membrane, which is the outermost layer of the plant, separating it from the surrounding environment. Formulations are usually used which, in addition to the AI, also contain stabilizers and adjuvants. Adjuvants can either have surface-active properties or they act directly as barrier-modifying agents. The latter are grouped in the class of accelerating adjuvants, whereby individual variants may also have surface-active properties. The uptake of a pesticide from a spray droplet depends essentially on its permeability through the cuticular barrier. Permeability defines a combined parameter, which is the product of AI mobility and AI solubility within the cuticle. In recent decades, several tools have been developed that allowed the determination of individual parameters of organic compound penetration across the cuticular membrane. Nevertheless, earlier studies showed that mainly cuticular waxes are the barrier-determining component of the cuticular membrane and additionally, it was shown that mainly the very-long-chain aliphatic compounds (VLCAs) are responsible for establishing an effective barrier. However, the barrier-determining role of the individual VLCAs, being classified according to their respective functional groups, is still unknown. Therefore, the following objectives were pursued and achieved in this work: (1) A new ATR-FTIR-based approach was developed to measure the temperature-dependent real-time diffusion kinetics of organic models for active ingredients (AIs) in paraffin wax, exclusively consisting of very-long chain alkanes. (2) The developed ATR-FTIR approach was applied to determine the diffusion kinetics of self-accelerating adjuvants in cuticular model waxes of different VLCA composition. At the same time, wax-specific changes were recorded in the respective IR spectra, which provided information about the respective wax modification. (3) The ATR-FTIR method was used to characterize the diffusion kinetics, as well as to determine the wax-specific sorption capacities for an AI-modeling organic compound and water in cuticular model waxes after adjuvant treatment. Regarding the individual chemical compositions and structures, conclusions were drawn about the adjuvant-specific modes of action (MoA). In the first chapter, the ATR-FTIR based approach to determine organic compound diffusion kinetics in paraffin wax was successfully established. The diffusion kinetics of the AI modelling organic compounds heptyl parabene (HPB) and 4-cyanophenol (CNP) were recorded, comprising different lipophilicities and molecular volumes typical for AIs used in pesticide formulations. Derived diffusion coefficients ranged within 10-15 m2 s-1, thus being thoroughly higher than those obtained from previous experiments using an approach solely investigating desorption kinetics in reconstituted cuticular waxes. An ln-linear dependence between the diffusion coefficients and the applied diffusion temperature was demonstrated for the first time in cuticular model wax, from which activation energies were derived. The determined activation energies were 66.2 ± 7.4 kJ mol-1 and 56.4 ± 9.8 kJ mol-1, being in the expected range of already well-founded activation energies required for organic compound diffusion across cuticular membranes, which again confirmed the significant contribution of waxes to the cuticular barrier. Deviations from the assumed Fickian diffusion were attributed to co-occurring water diffusion and apparatus-specific properties. In the second and third chapter, mainly the diffusion kinetics of accelerating adjuvants in the cuticular model waxes candelilla wax and carnauba wax were investigated, and simultaneously recorded changes in the wax-specific portion of the IR spectrum were interpreted as indications of plasticization. For this purpose, the oil derivative methyl oleate, as well as the organophosphate ester TEHP and three non-ionic monodisperse alcohol ethoxylates (AEs) C12E2, C12E4 and C12E6 were selected. Strong dependence of diffusion on the respective principal components of the mainly aliphatic waxes was demonstrated. The diffusion kinetics of the investigated adjuvants were faster in the n-alkane dominated candelilla wax than in the alkyl ester dominated carnauba wax. Furthermore, the equilibrium absorptions, indicating equilibrium concentrations, were also higher in candelilla wax than in carnauba wax. It was concluded that alkyl ester dominated waxes feature higher resistance to diffusion of accelerating adjuvants than alkane dominated waxes with shorter average chain lengths due to their structural integrity. This was also found either concerning candelilla/policosanol (n-alcohol) or candelilla/rice bran wax (alkyl-esters) blends: with increasing alcohol concentration, the barrier function was decreased, whereas it was increased with increasing alkyl ester concentration. However, due to the high variability of the individual diffusion curves, only a trend could be assumed here, but significant differences were not shown. The variability itself was described in terms of fluctuating crystalline arrangements and partial phase separation of the respective wax mixtures, which had inevitable effects on the adjuvant diffusion. However, diffusion kinetics also strongly depended on the studied adjuvants. Significantly slower methyl oleate diffusion accompanied by a less pronounced reduction in orthorhombic crystallinity was found in carnauba wax than in candelilla wax, whereas TEHP diffusion was significantly less dependent on the respective wax structure and therefore induced considerable plasticization in both waxes. Of particular interest was the AE diffusion into both waxes. Differences in diffusion kinetics were also found here between candelilla blends and carnauba wax. However, these depended equally on the degree of ethoxylation of the respective AEs. The lipophilic C12E2 showed approximately Fickian diffusion kinetics in both waxes, accompanied by a drastic reduction in orthorhombic crystallinity, especially in candelilla wax, whereas the more hydrophilic C12E6 showed significantly retarded diffusion kinetics associated with a smaller effect on orthorhombic crystallinity. The individual diffusion kinetics of the investigated adjuvants sometimes showed drastic deviations from the Fickian diffusion model, indicating a self-accelerating effect. Hence, adjuvant diffusion kinetics were accompanied by a distinct initial lag phase, indicating a critical concentration in the wax necessary for effective penetration, leading to sigmoidal rather than to exponential diffusion kinetics. The last chapter dealt with the adjuvant-affected diffusion of the AI modelling CNP in candelilla and carnauba wax. Using ATR-FTIR, diffusion kinetics were recorded after adjuvant treatment, all of which were fully explicable based on the Fickian model, with high diffusion coefficients ranging from 10-14 to 10-13 m2 s-1. It is obvious that the diffusion coefficients presented in this work consistently demonstrated plasticization induced accelerated CNP mobilities. Furthermore, CNP equilibrium concentrations were derived, from which partition- and permeability coefficients could be determined. Significant differences between diffusion coefficients (mobility) and partition coefficients (solubility) were found on the one hand depending on the respective waxes, and on the other hand depending on treatment with respective adjuvants. Mobility was higher in candelilla wax than in carnauba wax only after methyl oleate treatment. Treatment with TEHP and AEs resulted in higher CNP mobility in the more polar alkyl ester dominated carnauba wax. The partition coefficients, on the other hand, were significantly lower after methyl oleate treatment in both candelilla and carnauba wax as followed by TEHP or AE treatment. Models were designed for the CNP penetration mode considering the respective adjuvants in both investigated waxes. Co-penetrating water, which is the main ingredient of spray formulations applied in the field, was likely the reason for the drastic differences in adjuvant efficacy. Especially the investigated AEs favored an enormous water uptake in both waxes with increasing ethoxylation level. Surprisingly, this effect was also found for the lipophilic TEHP in both waxes. This led to the assumption that the AI permeability is not exclusively determined by adjuvant induced plasticization, but also depends on a "secondary plasticization", induced by adjuvant-attracted co-penetrating water, consequently leading to swelling and drastic destabilization of the crystalline wax structure. The successful establishment of the presented ATR-FTIR method represents a milestone for the study of adjuvant and AI diffusion kinetics in cuticular waxes. In particular, the simultaneously detectable wax modification and, moreover, the determinable water uptake form a perfect basis to establish the ATR-FTIR system as a universal screening tool for wax-adjuvants-AI-water interaction in crop protection science.}, subject = {Pflanzen}, language = {en} } @phdthesis{Zhou2023, author = {Zhou, Yang}, title = {The Exploitation of Opsin-based Optogenetic Tools for Application in Higher Plants}, doi = {10.25972/OPUS-23696}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-236960}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {The discovery, heterologous expression, and characterization of channelrhodopsin-2 (ChR2) - a light-sensitive cation channel found in the green alga Chlamydomonas reinhardtii - led to the success of optogenetics as a powerful technology, first in neuroscience. ChR2 was employed to induce action potentials by blue light in genetically modified nerve cells. In optogenetics, exogenous photoreceptors are expressed in cells to manipulate cellular activity. These photoreceptors were in the beginning mainly microbial opsins. During nearly two decades, many microbial opsins and their mutants were explored for their application in neuroscience. Until now, however, the application of optogenetics to plant studies is limited to very few reports. Several optogenetic strategies for plant research were demonstrated, in which most attempts are based on non-opsin optogenetic tools. Opsins need retinal (vitamin A) as a cofactor to generate the functional protein, the rhodopsin. As most animals have eyes that contain animal rhodopsins, they also have the enzyme - a 15, 15'-Dioxygenase - for retinal production from food-supplied provitamin A (beta-carotene). However, higher plants lack a similar enzyme, making it difficult to express functional rhodopsins successfully in plants. But plant chloroplasts contain plenty of beta-carotene. I introduced a gene, coding for a 15, 15'-Dioxygenase with a chloroplast target peptide, to tobacco plants. This enzyme converts a molecule of β-carotene into two of all-trans-retinal. After expressing this enzyme in plants, the concentration of all-trans-retinal was increased greatly. The increased retinal concentration led to increased expression of several microbial opsins, tested in model higher plants. Unfortunately, most opsins were observed intracellularly and not in the plasma membrane. To improve their localization in the plasma membrane, some reported signal peptides were fused to the N- or C-terminal end of opsins. Finally, I helped to identify three microbial opsins -- GtACR1 (a light-gated anion channel), ChR2 (a light-gated cation channel), PPR (a light-gated proton pump) which express and work well in the plasma membrane of plants. The transgene plants were grown under red light to prevent activation of the expressed opsins. Upon illumination with blue or green light, the activation of these opsins then induced the expected change of the membrane potential, dramatically changing the phenotype of plants with activated rhodopsins. This study is the first which shows the potential of microbial opsins for optogenetic research in higher plants, using the ubq10 promoter for ubiquitous expression. I expect this to be just the beginning, as many different opsins and tissue-specific promoters for selective expression now can be tested for their usefulness. It is further to be expected that the here established method will help investigators to exploit more optogenetic tools and explore the secrets, kept in the plant kingdom.}, language = {en} } @phdthesis{YuStrzelczyk2023, author = {Yu-Strzelczyk, Jing}, title = {Generation and Characterization of novel proteins for light-activated hyperpolarization of cell membranes}, doi = {10.25972/OPUS-26675}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-266752}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {The light-gated cation channel Channelrhodopsin-2 was discovered and characterized in 2003. Already in 2005/2006 five independent groups demonstrated that heterologous expression of Channelrhodopsin-2 is a highly useful and simply applicable method for depolarizing and thereby activating nerve cells. The application of Channelrhodopsin-2 revolutionized neuroscience research and the method was then called optogenetics. In recent years more and more light-sensitive proteins were successfully introduced as "optogenetic tools", not only in neuroscience. Optogenetic tools for neuronal excitation are well developed with many different cation-conducting wildtype and mutated channelrhodopsins, whereas for inhibition of neurons in the beginning (2007) only hyperpolarizing ion pumps were available. The later discovered light-activated anion channels (anion channelrhodopsins) can be useful hyperpolarizers, but only at low cytoplasmic anion concentration. For this thesis, I optimized CsR, a proton-pumping rhodopsin from Coccomyxa subellipsoidea, which naturally shows a robust expression in Xenopus laevis oocytes and plant leaves. I improved the expression and therefore the photocurrent of CsR about two-fold by N-terminal modification to the improved version CsR2.0, without altering the proton pump function and the action spectrum. A light pulse hyperpolarised the mesophyll cells of CsR2.0-expressing transgenic tobacco plants (N. tabacum) by up to 20 mV from the resting membrane potential of -150 to -200 mV. The robust heterologous expression makes CsR2.0 a promising optogenetic tool for hyperpolarization in other organisms as well. A single R83H point-mutation converted CsR2.0 into a light-activated (passive) proton channel with a reversal potential close to the Nernst potential for intra-/extra-cellular H+ concentration. This light-gated proton channel is expected to become a further useful optogenetic tool, e.g. for analysis of pH-regulation in cells or the intercellular space. Ion pumps as optogenetic tools require high expression levels and high light intensity for efficient pump currents, whereas long-term illumination may cause unwanted heating effects. Although anion channelrhodopsins are effective hyperpolarizing tools in some cases, their effect on neuronal activity is dependent on the cytoplasmic chloride concentration which can vary among neurons. In nerve cells, increased conductance for potassium terminates the action potential and K+ conductance underlies the resting membrane potential in excitable cells. Therefore, several groups attempted to synthesize artificial light-gated potassium channels but 2 all of these published innovations showed serious drawbacks, ranging from poor expression over lacking reversibility to poor temporal precision. A highly potassium selective light-sensitive silencer of action potentials is needed. To achieve this, I engineered a light-activated potassium channel by the genetic fusion of a photoactivated adenylyl cyclase, bPAC, and a cAMP-gated potassium channel, SthK. Illumination activates bPAC to produce cAMP and the elevated cAMP level opens SthK. The slow diffusion and degradation of cAMP makes this construct a very light-sensitive, long-lasting inhibitor. I have successfully developed four variants with EC50 to cAMP ranging from 7 over 10, 21, to 29 μM. Together with the original fusion construct (EC50 to cAMP is 3 μm), there are five different light- (or cAMP-) sensitive potassium channels for researchersto choose, depending on their cell type and light intensity needs.}, subject = {Proteine}, language = {en} } @phdthesis{Huang2023, author = {Huang, Shouguang}, title = {Role of ABA-induced Ca\(^{2+}\) signals, and the Ca\(^{2+}\)-controlled protein kinase CIPK23, in regulation of stomatal movements}, doi = {10.25972/OPUS-20473}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-204737}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {Stomata are pores in the leaf surface, formed by pairs of guard cells. The guard cells modulate the aperture of stomata, to balance uptake of CO2 and loss of water vapor to the atmosphere. During drought, the phytohormone abscisic acid (ABA) provokes stomatal closure, via a signaling chain with both Ca2+-dependent and Ca2+-independent branches. Both branches are likely to activate SLAC1-type (Slow Anion Channel Associated 1) anion channels that are essential for initiating the closure of stomata. However, the importance of the Ca2+-dependent signaling branch is still debated, as the core ABA signaling pathway only possesses Ca2+-independent components. Therefore, the aim of this thesis was to address the role of the Ca2+-dependent branch in the ABA signaling pathway of guard cells. In the first part of the thesis, the relation between ABA-induced Ca2+ signals and stomatal closure was studied, with guard cells that express the genetically encoded Ca2+-indicator R-GECO1-mTurquoise. Ejection of ABA into the guard cell wall rapidly induced stomatal closure, however, only in ¾ of the guard cells ABA evoked a cytosolic Ca2+ signal. A small subset of stomata (¼ of the experiments) closed without Ca2+ signals, showing that the Ca2+ signals are not essential for ABA-induced stomatal closure. However, stomata in which ABA evoked Ca2+ signals closed faster as those in which no Ca2+ signals were detected. Apparently, ABA-induced Ca2+ signals enhance the velocity of stomatal closure. In addition to ABA, hyperpolarizing voltage pulses could also trigger Ca2+ signals in wild type guard cells, which in turn activated S-type anion channels. However, these voltage pulses failed to elicit S-type anion currents in the slac1/slah3 guard cells, suggesting that SLAC1 and SLAH3 contribute to Ca2+-activated conductance. Taken together, our data indicate that ABA-induced Ca2+ signals enhance the activity of S-type anion channels, which accelerates stomatal closure. The second part of the thesis deals with the signaling pathway downstream of the Ca2+ signals. Two types of Ca2+-dependent protein kinase modules (CPKs and CBL/CIPKs) have been implicated in guard cells. We focused on the protein kinase CIPK23 (CBL-Interacting Protein Kinase 23), which is activated by the Ca2+-dependent protein CBL1 or 9 (Calcineurin B-Like protein 1 or 9) via interacting with the NAF domain of CIPK23. The CBL1/9-CIPK23 complex has been shown to affect stomatal movements, but the underlying molecular mechanisms remain largely unknown. We addressed this topic by using an estrogen-induced expression system, which specifically enhances the expression of wild type CIPK23, a phosphomimic CIPK23T190D and a kinase dead CIPK23K60N in guard cells. Our data show that guard cells expressing CIPK23T190D promoted stomatal opening, while CIPK23K60N enhanced ABA-induced stomatal closure, suggesting that CIPK23 is a negative regulator of stomatal closure. Electrophysiological measurements revealed that the inward K+ channel currents were similar in guard cells that expressed CIPK23, CIPK23T190D or CIPK23K60N, indicating that CIPK23-mediated inward K+ channel AKT1 does not contribute to stomatal movements. Expression of CIPK23K60N, or loss of CIPK23 in guard cells enhanced S-type anion activity, while the active CIPK23T190D inhibited the activity of these anion channels. These results are in line with the detected changes in stomatal movements and thus indicate that CIPK23 regulates stomatal movements by inhibiting S-type anion channels. CIPK23 thus serves as a brake to control anion channel activity. Overall, our findings demonstrate that CIPK23-mediated stomatal movements do not depend on CIPK23-AKT1 module, instead, it is achieved by regulating S-type anion channels SLAC1 and SLAH3. In sum, the data presented in this thesis give new insights into the Ca2+-dependent branch of ABA signaling, which may help to put forward new strategies to breed plants with enhanced drought stress tolerance, and in turn boost agricultural productivity in the future.}, language = {en} } @phdthesis{Henninger2022, author = {Henninger, Markus}, title = {Funktion der zentralen metabolischen Kinase SnRK1 und von ihr abh{\"a}ngiger Transkriptionsfaktoren bei der Mobilisierung von Speicherstoffen w{\"a}hrend der \(Arabidopsis\) Keimlingsentwicklung}, doi = {10.25972/OPUS-21430}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-214305}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2022}, abstract = {Pflanzen m{\"u}ssen sich w{\"a}hrend der Samenkeimung und Keimlingsentwicklung {\"u}ber eingelagerte Speicherstoffe heterotroph versorgen, bis sie, nach Etablierung ihres Photosyntheseapparats, einen autotrophen Lebensstil f{\"u}hren k{\"o}nnen. Diese Arbeit geht von der Hypothese aus, dass der evolution{\"a}r konservierten zentral-metabolischen Kinase Snf1-RELATED PROTEIN KINASE 1 (SnRK1) eine besondere Rolle bei der Mobilisierung von Speicherstoffen w{\"a}hrend der Keimlingsentwicklung zukommt. W{\"a}hrend die Bedeutung von SnRK1 als zentraler Regulator katabolischer Prozesse unter Energiemangel- und Stresssituationen bereits gezeigt wurde, war die Funktion von SnRK1 im Zusammenhang mit der Samenkeimung weitgehend ungekl{\"a}rt. In dieser Arbeit konnte erstmals gezeigt werden, dass SnRK1 in Arabidopsis die Mobilisierung und Degradation von Speicherstoffen, insbesondere von Triacylglyceride (TAGs), Samenspeicherproteinen und Aminos{\"a}uren, steuert. Sowohl Studien zur Lokalisation von SnRK1:GFP-Fusionsproteinen als auch Kinaseaktivit{\"a}tsassays unterst{\"u}tzen eine m{\"o}gliche Funktion von SnRK1 w{\"a}hrend der Keimlingsentwicklung. Eine induzierbare snrk1-knockdown Mutante zeigt neben einem eingeschr{\"a}nkten Wurzel- und Hypokotylwachstum auch keine Ausbildung eines Photosyntheseapparats, was die zentrale Rolle der SnRK1 in diesem fr{\"u}hen Entwicklungsstadium untermauert. Durch F{\"u}tterungsexperimente mit Glukose konnte der Ph{\"a}notyp einer snrk1 -Mutante in Keimlingen gerettet werden. Dies zeigt, dass der metabolische Block durch externe Gabe von Kohlenhydraten umgangen werden kann. Die zentrale Funktion von SnRK1 ist folgich der Abbau von Speicherstoffen und keine allgemeine Deregulation des pflanzlichen Stoffwechsels. Durch massenspektrometrische Untersuchungen von Keimlingen des Wildtyps und der snrk1-Mutante konnte gezeigt werden, dass TAGs in der Mutante in der sp{\"a}- ten Keimlingsentwicklung ab Tag 4 langsamer abgebaut werden als im Wildtyp. Ebenso werden Samenspeicherproteine in der Mutante langsamer degradiert, wodurch die Verf{\"u}gbarkeit von freien Aminos{\"a}uren in geringer ist. Entgegen der allgemeinen Annahme konnte gezeigt werden, dass w{\"a}hrend der Keimlingsentwicklung zumindest in Arabidopsis, einer {\"o}lhaltigen Pflanze, zun{\"a}chst Kohlenhydrate in Form von Saccharose abgebaut werden, bevor die Degradation von TAGs und Aminos{\"a}uren beginnt. Diese Abbauprodukte k{\"o}nnen dann der Glukoneogenese zugef{\"u}hrt werden um daraus Glukose herzustellen. Mittels Transkriptom-Analysen konnten zentrale SnRK1-abh{\"a}ngige Gene in der Speicherstoffmobilisierung von TAG, beispielsweise PEROXISOMAL NAD-MALATE DEHYDROGENASE 2 (PMDH2) und ACYL-CoA-OXIDASE 4 (ACX4), und Aminos{\"a}uren identifiziert werden. Somit wurde ein Mechanismus der SnRK1-abh{\"a}ngigen Genregulation w{\"a}hrend der Samenkeimung in Arabidopsis gefunden. Bei der Degradation von Aminos{\"a}uren wird die cytosolische PYRUVATE ORTHOPHOSPHATE DIKINASE (cyPPDK), ein Schl{\"u}sselenzym beim Abbau bestimmter Aminos{\"a}uren und bei der Glukoneogenese, SnRK1-abh{\"a}ngig transkriptionell reguliert. Durch Koregulation konnte der Transkriptionsfaktor bZIP63 (BASIC LEUCINE ZIPPER 63) gefunden werden, dessen Transkription ebenfalls SnRK1-abh{\"a}ngig reguliert wird. Außerdem konnte die Transkription von cyPPDK in bzip63-Mutanten nur noch sehr schwach induziert werden. In Protoplasten konnte der cyPPDK-Promotor durch Aktivierungsexperimente mit bZIP63 und SnRK1α1 induziert werden. Durch Mutationskartierung und Chromatin-Immunopr{\"a}zipitation (ChIP)PCR konnte mehrfach eine direkte Bindung von bZIP63 an den cyPPDK-Promotor nachgewiesen werden. Zusammenfassend ergibt sich ein mechanistisches Arbeitsmodell, in dem bZIP63 durch SnRK1 phosphoryliert wird und durch Bindung an regulatorische G-Box cis-Elemente im cyPPDK- Promotor dessen Transkription anschaltet. Infolgedessen werden Aminos{\"a}uren abgebaut und wird {\"u}ber die Glukoneogenese Glukose aufgebaut. Dieser Mechanismus ist essentiell f{\"u}r die {\"U}bergangsphase zwischen heterotropher und autotropher Lebensweise, und tr{\"a}gt dazu bei, die im Samen vorhandenen Ressourcen dem Keimling zum idealen Zeitpunkt zug{\"a}nglich zu machen. Dar{\"u}ber hinaus werden Gene im Abbau von verzweigtkettigen Aminos{\"a}uren ebenfalls durch bZIP63 reguliert. Dabei wird dem Keimling Energie in Form von Adenosin-Triphosphat (ATP) zur Verf{\"u}gung gestellt. Zusammengefasst zeigen die Ergebnisse dieser Arbeit, dass die Mobilisierung von Speicherstoffen auch w{\"a}hrend der Keimlingsentwicklung direkt von SnRK1 abh{\"a}ngig ist. Die umfangreichen Datens{\"a}tze der RNA-Seq-Analysen bieten zudem die M{\"o}glichkeit, weitere SnRK1-abh{\"a}ngige Gene der Speichermobilisierung zu identifizieren und somit einem besseren Verst{\"a}ndnis der Keimlingsentwicklung beizutragen. Aufgrund der zentralen Bedeutung der SnRK1-Kinase in diesem entscheidenden Entwicklungsschritt ist davon auszugehen, dass diese Erkenntnisse mittelfristig auch f{\"u}r bessere Keimungsraten und somit bessere Ertr{\"a}ge in der Landwirtschaft genutzt werden k{\"o}nnen.}, subject = {SnRK1}, language = {de} } @phdthesis{vonRueden2022, author = {von R{\"u}den, Martin Frederik}, title = {The Venus flytrap - Role of oxylipins in trap performance of Dionaea muscipula}, doi = {10.25972/OPUS-27385}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-273854}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2022}, abstract = {A part of the plant kingdom consists of a variety of carnivorous plants. Some trap their prey using sticky leaves, others have pitfall traps where prey cannot escape once it has fallen inside. A rare trap type is the snap-trap: it appears only twice in the plant kingdom, in the genera Aldrovanda and Dionaea. Even Charles Darwin himself described Dionaea muscipula, the Venus flytrap, with the following words "This plant, commonly called Venus' fly-trap, from the rapidity and force of its movements, is one of the most wonderful in the world". For a long time now, the mechanisms of Dionaea's prey recognition, capture and utilization are of interest for scientists and have been studied intensively. Dionaea presents itself with traps wide-open, ready to catch insects upon contact. For this, the insect has to touch the trigger hairs of the opened trap twice within about 20-30 seconds. Once the prey is trapped, the trap lobes close tight, forming a hermetically sealed "green stomach". Until lately, there was only limited knowledge about the molecular and hormonal mechanisms which lead to prey capture and excretion of digestive fluids. It is known that the digestion process is very water-consuming; therefore, the interplay of digestion-inducing and digestion inhibiting substances was to be analyzed in this work, to elucidate the fine-tuning of the digestive pathway. Special attention was given to the impact of phytohormones on mRNA transcript levels of digestion-related proteins after various stimuli as well as their effect on Dionaea's physiological responses. Jasmonic acid (JA) and its isoleucine-conjugated form, JA-Ile, are an important signal in the jasmonate pathway. In the majority of non-carnivorous plants, jasmonates are critical for the defense against herbivory and pathogens. In Dionaea, this defense mechanism has been restructured towards offensive prey catching. One question in this work was how the frequency of trigger hair bendings is related to the formation of jasmonates and the induction of the digestion process. Upon contact of a prey with the trigger hairs in the inside of the trap, the trap closes and jasmonates are produced biosynthetically. JA-Ile interacts with the COI1- receptor, thereby activating the digestion pathway which leads to the secretion of digestive fluid and production of transporters needed to take up prey-derived nutrients. In this work it could be shown that the number of trigger hair bendings is positively correlated with the level and duration of transcriptional induction of several digestive enzymes/hydrolases. Abscisic acid (ABA) acts, along with many other functions, as the plant "drought stress hormone". It is synthesized either by roots as the primary sensor for water shortage or by guard cells in the leaves. ABA affects a network of several thousand genes whose regulation prepares the plant for drought and initiates protective measurements. It was known from previous work that the application of ABA for 48 hours increased the required amount of trigger hair bendings to achieve trap closure. As the digestion process is very water-intensive, the question arose how exactly the interplay between the jasmonate- and the ABA-pathway is organized, and if ABA could stop the running digestion process once it had been activated. In the present work it could be shown that the application of ABA on intact traps prior to mechanically stimulating the trigger hairs (mechanostimulation) already significantly reduced the transcription of digestive enzymes for an incubation time as short as 4 h, showing that already short-term exposure to ABA counteracts the effects of jasmonates when it comes to initiating the digestion process, but does not inhibit trap closure. Incubation for 24 and 48 hours with 100 μM active ABA had no effect on trap reopening, only very high levels of 200 μM of active ABA inhibited trap reopening but also led to tissue necrosis. As the application of ABA could reduce the transcription of digestive hydrolases, it is likely that Dionaea can stop the digestion process, if corresponding external stimuli are received. Another factor, which only emerged later, was the effect of the wounding-induced systemic jasmonate burst. As efficient as ABA was in inhibiting marker hydrolase expression after mechanostimulation in intact plants, the application of ABA on truncated traps was not able to inhibit mechanostimulation-induced marker hydrolase expression. One reason might be that the ABA-signal is perceived in the roots, and therefore truncated traps were not able to react to it. Another reason might be that the wounding desensitized the tissue for the ABAsignal. Further research is required at this point. Inhibitors of the jasmonate pathway were also used to assess their effect on the regulation of Dionaea´s hunting cycle. Coronatine-O-methyloxime proved to be a potent inhibitor of mechanostimulation-induced expression of digestive enzymes, thus confirming the key regulatory role of jasmonates for Dionaea´s prey consumption mechanism. In a parallel project, the generation of in vitro cultures from sterilized seeds and single plant parts proved successful, which may be important for stock-keeping of future transgenic lines. Protoplasts were generated from leaf blade tissue and transiently transformed, expressing the reporter protein YFP after 24 h of incubation. In the future this might be the starting point for the generation of transgenic lines or the functional testing of DNA constructs.}, subject = {Venusfliegenfalle}, language = {en} } @phdthesis{Yang2022, author = {Yang, Shang}, title = {Characterization and engineering of photoreceptors with improved properties for optogenetic application}, doi = {10.25972/OPUS-20527}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-205273}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2022}, abstract = {Optogenetics became successful in neuroscience with Channelrhodopsin-2 (ChR2), a light-gated cation channel from the green alga Chlamydomonas reinhardtii, as an easy applicable tool. The success of ChR2 inspired the development of various photosensory proteins as powerful actuators for optogenetic manipulation of biological activity. However, the current optogenetic toolbox is still not perfect and further improvements are desirable. In my thesis, I engineered and characterized several different optogenetic tools with new features. (i) Although ChR2 is the most often used optogenetic actuator, its single-channel conductance and its Ca2+ permeability are relatively low. ChR2 variants with increased Ca2+ conductance were described recently but a further increase seemed possible. In addition, the H+ conductance of ChR2 may lead to cellular acidification and unintended pH-related side effects upon prolonged illumination. Through rational design, I developed several improved ChR2 variants with larger photocurrent, higher cation selectivity, and lower H+ conductance. (ii) The light-activated inward chloride pump NpHR is a widely used optogenetic tool for neural silencing. However, pronounced inactivation upon long time illumination constrains its application for long-lasting neural inhibition. I found that the deprotonation of the Schiff base underlies the inactivation of NpHR. Through systematically exploring optimized illumination schemes, I found illumination with blue light alone could profoundly increase the temporal stability of the NpHR-mediated photocurrent. A combination of green and violet light eliminates the inactivation effect, similar to blue light, but leading to a higher photocurrent and therefore better light-induced inhibition. (iii) Photoactivated adenylyl cyclases (PACs) were shown to be useful for light-manipulation of cellular cAMP levels. I developed a convenient in-vitro assay for soluble PACs that allows their reliable characterization. Comparison of different PACs revealed that bPAC from Beggiatoa is the best optogenetic tool for cAMP manipulation, due to its high efficiency and small size. However, a residual activity of bPAC in the dark is unwanted and the cytosolic localization prevents subcellular precise cAMP manipulation. I therefore introduced point mutations into bPAC to reduce its dark activity. Interestingly, I found that membrane targeting of bPAC with different linkers can remarkably alter its activity, in addition to its localization. Taken together, a set of PACs with different activity and subcellular localization were engineered for selection based on the intended usage. The membrane-bound PM-bPAC 2.0 with reduced dark activity is well-tolerated by hippocampal neurons and reliably evokes a transient photocurrent, when co-expression with a CNG channel. (iv) Bidirectional manipulation of cell activity with light of different wavelengths is of great importance in dissecting neural networks in the brain. Selection of optimal tool pairs is the first and most important step for dual-color optogenetics. Through N- and C-terminal modifications, an improved ChR variant (i.e. vf-Chrimson 2.0) was engineered and selected as the red light-controlled actuator for excitation. Detailed comparison of three two-component potassium channels, composed of bPAC and the cAMP-activated potassium channel SthK, revealed the superior properties of SthK-bP. Combining vf-Chrimson 2.0 and improved SthK-bP "SthK(TV418)-bP" could reliably induce depolarization by red light and hyperpolarization by blue light. A residual tiny crosstalk between vf-Chrimson 2.0 and SthK(TV418)-bP, when applying blue light, can be minimized to a negligible level by applying light pulses or simply lowering the blue light intensity.}, language = {en} } @phdthesis{Muralidhara2022, author = {Muralidhara, Prathibha}, title = {Perturbations in plant energy homeostasis alter lateral root plasticity via SnRK1-bZIP63-ARF19 signalling}, doi = {10.25972/OPUS-20563}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-205636}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2022}, abstract = {Photosynthetic plants have a remarkable ability to modify their metabolism and development according to ever changing environmental conditions. The root system displays continuous growth of the primary root and formation of lateral roots enabling efficient water and nutrient uptake and anchorage of the plant in soil. With regard to lateral roots, development is post-embryonic, originating from the pericycle of the primary root. Coordinated activity of several molecular signalling pathways controlled by the hormone auxin is important throughout all stages of lateral root development.At first, two adjacent Xylem Pole Pericycle (XPP) cells are activated and the nuclei of these cells migrate towards a common cell wall.This is followed by XPP cells acquiring volume thus swelling up.The XPP cells then undergo anticlinal cell division, followed by a series of periclinal and anticlinal divisions,leading to lateral root primordia.These break through the radial cell layers and emerge out the primary root. Although root system plasticity is well-described in response to environmental cues such as ion nutrition in the soil, little is known on how root development is shaped according to the endogenous energy status of the plant.In this study, we were able to connect limited perturbations in photosynthetic energy supply to lateral root development.We established two experimental systems - treatment with low light and unexpected darkness which led to short-term energy imbalance in the plant.These short perturbations administered, showed an increase in the emerged lateral root density and decrease in root hexose availability and activation of the low energy marker gene ASN1 (ASPARAGINE SYNTHETASE 1).Although not demonstrated, presumably, these disturbances in the plant energy homeo-stasis activates SnRK1 (SNF1 RELATED KINASE 1),an evolutionary conserved kinase mediat-ing metabolic and transcriptional responses towards low energy conditions. In A. thaliana, two catalytic α-subunits of this kinase (SnRK1.α1 and SnRK1.α2) are functionally active and form ternary complexes with the regulatory β- and γ- subunits. Whereas unexpected darkness results in an increase in emerged lateral root density, the snrk1.α1 loss-of-function mutant displayed decrease in emerged lateral root density. As this effect is not that pronounced in the snrk1.α2 loss-of-function mutant, the α1 catalytic subunit is important for the observed lateral root phenotype under short-term energy perturbations. Moreover, root expression patterns of SnRK1.α1:GFP supports a role of this catalytic subunit in lateral root development. Furthermore, the lateral root response during short-term perturbations requires the SnRK1 downstream transcriptional regulator bZIP63 (BASIC LEU-CINE ZIPPER 63), as demonstrated here by a loss-of-function approach. Phenotypic studies showed that in comparison to wild-type, bzip63 mutants displayed decreased lateral root density upon low-light and unexpected darkness conditions. Previous work has demonstrat-ed that SnRK1 directly phosphorylates bZIP63 at three serine residues. Alanine-exchange mutants of the SnRK1 dependent bZIP63 phosphorylation sites behave similarly to bzip63 loss-of-function mutants and do not display increased lateral root density upon short-term unexpected darkness. This data strongly supports an impact of SnRK1-bZIP63 signalling in mediating the observed lateral root density phenotype. Plants expressing a bZIP63:YFP fu-sion protein showed specific localization patterns in primary root and in all developmental stages of the lateral root. bzip63 loss-of-function mutant lines displayed reduced early stage lateral root initiation events under unexpected darkness as demonstrated by Differen-tial Interference Contrast microscopy (DIC) and the use of a GATA23 reporter line. This data supports a role of bZIP63 in early lateral root initiation. Next, by employing Chromatin Immunoprecitation (ChIP) sequencing, we were able to iden-tify global binding targets of bZIP63, including the auxin-regulated transcription factor (TF) ARF19 (AUXIN RESPONSE FACTOR 19), a well-described central regulator of lateral root development. Additional ChIP experiments confirmed direct binding of bZIP63 to an ARF19 promoter region harboring a G-Box cis-element, a well-established bZIP63 binding site. We also observed that short-term energy perturbation upon unexpected darkness induced tran-scription of ARF19, which was impaired in the bzip63 loss-of-function mutant. These results propose that bZIP63 mediates lateral root development under short-term energy perturba-tion via ARF19. In conclusion, this study provides a novel mechanistic link between energy homeostasis and plant development. By employing reverse genetics, confocal imaging and high-throughput sequencing strategies, we were able to propose a SnRK1-bZIP63-ARF19 signalling module in integrating energy signalling into lateral root developmental programs.}, subject = {Arabidopsis thaliana}, language = {en} } @phdthesis{Staiger2022, author = {Staiger, Simona}, title = {Chemical and physical nature of the barrier against active ingredient penetration into leaves: effects of adjuvants on the cuticular diffusion barrier}, doi = {10.25972/OPUS-19937}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-199375}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2022}, abstract = {Agrochemicals like systemic active ingredients (AI) need to penetrate the outermost barrier of the plant, known as the plant cuticle, to reach its right target site. Therefore, adjuvants are added to provide precise and efficient biodelivery by i.a. modifying the cuticular barrier and increasing the AI diffusion. This modification process is depicted as plasticization of the cuticular wax which mainly consists of very long-chain aliphatic (VLCA) and cyclic compounds. Plasticization of cuticular waxes is pictured as an increase of amorphous domains and/or a decrease of crystalline fractions, but comprehensive, experimental proof is lacking to date. Hence, the objective of this thesis was to i) elucidate the permeation barrier of the plant cuticle to AIs in terms of the different wax fractions and ii) holistically investigate the modification of this barrier using selected oil and surface active adjuvants, an aliphatic leaf wax and an artificial model wax. Therefore, the oil adjuvant methyl oleate (MeO) and other oil derivatives like methyl linolenate (MeLin), methyl stearate (MeSt) and oleic acid (OA) were selected. Three monodisperse, non-ionic alcohol ethoxylates with increasing ethylene oxide monomer (EO) number (C10E2, C10E5, C10E8) were chosen as representatives of the group of surface active agents (surfactants). Both adjuvant classes are commonly used as formulation aids for agrochemicals which are known for its penetration enhancing effect. The aliphatic leaf wax of Schefflera elegantissima was selected, as well as a model wax comprising the four most abundant cuticular wax compounds of this species. Permeation, transpiration and penetration studies were conducted using enzymatically isolated cuticles of Prunus laurocerasus and Garcinia xanthochymus. Cuticular permeability to the three organic solutes theobromine, caffeine and azoxystrobin differing in lipophilicity was measured using a steady-state two-chamber system separated by the isolated leaf cuticles of the evergreen species P. laurocerasus and G. xanthochymus. Treating the isolated cuticles with methanol selectively removed the cyclic fraction, and membrane permeability to the organic compounds was not altered. In contrast, fully dewaxing the membranes using chloroform resulted in a statistically significant increase in permeance for all compounds and species, except caffeine with cuticles of G. xanthochymus due to a matrix-specific influence on the semi-hydrophilic compound. Crystalline regions may reduce the accessibility to the lipophilic pathway across the waxes and also block hydrophilic domains in the cuticle. Knowing that the aliphatic wax fraction builds the cuticular diffusion barrier, the influence of the adjuvants on the phase behaviour of an aliphatic cuticular wax as well as the influence on the cuticular penetration of AIs were investigated. Differential scanning calorimetry (DSC) and Fourier-transform infrared spectroscopy (FTIR) were selected to investigate the phase behaviour and thus possible plasticization of pure Schefflera elegantissima leaf wax, its artificial model wax comprising the four most abundant compounds (n-nonacosane, n-hentriacontane, 1-triacontanol and 1-dotriacontanol) and wax adjuvant mixtures. DSC thermograms showed a shift of the melting ranges to lower temperatures and decreased absolute values of the total enthalpy of transition (EOT) for all adjuvant leaf wax blends at 50 \% (w/w) adjuvant proportion. The highest decrease was found for C10E2 followed by MeO > OA and C10E8 > MeLin > MeSt. The aliphatic crystallinity determined by FTIR yielded declined values for the leaf and the artificial wax with 50 \% MeO. All other adjuvant leaf wax blends did not show a significant decrease of crystallinity. As it is assumed that the cuticular wax is formed by crystalline domains which consist of aliphatic hydrocarbon chains and an amorphous fraction comprising aliphatic chain ends and functional groups, the plasticizers are depicted as wax disruptors influencing amorphization and/or crystallization. The adjuvants can increase crystalline domains using the aliphatic tail whereas their more hydrophilic head is embedded in the amorphous wax fraction. DSC and FTIR showed similar trends using the leaf wax and the model wax in combination with the adjuvants. In general, cuticular transpiration increased after adding the pure adjuvants to the surface of isolated cuticles or leaf envelopes. As waxes build the cuticular permeation barrier not only to AIs but also to water, the adjuvant wax interaction might affect the cuticular barrier properties leading to increased transpiration. Direct evidence for increased AI penetration with the adjuvants was given using isolated cuticles of P. laurocerasus in combination with the non-steady-state setup simulation of foliar penetration (SOFP) and caffeine at relative humidity levels (RH) of 30, 50 and 80 \%. The increase in caffeine penetration was much more pronounced using C10E5 and C10E8 than MeO but always independent of RH. Only C10E2 exhibited an increased penetration enhancing effect positively related to RH. The role of the molecular structure of adjuvants in terms of humectant and plasticizer properties are discussed. Hence, the current work shows for the first time that the cuticular permeation barrier is associated with the VLCAs rather than the cyclic fraction and that adjuvants structurally influence this barrier resulting in penetration enhancing effects. Additionally, this work demonstrates that an artificial model wax is feasible to mimic the wax adjuvant interaction in conformity with a leaf wax, making it feasible for in-vitro experiments on a larger scale (e.g. screenings). This provides valuable knowledge about the cuticular barrier modification to enhance AI penetration which is a crucial factor concerning the optimization of AI formulations in agrochemistry.}, subject = {Adjuvans}, language = {en} } @phdthesis{Schaebler2022, author = {Sch{\"a}bler, Stefan}, title = {Charakterisierung des circadianen Drosophila Metaboloms unter Zuhilfenahme massenspektrometrischer Methoden}, doi = {10.25972/OPUS-25190}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-251908}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2022}, abstract = {Die F{\"a}higkeit sich an die Rotation der Erde und den daraus resultierenden Tag- und Nacht-Rhythmus anzupassen, basiert auf einer komplexen Regulation verschiedener physiologischer Prozesse. Auf molekularer Ebene liegt diesen Prozessen eine Orchestration von Uhr-Genen zugrunde - auch als innere Uhr bezeichnet - die einen aktivierenden bzw. reprimierenden Einfluss auf die Expression einer Vielzahl weiterer Gene hat. Ausgehend von dieser Regulation lassen sich auf unterschiedlichsten Ebenen tageszeitabh{\"a}ngige, wiederkehrende Rhythmen beobachten. W{\"a}hrend diese wiederkehrenden Rhythmen auf einigen Ebenen bereits gut erforscht und beschrieben sind, gibt es weitere Ebenen wie den Metabolismus, {\"u}ber die das Wissen bisher noch begrenzt ist. So handelt es sich bei Drosophila beispielsweise um den Organismus, dessen innere Uhr auf molekularer Ebene wahrscheinlich mit am besten charakterisiert ist. Dennoch ist bisher nur wenig {\"u}ber Stoffklassen bekannt, deren Metabolismus durch die innere Uhr kontrolliert wird. Zwar konnte bereits gezeigt werden, dass sich eine gest{\"o}rte innere Uhr auf die Anlage der Energiespeicher auswirkt, inwiefern dies allerdings einen Einfluss auf dem intermedi{\"a}ren Stoffwechsel hat, blieb bisher weitgehend unerforscht. Auch die Frage, welche Metaboliten wiederkehrende, tageszeitabh{\"a}ngige Rhythmen aufweisen, wurde bisher nur f{\"u}r eine begrenzte Anzahl Metaboliten untersucht. Bei der hier durchgef{\"u}hrten Arbeit wurden deshalb zun{\"a}chst die globalen Metabolit-Profile von Fliegen mit einer auf molekularer Ebene gest{\"o}rten inneren Uhr (per01) mit Fliegen, die {\"u}ber eine funktionale Uhr verf{\"u}gen (CantonS), zu zwei Zeitpunkten verglichen. Um die Anzahl der zeitgleich untersuchten Gewebe und somit die Komplexit{\"a}t der Probe zu reduzieren, wurden hierf{\"u}r die K{\"o}pfe von den K{\"o}rpern der Fliegen getrennt und separat analysiert. Beide K{\"o}rperteile wurden sowohl auf kleine hydrophile als auch auf hydrophobe Metaboliten hin mittels UPLC-ESI-qTOF-MS untersucht. Die anschließend durchgef{\"u}hrte, statistische Analyse brachte hervor, dass sich Unterschiede zwischen den beiden Fliegenlinien besonders in den Spiegeln der essentiellen Aminos{\"a}uren, den Kynureninen, den Pterinaten sowie den Spiegeln der Glycero(phospho)lipiden und Fetts{\"a}ureester zeigten. Bei den Lipiden zeigte sich, dass die Auswirkungen weniger ausgepr{\"a}gt f{\"u}r die Anlage der Speicher- und Strukturlipide als f{\"u}r die Intermediate des Lipidabbaus, die Diacylglycerole (DAGs) sowie die Acylcarnitine (ACs), waren. Um zu best{\"a}tigen, dass die inneren Uhr tats{\"a}chlich einen regulatorischen Einfluss auf die ausgemachten Stoffwechselwege hat, wurden anschließend die Spiegel aller Mitglieder darauf hin untersucht, ob diese wiederkehrende, tageszeitabh{\"a}ngige Schwankungen aufweisen. Hierf{\"u}r wurden Proben alle zwei Stunden {\"u}ber drei aufeinanderfolgende Tage genommen und analysiert, bevor mittels JTK_CYCLE eine statistische Analyse der Daten durchgef{\"u}hrt und die Metaboliten herausgefiltert wurden, die ein rhythmisches Verhalten bei einer Periodenl{\"a}nge von 24h zeigten. Hierbei best{\"a}tigte sich, dass besonders die Mitglieder des intermedi{\"a}ren Lipidmetablismus hiervon betroffen waren. So konnten zwar auch f{\"u}r einige Aminos{\"a}uren robuste Rhythmen ausgemacht werden, besonders ausgepr{\"a}gt waren diese jedoch erneut bei den DAGs und den ACs. Die abschließende Untersuchung letzterer unter Freilaufbedingungen (DD) sowie in per01 brachte hervor, dass die ausgemachten Rhythmen unter diesen Bedingungen entweder nicht mehr detektiert werden konnten oder deutlich abgeschw{\"a}cht vorlagen. Lediglich zwei kurzkettige ACs zeigten auch unter DD-Bedingungen statistisch signifikante Rhythmen in ihren Spiegeln. Dies spricht daf{\"u}r, dass neben der Regulation durch die innere Uhr weitere Faktoren, wie beispielsweise das Licht, eine entscheidende Rolle zu spielen scheinen.}, subject = {Drosophila}, language = {de} } @phdthesis{Thomas2021, author = {Thomas, Sarah Katharina}, title = {Design of novel IL-4 antagonists employing site-specific chemical and biosynthetic glycosylation}, doi = {10.25972/OPUS-17517}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-175172}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {The cytokines interleukin 4 (IL-4) and IL-13 are important mediators in the humoral immune response and play a crucial role in the pathogenesis of chronic inflammatory diseases, such as asthma, allergies, and atopic dermatitis. Hence, IL-4 and IL-13 are key targets for treatment of such atopic diseases. For cell signalling IL-4 can use two transmembrane receptor assemblies, the type I receptor consisting of receptors IL-4R and γc, and type II receptor consisting of receptors IL-4R and IL-13R1. The type II receptor is also the functional receptor of IL-13, receptor sharing being the molecular basis for the partially overlapping effects of IL-4 and IL-13. Since both cytokines require the IL-4R receptor for signal transduction, this allows the dual inhibition of both IL-4 and IL-13 by specifically blocking the receptor IL-4R. This study describes the design and synthesis of novel antagonistic variants of human IL-4. Chemical modification was used to target positions localized in IL-4 binding sites for γc and IL-13R1 but outside of the binding epitope for IL-4R. In contrast to existing studies, which used synthetic chemical compounds like polyethylene glycol for modification of IL-4, we employed glycan molecules as a natural alternative. Since glycosylation can improve important pharmacological parameters of protein therapeutics, such as immunogenicity and serum half-life, the introduced glycan molecules thus would not only confer a steric hindrance based inhibitory effect but simultaneously might improve the pharmacokinetic profile of the IL-4 antagonist. For chemical conjugation of glycan molecules, IL-4 variants containing additional cysteine residues were produced employing prokaryotic, as well as eukaryotic expression systems. The thiol-groups of the engineered cysteines thereby allow highly specific modification. Different strategies were developed enabling site-directed coupling of amine- or thiol- functionalized monosaccharides to introduced cysteine residues in IL-4. A linker-based coupling procedure and an approach requiring phenylselenyl bromide activation of IL-4 thiol-groups were hampered by several drawbacks, limiting their feasibility. Surprisingly, a third strategy, which involved refolding of IL-4 cysteine variants in the presence of thiol- glycans, readily allowed synthesis of IL-4 glycoconjugates in form of mixed disulphides in milligram amount. This approach, therefore, has the potential for large-scale synthesis of IL-4 antagonists with highly defined glycosylation. Obtaining a homogenous glycoconjugate with exactly defined glycan pattern would allow using the attached glycan structures for fine-tuning of pharmacokinetic properties of the IL-4 antagonist, such as absorption and metabolic stability. The IL-4 glycoconjugates generated in this work proved to be highly effective antagonists inhibiting IL-4 and/or IL-13 dependent responses in cell-based experiments and in in vitro binding studies. Glycoengineered IL-4 antagonists thus present valuable alternatives to IL-4 inhibitors used for treatment of atopic diseases such as the neutralizing anti-IL-4R antibody Dupilumab.}, subject = {Glykosylierung}, language = {en} } @phdthesis{Kucka2021, author = {Kucka, Kirstin Michaela}, title = {Charakterisierung eines neuen Tumor Nekrose Faktor (TNF) Rezeptor 2 (TNFR2) Agonisten: Der heteromere, membranst{\"a}ndige Ligand Lymphotoxin α\(_2\)β}, doi = {10.25972/OPUS-24982}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-249824}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {Seit mehr als zwei Jahrzehnten ist bekannt, dass nicht nur der Tumor Nekrose Faktor-α (=TNF-α) sondern auch Lymphotoxin-α (=LTα) in Form von Trimeren an TNFR1 und TNFR2 binden kann. Durch diese F{\"a}higkeit an beide Rezeptoren zu binden, haben diese zwei Liganden eine essentielle Rolle in der Entwicklung und dem Verlauf von Autoimmunerkrankungen. Bereits mit Beginn der 1990er Jahren wurde gezeigt, dass LTα nicht nur in Form von Homotrimeren vorliegt, sondern auch mit dem verwandten TNF-Superfamilie Liganden Lymphotoxin β (=LTβ) Heterotrimere bilden kann. Hierbei lagern sich LTα und LTβ in Form von LTα2β und LTαβ2 zusammen. Die initialen Experimente mit diesen Heterotrimeren zeigten bereits Unterschiede von LTα2β und LTαβ2. W{\"a}hrend LTα2β wie LTα an den TNFR1 bindet, kann LTαβ2 weder an TNFR1 noch TNFR2 binden und interagiert mit einem eigenen Rezeptor namens Lymphotoxin β Rezeptor (=LTβR). Da bereits zwei Liganden (TNF und LTα) f{\"u}r TNFR1 und TNFR2 bekannt waren, wurde LTα2β bis heute nicht weiter charakterisiert. LTαβ2 hingegen war lange Zeit der einzige bekannte Ligand f{\"u}r den LTβR, weshalb die LTαβ2-LTβR-Interaktion ausf{\"u}hrlich untersucht wurde. Diese Arbeit fokusiert sich auf die Charakterisierung von LTα2β. Hierf{\"u}r wurde die einzige bekannte Eigenschaft aus den 90er Jahren von LTα2β n{\"a}mlich die Bindung an TNFR1 aufgegriffen und um die Rezeptoren TNFR2 und LTβR erweitert. Diese Arbeit zeigt, dass LTα2β nicht nur an den TNFR1, sondern auch an TNFR2 und schwach an LTβR bindet. Trotz der asymmetrischen Bindestellen kann membrangebundenes LTα2β TNFR1 und TNFR2 nicht nur binden, sondern ist auch in der Lage diese zu aktivieren. Diese Arbeit gibt erste Einblicke in die Komplexizit{\"a}t dieses Heterotrimers indem gezeigt wird, dass LTα2β sowohl in seiner l{\"o}slichen als auch in seiner membrangebundenen Form den TNFR1 aktivieren kann, w{\"a}hrend der TNFR2 nur durch das membranst{\"a}ndige LTα2β aktiviert wird. Aufgrund der aktivierenden Eigenschaften von membranst{\"a}ndigem LTα2β und LTαβ2 auf die murine (=mu) Panc02-Zelllinie wird ein ersten Ausblick auf m{\"o}gliche weitergehende Experimente in mausbasierten Modellen gegeben. Die erzielten Ergebnisse zeigen, dass mit membranst{\"a}ndigem LTα2β ein neuer TNFR2 Agonist gefunden wurde.}, subject = {Ligand}, language = {de} }