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Salt stress is a major abiotic stress, responsible for declining agricultural productivity. Roots are regarded as hubs for salt detoxification, however, leaf salt concentrations may exceed those of roots. How mature leaves manage acute sodium chloride (NaCl) stress is mostly unknown.
To analyze the mechanisms for NaCl redistribution in leaves, salt was infiltrated into intact tobacco leaves. It initiated pronounced osmotically‐driven leaf movements. Leaf downward movement caused by hydro‐passive turgor loss reached a maximum within 2 h.
Salt‐driven cellular water release was accompanied by a transient change in membrane depolarization but not an increase in cytosolic calcium ion (Ca\(^{2+}\)) level. Nonetheless, only half an hour later, the leaves had completely regained turgor. This recovery phase was characterized by an increase in mesophyll cell plasma membrane hydrogen ion (H\(^{+}\)) pumping, a salt uptake‐dependent cytosolic alkalization, and a return of the apoplast osmolality to pre‐stress levels. Although, transcript numbers of abscisic acid‐ and Salt Overly Sensitive pathway elements remained unchanged, salt adaptation depended on the vacuolar H\(^{+}\)/Na\(^{+}\)‐exchanger NHX1.
Altogether, tobacco leaves can detoxify sodium ions (Na\(^{+}\)) rapidly even under massive salt loads, based on pre‐established posttranslational settings and NHX1 cation/H+ antiport activity. Unlike roots, signaling and processing of salt stress in tobacco leaves does not depend on Ca\(^{2+}\) signaling.
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.
Glycoprotein VI (GPVI) is a platelet-specific receptor for collagen and fibrin, regulating important platelet functions such as platelet adhesion and thrombus growth. Although the blockade of GPVI function is widely recognized as a potent anti-thrombotic approach, there are limited studies focused on site-specific targeting of GPVI. Using computational modeling and bioinformatics, we analyzed collagen- and CRP-binding surfaces of GPVI monomers and dimers, and compared the interacting surfaces with other mammalian GPVI isoforms. We could predict a minimal collagen-binding epitope of GPVI dimer and designed an EA-20 antibody that recognizes a linear epitope of this surface. Using platelets and whole blood samples donated from wild-type and humanized GPVI transgenic mice and also humans, our experimental results show that the EA-20 antibody inhibits platelet adhesion and aggregation in response to collagen and CRP, but not to fibrin. The EA-20 antibody also prevents thrombus formation in whole blood, on the collagen-coated surface, in arterial flow conditions. We also show that EA-20 does not influence GPVI clustering or receptor shedding. Therefore, we propose that blockade of this minimal collagen-binding epitope of GPVI with the EA-20 antibody could represent a new anti-thrombotic approach by inhibiting specific interactions between GPVI and the collagen matrix.
Rationale: Social factors are considered important for the initiation and maintenance of drug abuse. Virtual reality (VR) research on cue reactivity and exposure frequently incorporates social stimuli as part of complex drug-intake scenarios. Attempts are rarely made to dissect the impact of the different components and their interactive effects. The present study critically extends this line of research by investigating the modulatory effects of social context on the reactivity evoked by proximal smoking cues.
Methods: Thirty-two smokers and 33 never-smokers were presented in VR with proximal cues and neutral stimuli, embedded in a social context or a neutral context. A virtual hand model was used to translate real hand movements into VR. Each trial started with the presentation of the different stimulus–context combinations. Discrete stimuli were presented on the table in front of the participants, and contextual stimuli were presented at the end of the table. Afterward, participants were instructed to grasp the target stimulus (a cigarette vs. a pencil) in front of them. After successful contact, the stimulus appeared in the virtual hand. Modulation of cue reactivity by social context was assessed by self-report, physiological measures, and overt approach behavior.
Results: The results revealed modulatory effects of social context on the responses to proximal smoking cues in smokers. In contrast to never-smokers, smoking cues evoked craving in smokers, which was attenuated in a social context. Furthermore, social context increased the latency to approach and contact the cigarette in the group of smokers but did not affect behavioral approach responses in never-smokers. Other data provided indications for interactive, but also main effects of cues and contexts. Interestingly, cue-evoked craving was increased after contact with the virtual cigarette.
Conclusion: The present study critically extends previous research by providing evidence for the modulation of cue reactivity by social context. The results are particularly important given the well-established role of drug-associated environmental contexts in the stimulus control of addictive behaviors. Our results emphasize the need to address social context effects on cue reactivity in basic research and treatment and further suggest that changes in the perceived availability of smoking might enhance or inhibit cue-evoked reactivity.
We study the topological properties of the generalized two-dimensional (2D) Su-Schrieffer-Heeger (SSH) models. We show that a pair of Dirac points appear in the Brillouin zone (BZ), consisting a semimetallic phase. Interestingly, the locations of these Dirac points are not pinned to any high-symmetry points of the BZ but tunable by model parameters. Moreover, the merging of two Dirac points undergoes a novel topological phase transition, which leads to either a weak topological insulator or a nodal-line metallic phase. We demonstrate these properties by constructing two specific models, which we referred as type-I and type-II 2D SSH models. The feasible experimental platforms to realize our models are also discussed.
Excitons in atomically thin transition-metal dichalcogenides (TMDs) have been established as an attractive platform to explore polaritonic physics, owing to their enormous binding energies and giant oscillator strength. Basic spectral features of exciton polaritons in TMD microcavities, thus far, were conventionally explained via two-coupled-oscillator models. This ignores, however, the impact of phonons on the polariton energy structure. Here we establish and quantify the threefold coupling between excitons, cavity photons, and phonons. For this purpose, we employ energy-momentum-resolved photoluminescence and spatially resolved coherent two-dimensional spectroscopy to investigate the spectral properties of a high-quality-factor microcavity with an embedded WSe\(_2\) van-der-Waals heterostructure at room temperature. Our approach reveals a rich multi-branch structure which thus far has not been captured in previous experiments. Simulation of the data reveals hybridized exciton-photon-phonon states, providing new physical insight into the exciton polariton system based on layered TMDs.
Bile salts accumulating during cholestatic liver disease are believed to promote liver fibrosis. We have recently shown that chenodeoxycholate (CDC) induces expansion of hepatic stellate cells (HSCs) in vivo, thereby promoting liver fibrosis. Mechanisms underlying bile salt-induced fibrogenesis remain elusive. We aimed to characterize the effects of different bile salts on HSC biology and investigated underlying signaling pathways. Murine HSCs (mHSCs) were stimulated with hydrophilic and hydrophobic bile salts. Proliferation, cell mass, collagen deposition, and activation of signaling pathways were determined. Activation of the human HSC cell line LX 2 was assessed by quantification of α-smooth muscle actin (αSMA) expression. Phosphatidyl-inositol-3-kinase (PI3K)-dependent signaling was inhibited both pharmacologically and by siRNA. CDC, the most abundant bile salt accumulating in human cholestasis, but no other bile salt tested, induced Protein kinase B (PKB) phosphorylation and promoted HSC proliferation and subsequent collagen deposition. Pharmacological inhibition of the upstream target PI3K-inhibited activation of PKB and pro-fibrogenic proliferation of HSCs. The PI3K p110α-specific inhibitor Alpelisib and siRNA-mediated knockdown of p110α ameliorated pro-fibrogenic activation of mHSC and LX 2 cells, respectively. In summary, pro-fibrogenic signaling in mHSCs is selectively induced by CDC. PI3K p110α may be a potential therapeutic target for the inhibition of bile salt-induced fibrogenesis in cholestasis.
Effective lifting of the topological protection of quantum spin Hall edge states by edge coupling
(2022)
The scientific interest in two-dimensional topological insulators (2D TIs) is currently shifting from a more fundamental perspective to the exploration and design of novel functionalities. Key concepts for the use of 2D TIs in spintronics are based on the topological protection and spin-momentum locking of their helical edge states. In this study we present experimental evidence that topological protection can be (partially) lifted by pairwise coupling of 2D TI edges in close proximity. Using direct wave function mapping via scanning tunneling microscopy/spectroscopy (STM/STS) we compare isolated and coupled topological edges in the 2D TI bismuthene. The latter situation is realized by natural lattice line defects and reveals distinct quasi-particle interference (QPI) patterns, identified as electronic Fabry-Pérot resonator modes. In contrast, free edges show no sign of any single-particle backscattering. These results pave the way for novel device concepts based on active control of topological protection through inter-edge hybridization for, e.g., electronic Fabry-Pérot interferometry.
Coal mining, an important human activity, disturbs soil organic carbon (SOC) accumulation and decomposition, eventually affecting terrestrial carbon cycling and the sustainability of human society. However, changes of SOC content and their relation with influential factors in coal mining areas remained unclear. In the study, predictive models of SOC content were developed based on field sampling and Landsat images for different land-use types (grassland, forest, farmland, and bare land) of the largest coal mining area in China (i.e., Shendong). The established models were employed to estimate SOC content across the Shendong mining area during 1990–2020, followed by an investigation into the impacts of climate change and human disturbance on SOC content by a Geo-detector. Results showed that the models produced satisfactory results (R\(^2\) > 0.69, p < 0.05), demonstrating that SOC content over a large coal mining area can be effectively assessed using remote sensing techniques. Results revealed that average SOC content in the study area rose from 5.67 gC·kg\(^{−1}\) in 1990 to 9.23 gC·kg\(^{−1}\) in 2010 and then declined to 5.31 gC·Kg\(^{−1}\) in 2020. This could be attributed to the interaction between the disturbance of soil caused by coal mining and the improvement of eco-environment by land reclamation. Spatially, the SOC content of farmland was the highest, followed by grassland, and that of bare land was the lowest. SOC accumulation was inhibited by coal mining activities, with the effect of high-intensity mining being lower than that of moderate- and low-intensity mining activities. Land use was found to be the strongest individual influencing factor for SOC content changes, while the interaction between vegetation coverage and precipitation exerted the most significant influence on the variability of SOC content. Furthermore, the influence of mining intensity combined with precipitation was 10 times higher than that of mining intensity alone.
Poxviruses are large DNA viruses with a linear double-stranded DNA genome circularized at the extremities. The helicase-primase D5, composed of six identical 90 kDa subunits, is required for DNA replication. D5 consists of a primase fragment flexibly attached to the hexameric C-terminal polypeptide (res. 323–785) with confirmed nucleotide hydrolase and DNA-binding activity but an elusive helicase activity. We determined its structure by single-particle cryo-electron microscopy. It displays an AAA+ helicase core flanked by N- and C-terminal domains. Model building was greatly helped by the predicted structure of D5 using AlphaFold2. The 3.9 Å structure of the N-terminal domain forms a well-defined tight ring while the resolution decreases towards the C-terminus, still allowing the fit of the predicted structure. The N-terminal domain is partially present in papillomavirus E1 and polyomavirus LTA helicases, as well as in a bacteriophage NrS-1 helicase domain, which is also closely related to the AAA+ helicase domain of D5. Using the Pfam domain database, a D5_N domain followed by DUF5906 and Pox_D5 domains could be assigned to the cryo-EM structure, providing the first 3D structures for D5_N and Pox_D5 domains. The same domain organization has been identified in a family of putative helicases from large DNA viruses, bacteriophages, and selfish DNA elements.