@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{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{XavierdeSouza2024, author = {Xavier de Souza, Aline}, title = {Ecophysiological adaptations of the cuticular water permeability within the Solanaceae family}, doi = {10.25972/OPUS-22539}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-225395}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2024}, abstract = {The cuticle, a complex lipidic layer synthesized by epidermal cells, covers and protects primary organs of all land plants. Its main function is to avoid plant desiccation by limiting non-stomatal water loss. The cuticular properties vary widely among plant species. So far, most of the cuticle-related studies have focused on a limited number of species, and studies addressing phylogenetically related plant species are rare. Moreover, comparative studies among organs from the same plant species are still scarce. Thus, this study focus on organ-specificities of the cuticle within and between plant species of the Solanaceae family. Twenty-seven plant species of ten genera, including cultivated and non- cultivated species, were investigated to identify potential cuticular similarities. Structural, chemical and functional traits of fully expanded leaves, inflated fruiting calyces, and ripe fruits were analyzed. The surface morphology was investigated by scanning electron microscopy. Leaves were mainly amphistomatic and covered by an epicuticular wax film. The diversity and distribution of trichomes varied among species. Only the leaves of S. grandiflora were glabrous. Plant species of the Leptostemonum subgenus had numerous prickles and non-glandular stellate trichomes. Fruits were stomata-free, except for S. muricatum, and a wax film covered their surface. Last, lenticel- like structures and remaining scars of broken trichomes were found on the surface of some Solanum fruits. Cuticular water permeability was used as indicators of the cuticular transpiration barrier efficiency. The water permeability differed among plant species, organs and fruit types with values ranging up to one hundred-fold. The minimum leaf conductance ranged from 0.35 × 10-5 m s-1 in S. grandiflora to 31.54 × 10-5 m s-1 in S. muricatum. Cuticular permeability of fruits ranged from 0.64 × 10-5 m s-1 in S. dulcamara (fleshy berry) to 34.98 × 10-5 m s-1 in N. tabacum (capsule). Generally, the cuticular water loss of dry fruits was about to 5-fold higher than that of fleshy fruits. Interestingly, comparisons between cultivated and non-cultivated species showed that wild species have the most efficient cuticular transpiration barrier in leaves and fruits. The average permeability of leaves and fruits of wild plant species was up to three-fold lower in comparison to the cultivated ones. Moreover, ripe fruits of P. ixocarpa and P. peruviana showed two-times lower cuticular transpiration when enclosed by the inflated fruiting calyx. The cuticular chemical composition was examined using gas chromatography. Very-long-chain aliphatic compounds primarily composed the cuticular waxes, being mostly dominated by n- alkanes (up to 80\% of the total wax load). Primary alkanols, alkanoic acids, alkyl esters and branched iso- and anteiso-alkanes were also frequently found. Although in minor amounts, sterols, pentacyclic triterpenoids, phenylmethyl esters, coumaric acid esters, and tocopherols were identified in the cuticular waxes. Cuticular wax coverages highly varied in solanaceous (62- fold variation). The cuticular wax load of fruits ranged from 0.55 μg cm-2 (Nicandra physalodes) to 33.99 μg cm-2 (S. pennellii), whereas the wax amount of leaves varied from 0.90 μg cm-2 (N. physalodes) to 28.42 μg cm-2 (S. burchellii). Finally, the wax load of inflated fruiting calyces ranged from 0.56 μg cm-2 in P. peruviana to 2.00 μg cm-2 in N. physalodes. For the first time, a comparative study on the efficiency of the cuticular transpiration barrier in different plant organs of closely related plant species was conducted. Altogether, the cuticular chemical variability found in solanaceous species highlight species-, and organ-specific wax biosynthesis. These chemical variabilities might relate to the waterproofing properties of the plant cuticle, thereby influencing leaf and fruit performances. Additionally, the high cuticular water permeabilities of cultivated plant species suggest a potential existence of a trade-off between fruit organoleptic properties and the efficiency of the cuticular transpiration barrier. Last, the high cuticular water loss of the solanaceous dry fruits might be a physiological adaptation favouring seed dispersion.}, subject = {Kutikula}, 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} }