@phdthesis{Iosip2024,
  author    = {Iosip, Anda-Larisa},
  title     = {Molecular Mechanosensing Mechanisms of the Carnivorous Plant \(Dionaea\) \(muscipula\)},
  doi       = {10.25972/OPUS-28764},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-287649},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {Plants are able to sense mechanical forces in order to defend themselves against predators, for instance by synthesizing repellent compounds. Very few plants evolved extremely sensitive tactile abilities that allow them to perceive, interpret and respond by rapid movement in the milliseconds range. One such rarity is the charismatic Venus flytrap (Dionaea muscipula) - a carnivorous plant which relies on its spectacular active trapping strategy to catch its prey. The snapping traps are equipped with touch-specialised trigger hairs, that upon bending elicit an action potential (AP). This electrical signal originates within the trigger hairs' mechanosensory cells and further propagates throughout the whole trap, alerting the plant of potential prey. Two APs triggered within thirty seconds will set off the trap and more than five APs will initiate the green stomach formation for prey decomposition and nutrient uptake. Neither the molecular components of the plant's AP nor the Venus flytrap's fast closure mechanism have been fully elucidated yet. Therefore, the general objective of this study is to expound on the molecular basis of touch perception: from AP initiation to trap closure and finally to stomach formation. The typical electrical signal in plants lasts for minutes and its shape is determined by the intensity of the mechanical force applied. In contrast, the Venus flytrap's one-second AP is of all-or-nothing type, similar in shape to the animal AP. In order to gain more insight into the molecular components that give rise to the Venus flytrap's emblematic AP, the transcriptomic landscape of its unique mechanotransducer - the trigger hair - was compared to the rest of the non-specialised tissues and organs. Additionally, the transcriptome of the electrically excitable fully-developed adult trap was compared to non-excitable juvenile traps that are unable to produce sharp APs. Together, the two strategies helped with the identification of electrogenic channels and pumps for each step of the AP as follows: (1) the most specific to the trigger hair was the mechanosensitive channel DmMSL10, making up the best candidate for the initial AP depolarization phase, (2) the K+ outward rectifier DmSKOR could be responsible for repolarisation, (3) further, the proton pump DmAHA4, might kick in during repolarisation and go on with hyperpolarisation and (4) the hyperpolarization- and acid-activated K+ inward rectifier KDM1 might contribute to the re-establishment of electrochemical gradient and the resting potential. Responsible for the AP-associated Ca2+ wave and electrical signal propagation, the glutamate-like receptor DmGLR3.6 was also enriched in the trigger hairs. Together, these findings suggest that the reuse of genes involved in electrical signalling in ordinary plants can give rise to the Venus flytrap's trademark AP. The Venus flytrap has been cultivated ever since its discovery, generating more than one hundred cultivars over the years. Among them, indistinguishable from a normal Venus flytrap at first sight, the 'ERROR' cultivar exhibits a peculiar behaviour: it is unable to snap its traps upon two APs. Nevertheless, it is still able to elicit normal APs. To get a better understanding of the key molecular mechanisms and pathways that are essential for a successful trap closure, the 'ERROR' mutant was compared to the functional wild type. Timelapse photography led to the observation that the 'ERROR' mutants were able to leisurely half close their traps when repeated mechanostimulation was applied (10 minutes after 20 APs, 0.03 Hz). As a result of touch or wounding in non-carnivorous plants, jasmonic acid (JA) is synthesized, alerting the plants of potential predators. Curiously, the JA levels were reduced upon mechanostimulation and completely impaired upon wounding in the 'ERROR' mutant. In search of genes accountable for the 'ERROR' mutant's defects, the transcriptomes of the two phenotypes were compared before and after mechanostimulation (1h after 10 APs, 0.01 Hz). The overall dampened response of the mutant compared to the wild type, was reflected at transcriptomic level as well. Only about 50\% of wild type's upregulated genes after touch stimulation were differentially expressed in 'ERROR' and they manifested only half of the wild type's expression amplitude. Among unresponsive functional categories of genes in 'ERROR' phenotype, there were: cell wall integrity surveilling system, auxin biosynthesis and stress-related transcription factors from the ethylene-responsive AP2/ERF and C2H2-ZF families. Deregulated Ca2+-decoding as well as redox-related elements together with JA-pathway components might also contribute to the malfunctioning of the 'ERROR' mutant. As the mutant does not undergo full stomach formation after mechanical treatment, these missing processes represent key milestones that might mediate growth-defence trade-offs under JA signalling. This confirms the idea that carnivory has evolved by recycling the already available molecular machineries of the ubiquitous plant immune system. To better understand the mutant's defect in the trap snapping mechanism, the ground states (unstimulated traps) of the two phenotypes were compared. In this case, many cell wall-related genes (e.g. expansins) were downregulated in the 'ERROR' mutant. For the first time, these data point to the importance of a special cell wall architecture of the trap, that might confer the mechanical properties needed for a functional buckling system - which amplifies the speed of the trap closure. This study provides candidate channels for each of the AP phases that give rise to and shape the sharp Venus flytrap-specific AP. It further underlines the possible contribution of the cell wall architecture to the metastable ready-to-snap configuration of the trap before stimulation - which might be crucial for the buckling-dependent snapping. And finally, it highlights molecular milestones linked to defence responses that ensure trap morphing into a green stomach after mechanostimulation. Altogether, these processes prove to be interdependent and essential for a successful carnivorous lifestyle.},
  subject      = {Venusfliegenfalle},
  language  = {en}
}
@phdthesis{Kreisz2024,
  author    = {Kreisz, Philipp},
  title     = {Group S1 bZIP transcription factors regulate sink tissue development by controlling carbon and nitrogen resource allocation in \(Arabidopsis\) \(thaliana\)},
  doi       = {10.25972/OPUS-32192},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-321925},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {The evolutionary success of higher plants is largely attributed to their tremendous developmental plasticity, which allows them to cope with adverse conditions. However, because these adaptations require investments of resources, they must be tightly regulated to avoid unfavourable trade-offs. Most of the resources required are macronutrients based on carbon and nitrogen. Limitations in the availability of these nutrients have major effects on gene expression, metabolism, and overall plant morphology. These changes are largely mediated by the highly conserved master kinase SNF1-RELATED PROTEIN KINASE1 (SnRK1), which represses growth and induces catabolic processes. Downstream of SnRK1, a hub of heterodimerising group C and S1 BASIC LEUCINE ZIPPER (bZIP) transcription factors has been identified. These bZIPs act as regulators of nutrient homeostasis and are highly expressed in strong sink tissues, such as flowers or the meristems that initiate lateral growth of both shoots and roots. However, their potential involvement in controlling developmental responses through their impact on resource allocation and usage has been largely neglected so far. Therefore, the objective of this work was to elucidate the impact of particularly S1 bZIPs on gene expression, metabolism, and plant development. Due to the high homology and suspected partial redundancy of S1 bZIPs, higher order loss-of-function mutants were generated using CRISPR-Cas9. The triple mutant bzip2/11/44 showed a variety of robust morphological changes but maintained an overall growth comparable to wildtype plants. In detail however, seedlings exhibited a strong reduction in primary root length. In addition, floral transition was delayed, and siliques and seeds were smaller, indicating a reduced supply of resources to the shoot and root apices. However, lateral root density and axillary shoot branching were increased, suggesting an increased ratio of lateral to apical growth in the mutant. The full group S1 knockout bzip1/2/11/44/53 showed similar phenotypes, albeit far more pronounced and accompanied by growth retardation. Metabolomic approaches revealed that these architectural changes were accompanied by reduced sugar levels in distal sink tissues such as flowers and roots. Sugar levels were also diminished in leaf apoplasts, indicating that long distance transport of sugars by apoplastic phloem loading was impaired in the mutants. In contrast, an increased sugar supply to the proximal axillary buds and elevated starch levels in the leaves were measured. In addition, free amino acid levels were increased in bzip2/11/44 and bzip1/2/11/44/53, especially for the important transport forms asparagine and glutamine. The increased C and N availability in the proximal tissues could be the cause of the increased axillary branching in the mutants. To identify bZIP target genes that might cause the observed shifts in metabolic status, RNAseq experiments were performed. Strikingly, clade III SUGARS WILL EVENTUALLY BE EXPORTED (SWEET) 8 genes were abundant among the differentially expressed genes. As SWEETs are crucial for sugar export to the apoplast and long-distance transport through the phloem, their reduced expression is likely to be the cause of the observed changes in sugar allocation. Similarly, the reduced expression of GLUTAMINE AMIDOTRANSFERASE 1_2.1 (GAT1_2.1), which exhibits glutaminase activity, could be an explanation for the abundance of glutamine in the mutants. Additional experiments (ATAC-seq, DAP� seq, PTA, q-RT-PCR) supported the direct induction of SWEETs and GAT1_2.1 by S1 bZIPs. To confirm the involvement of these target genes in the observed S1 bZIP mutant phenotypes, loss-of-function mutants were obtained, which showed moderately increased axillary branching. At the same time, the induced overexpression of bZIP11 in axillary meristems had the opposite effect. Collectively, a model is proposed for the function of S1 bZIPs in regulating sink tissue development. For efficient long-distance sugar transport, bZIPs may be required to induce the expression of clade III SWEETs. Thus, reduced SWEET expression in the S1 bZIP mutants would lead to a decrease in apoplastic sugar loading and a reduced supply to distal sinks such as shoot or root apices. The reduction in long� distance transport could lead to sugar accumulation in the leaves, which would then increasingly be transported via symplastic routes towards proximal sinks such as axillary branches and lateral roots or sequestered as starch. The reduced GAT1_2.1 levels lead to an abundance of glutamine, a major nitrogen transport form. The combined effect on C and N allocation results in increased nutrient availability in proximal tissues, promoting the formation of lateral plant organs. Alongside emerging evidence highlighting the power of bZIPs to steer nutrient allocation in other species, a novel but evolutionary conserved role for S1 bZIPs as regulators of developmental plasticity is proposed, while the generation of valuable data sets and novel genetic resources will help to gain a deeper understanding of the molecular mechanisms involved},
  subject      = {Molekularbiologie},
  language  = {en}
}
@phdthesis{Kumar2024,
  author    = {Kumar, Manish},
  title     = {Structural and compositional effects on tree-water relation},
  doi       = {10.25972/OPUS-32624},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-326245},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {Forests are essential sources of tangible and intangible benefits, but global climate change associated with recurrent extreme drought episodes severely affects forest productivity due to extensive tree die-back. On that, it appeals to an urgency for large-scale reforestation efforts to mitigate the impact of climate change worldwide; however, there is a lack of understanding of drought-effect on sapling growth and survival mechanisms. It is also challenging to anticipate how long trees can survive and when they succumb to drought. Hence, to ensure success of reforestation programs and sustainable forest productivity, it is essential to identify drought-resistant saplings. For that, profound knowledge of hydraulic characteristics is needed. To achieve this, the study was split into two phases which seek to address (1) how the hydraulic and anatomical traits influence the sapling's growth rate under drought stress. (2) how plant water potential regulation and physiological traits are linked to species' water use strategies and their drought tolerance. The dissertation is assembled of two study campaigns carried out on saplings at the Chair of Botany II, University of W{\"u}rzburg, Germany. The first study involved three ecologically important temperate broadleaved tree species — saplings of 18-month (Acer pseudoplatanus, Betula pendula, and Sorbus aucuparia) — grown from seeds in contrasting conditions (inside a greenhouse and outside), with the latter being subjected to severe natural heat waves. In the second study, two additional temperate species (Fagus sylvatica and Tilia cordata) were added. The drying-out event was conducted using a randomised blocked design by monitoring plant water status in a climate-controlled chamber and a greenhouse. In campaign I, I present the result based on analysed data of 82 plants of temperate deciduous species and address the juvenile growth rate trade-off with xylem safety-efficiency. Our results indicate biomass production varies considerably due to the contrasted growing environment. High hydraulic efficiency is necessary for increased biomass production, while safety-efficiency traits are decoupled and species-specific. Furthermore, productivity was linked considerably to xylem safety without revealing a well-defined pattern among species. Moreover, plasticity in traits differed between stressed and non-stressed plants. For example, safety-related characteristics were more static than efficiency-related traits, which had higher intra-specific variation. Moreover, we recorded anatomical and leaf traits adjustments in response to a stress condition, but consistency among species is lacking. In campaign II, I combined different ways to estimate the degree of isohydry based on water potential regulation and connected the iso-anisohydric spectrum (i.e., hydroscape area, HSA) to hydraulic traits to elucidate actual plant performance during drought. We analysed plant water potential regulation (Ψpd and Ψmd) and stomatal conductance of 28-29 month saplings of five species. I used a linear mixed modelling approach that allowed to control individual variations to describe the water potential regulation and tested different conceptual definitions of isohydricity. The combined methods allowed us to estimate species' relative degree of isohydry. Further, we examined the traits coordination, including hydraulic safety margin, HSM; embolism resistance, P88; turgor loss, Ψtlp; stomata closure, Ps90; capacitance, C; cuticular conductance, gmin, to determine time to hydraulic failure (Thf). Thf is the cumulative effect of time to stomata closure (Tsc) and time after stomatal closure to catastrophic hydraulic failure (Tcrit). Our results show the species' HSA matches their stomatal stringency, which confirms the relationship between stomatal response and leaf water potential decline. Species that close stomata at lower water potential notably had a larger HSA. Isohydric behaviour was mostly associated with leaf hydraulic traits and poorly to xylem safety traits. Species' degree of isohydry was also unrelated to the species' time to death during drying-out experiments. This supports the notion that isohydry behaviours are linked to water use rather than drought survival strategies. Further, consistent with our assumptions, more isohydric species had larger internal water storage and lost their leaf turgor at less negative water potentials. Counter to our expectations, neither embolism resistance nor the associated hydraulic safety margins were related to metrics of isohydry. Instead, our results indicate traits associated with plant drought response to cluster along two largely independent axes of variation (i.e., stomatal stringency and xylem safety). Furthermore, on the temporal progression of plant drought responses, stomatal closure is critical in coordinating various traits to determine species' hydraulic strategies. Desiccation avoidance strategy was linked to Tsc and coordinated traits response of Ps90, Ψtlp, and HSA, whereas desiccation tolerance was related to Tcrit and traits such as lower P88 value, high HSM, and lower gmin. Notably, the shoot capacitance (C) is crucial in Thf and exhibits dichotomous behaviour linked to both Tsc and Tcrit. In conclusion, knowledge of growth rate trade-offs with xylem safety-efficiency combined with traits linked to species' hydraulic strategies along the isohydry could substantially enhance our ability to identify drought-resistant saplings to ensure the success of reforestation programs and predicting sensitivity to drought for achieving sustainable forest ecosystems.},
  subject      = {Wachstumsrate},
  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{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{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}
}
@article{SteinerZacharyBaueretal.2023,
  author    = {Steiner, Thomas and Zachary, Marie and Bauer, Susanne and M{\"u}ller, Martin J. and Krischke, Markus and Radziej, Sandra and Klepsch, Maximilian and Huettel, Bruno and Eisenreich, Wolfgang and Rudel, Thomas and Beier, Dagmar},
  title     = {Central Role of Sibling Small RNAs NgncR_162 and NgncR_163 in Main Metabolic Pathways of Neisseria gonorrhoeae},
  series = {mBio},
  volume    = {14},
  journal   = {mBio},
  doi       = {10.1128/mbio.03093-22},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-313323},
  year      = {2023},
  abstract  = {Small bacterial regulatory RNAs (sRNAs) have been implicated in the regulation of numerous metabolic pathways. In most of these studies, sRNA-dependent regulation of mRNAs or proteins of enzymes in metabolic pathways has been predicted to affect the metabolism of these bacteria. However, only in a very few cases has the role in metabolism been demonstrated. Here, we performed a combined transcriptome and metabolome analysis to define the regulon of the sibling sRNAs NgncR_162 and NgncR_163 (NgncR_162/163) and their impact on the metabolism of Neisseria gonorrhoeae. These sRNAs have been reported to control genes of the citric acid and methylcitric acid cycles by posttranscriptional negative regulation. By transcriptome analysis, we now expand the NgncR_162/163 regulon by several new members and provide evidence that the sibling sRNAs act as both negative and positive regulators of target gene expression. Newly identified NgncR_162/163 targets are mostly involved in transport processes, especially in the uptake of glycine, phenylalanine, and branched-chain amino acids. NgncR_162/163 also play key roles in the control of serine-glycine metabolism and, hence, probably affect biosyntheses of nucleotides, vitamins, and other amino acids via the supply of one-carbon (C\(_1\)) units. Indeed, these roles were confirmed by metabolomics and metabolic flux analysis, which revealed a bipartite metabolic network with glucose degradation for the supply of anabolic pathways and the usage of amino acids via the citric acid cycle for energy metabolism. Thus, by combined deep RNA sequencing (RNA-seq) and metabolomics, we significantly extended the regulon of NgncR_162/163 and demonstrated the role of NgncR_162/163 in the regulation of central metabolic pathways of the gonococcus.},
  language  = {en}
}
@article{DeğirmenciRogeFerreiraVukosavljevicetal.2023,
  author    = {Değirmenci, Laura and Rog{\´e} Ferreira, Fabio Luiz and Vukosavljevic, Adrian and Heindl, Cornelia and Keller, Alexander and Geiger, Dietmar and Scheiner, Ricarda},
  title     = {Sugar perception in honeybees},
  series = {Frontiers in Physiology},
  volume    = {13},
  journal   = {Frontiers in Physiology},
  issn      = {1664-042X},
  doi       = {10.3389/fphys.2022.1089669},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-302284},
  year      = {2023},
  abstract  = {Honeybees (Apis mellifera) need their fine sense of taste to evaluate nectar and pollen sources. Gustatory receptors (Grs) translate taste signals into electrical responses. In vivo experiments have demonstrated collective responses of the whole Gr-set. We here disentangle the contributions of all three honeybee sugar receptors (AmGr1-3), combining CRISPR/Cas9 mediated genetic knock-out, electrophysiology and behaviour. We show an expanded sugar spectrum of the AmGr1 receptor. Mutants lacking AmGr1 have a reduced response to sucrose and glucose but not to fructose. AmGr2 solely acts as co-receptor of AmGr1 but not of AmGr3, as we show by electrophysiology and using bimolecular fluorescence complementation. Our results show for the first time that AmGr2 is indeed a functional receptor on its own. Intriguingly, AmGr2 mutants still display a wildtype-like sugar taste. AmGr3 is a specific fructose receptor and is not modulated by a co-receptor. Eliminating AmGr3 while preserving AmGr1 and AmGr2 abolishes the perception of fructose but not of sucrose. Our comprehensive study on the functions of AmGr1, AmGr2 and AmGr3 in honeybees is the first to combine investigations on sugar perception at the receptor level and simultaneously in vivo. We show that honeybees rely on two gustatory receptors to sense all relevant sugars.},
  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{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}
}