Unlocking the Potential of Bi2S3-Derived Bi Nanoplates: Enhanced Catalytic Activity and Selectivity in Electrochemical and Photoelectrochemical CO2 Reduction to Formate

Various electrocatalysts are extensively examined for their ability to selectively produce desired products by electrochemical CO2 reduction reaction (CO2RR). However, an efficient CO2RR electrocatalyst doesn't ensure an effective co-catalyst on the semiconductor surface for photoelectrochemical CO2RR. Herein, Bi2S3 nanorods are synthesized and electrochemically reduced to Bi nanoplates that adhere to the substrates for application in the electrochemical and photoelectrochemical CO2RR. Compared with commercial-Bi, the Bi2S3-derived Bi (S-Bi) nanoplates on carbon paper exhibit superior electrocatalytic activity and selectivity for formate (HCOO-) in the electrochemical CO2RR, achieving a Faradaic efficiency exceeding 93%, with minimal H2 production over a wide potential range. This highly selective S-Bi catalyst is being employed on the Si photocathode to investigate the behavior of electrocatalysts during photoelectrochemical CO2RR. The strong adhesion of the S-Bi nanoplates to the Si nanowire substrate and their unique catalytic properties afford exceptional activity and selectivity for HCOO- under simulated solar irradiation. The selectivity observed in electrochemical CO2RR using the S-Bi catalyst correlates with that seen in the photoelectrochemical CO2RR system. Combined pulsed potential methods and theoretical analyses reveal stabilization of the OCHO* intermediate on the S-Bi catalyst under specific conditions, which is critical for developing efficient catalysts for CO2-to-HCOO- conversion.

Steering lithium and potassium storage mechanism in covalent organic frameworks by incorporating transition metal single atoms

Organic electrodes mainly consisting of C, O, H, and N are promising candidates for advanced batteries. However, the sluggish ionic and electronic conductivity limit the full play of their high theoretical capacities. Here, we integrate the idea of metal-support interaction in single-atom catalysts with π-d hybridization into the design of organic electrode materials for the applications of lithium (LIBs) and potassium-ion batteries (PIBs). Several types of transition metal single atoms (e.g., Co, Ni, Fe) with π-d hybridization are incorporated into the semiconducting covalent organic framework (COF) composite. Single atoms favorably modify the energy band structure and improve the electronic conductivity of COF. More importantly, the electronic interaction between single atoms and COF adjusts the binding affinity and modifies ion traffic between Li/K ions and the active organic units of COFs as evidenced by extensive in situ and ex situ characterizations and theoretical calculations. The corresponding LIB achieves a high reversible capacity of 1,023.0 mA h g-1 after 100 cycles at 100 mA g-1 and 501.1 mA h g-1 after 500 cycles at 1,000 mA g-1. The corresponding PIB delivers a high reversible capacity of 449.0 mA h g-1 at 100 mA g-1 after 150 cycles and stably cycled over 500 cycles at 1,000 mA g-1. This work provides a promising route to engineering organic electrodes.

Scaling-Up Insights for Zinc-Air Battery Technologies Realizing Reversible Zinc Anodes

Zinc-air battery (ZAB) technology is considered one of the promising candidates to complement the existing lithium-ion batteries for future large-scale high-energy-storage demands. The scientific literature reveals many efforts for the ZAB chemistries, materials design, and limited accounts for cell design principles with apparently superior performances for liquid and solid-state electrolytes. However, along with the difficulty of forming robust solid-electrolyte interphases, the discrepancy in testing methods and assessment metrics severely challenges the realistic evaluation/comparison and commercialization of ZABs. Here, strategies to formulate reversible zinc anodes are proposed and specific cell-level energy metrics (100-500 Wh kg-1 ) and realistic long-cycling operations are realized. Stabilizing anode/electrolyte interfaces results in a cumulative capacity of 25 Ah cm-2 and Coulomb efficiency of >99.9% for 5000 plating/stripping cycles. Using 1-10 Ah scale (≈500 Wh kg-1 at cell level) solid-state zinc-air pouch cells, scale-up insights for Ah-level ZABs that can progress from lab-scale research to practical production are also offered.

Heterointerface promoted trifunctional electrocatalysts for all temperature high-performance rechargeable Zn-air batteries

The rational design of wide-temperature operating Zn-air batteries is crucial for their practical applications. However, the fundamental challenges remain; the limitation of the sluggish oxygen redox kinetics, insufficient active sites, and poor efficiency/cycle lifespan. Here we present heterointerface-promoted sulfur-deficient cobalt-tin-sulfur (CoS_1-δ/SnS_2-δ) trifunctional electrocatalysts by a facile solvothermal solution-phase approach. The CoS_1-δ/SnS_2-δ displays superb trifunctional activities, precisely a record-level oxygen bifunctional activity of 0.57 V (E_1/2 = 0.90 V and E_j=10 = 1.47 V) and a hydrogen evolution overpotential (41 mV), outperforming those of Pt/C and RuO₂. Theoretical calculations reveal the modulation of the electronic structures and d-band centers that endorse fast electron/proton transport for the hetero-interface and avoid the strong adsorption of intermediate species. The alkaline Zn-air batteries with CoS_1-δ/SnS_2-δ manifest record-high power density of 249 mW cm^-2 and long-cycle life for >1000 cycles under harsh operations of 20 mA cm^-2, surpassing those of Pt/C + RuO₂ and previous state-of-the-art catalysts. Furthermore, the solid-state flexible Zn-air battery also displays remarkable performance with an energy density of 1077 Wh kg^-1, >690 cycles for 50 mA cm^-2, and a wide operating temperature from +80 to -40 °C with 85% capacity retention, which provides insights for practical Zn-air batteries.

Supramolecular Polymer Intertwined Free-Standing Bifunctional Membrane Catalysts for All-Temperature Flexible Zn-Air Batteries

Rational construction of flexible free-standing electrocatalysts featuring long-lasting durability, high efficiency, and wide temperature tolerance under harsh practical operations are fundamentally significant for commercial zinc-air batteries. Here, 3D flexible free-standing bifunctional membrane electrocatalysts composed of covalently cross-linked supramolecular polymer networks with nitrogen-deficient carbon nitride nanotubes are fabricated (referred to as PEMAC@NDCN) by a facile self-templated approach. PEMAC@NDCN demonstrates the lowest reversible oxygen bifunctional activity of 0.61 V with exceptional long-lasting durability, which outperforms those of commercial Pt/C and RuO₂. Theoretical calculations and control experiments reveal the boosted electron transfer, electrolyte mass/ion transports, and abundant active surface site preferences. Moreover, the constructed alkaline Zn-air battery with PEMAC@NDCN air-cathode reveals superb power density, capacity, and discharge-charge cycling stability (over 2160 cycles) compared to the reference Pt/C + RuO₂. Solid-state Zn-air batteries enable a high power density of 211 mW cm^-2, energy density of 1056 Wh kg^-1, stable charge-discharge cycling of 2580 cycles for 50 mA cm^-2, and wide temperature tolerance from - 40 to 70 °C with retention of 86% capacity compared to room-temperature counterparts, illustrating prospects over harsh operations.

Silicon Microwire Arrays with Nanoscale Spacing for Radial Junction c-Si Solar Cells with an Efficiency of 20.5

Structural optimization of microwire arrays is important for the successful demonstration of the practical feasibility of radial junction crystalline silicon (c-Si) solar cells. In this study, we investigated an optimized design of tapered microwire (TMW) arrays to maximize the light absorption of c-Si solar cells, while minimizing the surface recombination, for simultaneously improving the open-circuit voltage and short-circuit current density (J_sc). Finite-difference time-domain simulations confirmed that controlling the spacing between the TMWs at the nanometer scale is more effective for increasing the light absorption than increasing the TMW length. The photogenerated current of a c-Si TMW array with a 200 nm spacing was calculated to be 42.90 mA/cm², which is close to the theoretical limit of 43.37 mA/cm² in the 300-1100 nm wavelength range. To experimentally demonstrate the TMW arrays with a nanometer-scale spacing of 200 nm, which cannot be realized by conventional photolithography, we utilized a soft lithography method based on polystyrene beads for patterning a c-Si wafer. The solar cells based on optimized TMW arrays exhibited a J_sc of 42.5 mA/cm² and power conversion efficiency of 20.5%, which exceed those of the previously reported microwire-based radial junction solar cells.

Electrostatically Doped Silicon Nanowire Arrays for Multispectral Photodetectors

Nanowires have promising applications as photodetectors with superior ability to tune absorption with morphology. Despite their high optical absorption, the quantum efficiencies of these nanowire photodetectors remain low due to difficulties in fabricating a shallow junction using traditional doping methods. As an alternative, we report nonconventional radial heterojunction photodiodes obtained by conformal coating of an indium oxide layer on silicon nanowire arrays. The indium oxide layer has a high work function which induces a strong inversion in the silicon nanowire and creates a virtual p-n junction. The resulting nanowire photodetectors show efficient carrier separation and collection, leading to an improvement of quantum efficiency up to 0.2. In addition, by controlling the nanowire radii, the spectral responses of the In₂O₃/Si nanowire photodetectors are tuned over several visible light wavelengths, creating a multispectral detector. Our approach is promising for the development of highly efficient wavelength-selective photodetectors.

Cold Isostatic-Pressured Silver Nanowire Electrodes for Flexible Organic Solar Cells via Room-Temperature Processes

Transparent conducting electrodes (TCEs) are considered to be an essential structural component of flexible organic solar cells (FOSCs). Silver nanowire (AgNW) electrodes are widely used as TCEs owing to their excellent electrical and optical properties. The fabrication of AgNW electrodes has faced challenges in terms of forming large uniform interconnected networks so that high conductivity and reproducibility can be achieved. In this study, a simple method for creating an intimate contact between AgNWs that uses cold isostatic pressing (CIP) is demonstrated. This method increases the conductivity of the AgNW electrodes, which enables the fabrication of high-efficiency inverted FOSCs that have a power conversion efficiency of 8.75% on flexible polyethylene terephthalate with no short circuiting occurring as the CIP process minimizes the surface roughness of the AgNW electrode. This allows to achieve 100% manufacturing yield of FOSCs. Furthermore, these highly efficient FOSCs are proven to only be 2.4% less efficient even for an extreme bending radius of R ≈ 1.5 mm, compared with initial efficiency.

Embedded Metal Electrode for Organic-Inorganic Hybrid Nanowire Solar Cells

We demonstrate here an embedded metal electrode for highly efficient organic-inorganic hybrid nanowire solar cells. The electrode proposed here is an effective alternative to the conventional bus and finger electrode which leads to a localized short circuit at a direct Si/metal contact and has a poor collection efficiency due to a nonoptimized electrode design. In our design, a Ag/SiO₂ electrode is embedded into a Si substrate while being positioned between Si nanowire arrays underneath poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS), facilitating suppressed recombination at the Si/Ag interface and notable improvements in the fabrication reproducibility. With an optimized microgrid electrode, our 1 cm² hybrid solar cells exhibit a power conversion efficiency of up to 16.1% with an open-circuit voltage of 607 mV and a short circuit current density of 34.0 mA/cm². This power conversion efficiency is more than twice as high as that of solar cells using a conventional electrode (8.0%). The microgrid electrode significantly minimizes the optical and electrical losses. This reproducibly yields a superior quantum efficiency of 99% at the main solar spectrum wavelength of 600 nm. In particular, our solar cells exhibit a significant increase in the fill factor of 78.3% compared to that of a conventional electrode (61.4%); this is because of the drastic reduction in the metal/contact resistance of the 1 μm-thick Ag electrode. Hence, the use of our embedded microgrid electrode in the construction of an ideal carrier collection path presents an opportunity in the development of highly efficient organic-inorganic hybrid solar cells.

17.6%-Efficient radial junction solar cells using silicon nano/micro hybrid structures

We developed a unique nano- and microwire hybrid structure by selectively modifying only the tops of microwires using metal-assisted chemical etching. The proposed nano/micro hybrid structure not only minimizes surface recombination but also absorbs 97% of incident light under AM 1.5G illumination, demonstrating outstanding light absorption compared to that of planar (59%) and microwire arrays (85%). The proposed hybrid solar cells with an area of 1 cm(2) exhibit power conversion efficiencies (Eff) of up to 17.6% under AM 1.5G illumination. In particular, the solar cells show a high short-circuit current density (Jsc) of 39.5 mA cm(-2) because of the high light-absorbing characteristics of the nanostructures. This corresponds to an approximately 61.5% and 16.5% increase in efficiency compared to that of a planar silicon solar cell (Eff = 10.9%) and a microwire solar cell (Eff = 15.1%), respectively. Therefore, we expect the proposed hybrid structure to become a foundational technology for the development of highly efficient radial junction solar cells.

18.4%-Efficient Heterojunction Si Solar Cells Using Optimized ITO/Top Electrode

We optimize the thickness of a transparent conducting oxide (TCO) layer, and apply a microscale mesh-pattern metal electrode for high-efficiency a-Si/c-Si heterojunction solar cells. A solar cell equipped with the proposed microgrid metal electrode demonstrates a high short-circuit current density (JSC) of 40.1 mA/cm(2), and achieves a high efficiency of 18.4% with an open-circuit voltage (VOC) of 618 mV and a fill factor (FF) of 74.1% as result of the shortened carrier path length and the decreased electrode area of the microgrid metal electrode. Furthermore, by optimizing the process sequence for electrode formation, we are able to effectively restore the reduction in VOC that occurs during the microgrid metal electrode formation process. This work is expected to become a fundamental study that can effectively improve current loss in a-Si/c-Si heterojunction solar cells through the optimization of transparent and metal electrodes.

Dopant-Free All-Back-Contact Si Nanohole Solar Cells Using MoOx and LiF Films

We demonstrate novel all-back-contact Si nanohole solar cells via the simple direct deposition of molybdenum oxide (MoOx) and lithium fluoride (LiF) thin films as dopant-free and selective carrier contacts (SCCs). This approach is in contrast to conventionally used high-temperature thermal doping processes, which require multistep patterning processes to produce diffusion masks. Both MoOx and LiF thin films are inserted between the Si absorber and Al electrodes interdigitatedly at the rear cell surfaces, facilitating effective carrier collection at the MoOx/Si interface and suppressed recombination at the Si and LiF/Al electrode interface. With optimized MoOx and LiF film thickness as well as the all-back-contact design, our 1 cm(2) Si nanohole solar cells exhibit a power conversion efficiency of up to 15.4%, with an open-circuit voltage of 561 mV and a fill factor of 74.6%. In particular, because of the significant reduction in Auger/surface recombination as well as the excellent Si-nanohole light absorption, our solar cells exhibit an external quantum efficiency of 83.4% for short-wavelength light (∼400 nm), resulting in a dramatic improvement (54.6%) in the short-circuit current density (36.8 mA/cm(2)) compared to that of a planar cell (23.8 mA/cm(2)). Hence, our all-back-contact design using MoOx and LiF films formed by a simple deposition process presents a unique opportunity to develop highly efficient and low-cost nanostructured Si solar cells.

Incorporation of a self-aligned selective emitter to realize highly efficient (12.8%) Si nanowire solar cells

Formation of a selective emitter in crystalline silicon solar cells improves photovoltaic conversion efficiency by decoupling emitter regions for light absorption (moderately doped) and metallization (degenerately doped). However, use of a selective emitter in silicon nanowire (Si NW) solar cells is technologically challenging because of difficulties in forming robust Ohmic contacts that interface directly with the top-ends of nanowires. Here we describe a self-aligned selective emitter successfully integrated into an antireflective Si NW solar cell. By one-step metal-assisted chemical etching, NW arrays formed only at light-absorbing areas between top-metal grids while selectively retaining Ohmic contact regions underneath the metal grids. We observed a remarkable ∼40% enhancement in blue responses of internal quantum efficiency, corresponding to a conversion efficiency of 12.8% in comparison to the 8.05% of a conventional NW solar cell.

Lossless hybridization between photovoltaic and thermoelectric devices

The optimal hybridization of photovoltaic (PV) and thermoelectric (TE) devices has long been considered ideal for the efficient harnessing solar energy. Our hybrid approach uses full spectrum solar energy via lossless coupling between PV and TE devices while collecting waste energy from thermalization and transmission losses from PV devices. Achieving lossless coupling makes the power output from the hybrid device equal to the sum of the maximum power outputs produced separately from individual PV and TE devices. TE devices need to have low internal resistances enough to convey photo-generated currents without sacrificing the PV fill factor. Concomitantly, a large number of p-n legs are preferred to drive a high Seebeck voltage in TE. Our simple method of attaching a TE device to a PV device has greatly improved the conversion efficiency and power output of the PV device (~30% at a 15°C temperature gradient across a TE device).

Highly electrocatalytic Cu₂ZnSn(S₁-xSex)₄ counter electrodes for quantum-dot-sensitized solar cells

Traditional Pt counter electrode in quantum-dot-sensitized solar cells suffers from a low electrocatalytic activity and instability due to irreversible surface adsorption of sulfur species incurred while regenerating polysulfide (S(n)(2-)/S(2-)) electrolytes. To overcome such constraints, chemically synthesized Cu(2)ZnSn(S(1-x)Se(x))(4) nanocrystals were evaluated as an alternative to Pt. The resulting chalcogenides exhibited remarkable electrocatalytic activities for reduction of polysulfide (S(n)(2-)) to sulfide (S(2-)), which were dictated by the ratios of S/Se. In this study, a quantum dot sensitized solar cell constructed with Cu(2)ZnSn(S(0.5)Se(0.5))(4) as a counter electrode showed the highest energy conversion efficiency of 3.01%, which was even higher than that using Pt (1.24%). The compositional variations in between Cu(2)ZnSnS(4) (x = 0) and Cu(2)ZnSnSe(4) (x = 1) revealed that the solar cell performances were closely related to a difference in electrocatalytic activities for polysulfide reduction governed by the S/Se ratios.

The tradeoff between plasmonic enhancement and optical loss in silicon nanowire solar cells integrated in a metal back reflector

We perform a systematic numerical study to characterize the tradeoff between the plasmonic enhancement and optical loss in periodically aligned, silicon nanowire (SiNW) arrays integrated with a silver back reflector (Ag BR). Optimizing the embedded depth of the wire bottoms into a silver reflector achieved a highly efficient SiNW solar cell. Compared to the SiNW solar cell employing a flat back reflector, the embedded depth of ~20 nm resulted in the relative increase of ~5% in ultimate solar cell efficiency.

A stamped PEDOT:PSS-silicon nanowire hybrid solar cell

A novel stamped hybrid solar cell was proposed using the stamping transfer technique by stamping an active PEDOT:PSS thin layer onto the top of silicon nanowires (SiNWs). Compared to a bulk-type counterpart that fully embeds SiNWs inside PEDOT:PSS, an increase in the photovoltaic efficiency was observed by a factor of ∼4.6, along with improvements in both electrical and optical responses for the stamped hybrid cell. Such improvements for hybrid cells was due to the formation of well-connected and linearly aligned active PEDOT:PSS channels at the top ends of the nanowires after the stamping process. These stamped channels facilitated not only to improve the charge transport, light absorption, but also to decrease the free carriers as well as exciton recombination losses for stamped hybrid solar cells.

Effective method to extract optical bandgaps in Si nanowire arrays

A simple method to extract the optical bandgap of Si nanowire (SiNW) arrays that utilizes the reflection spectra of freestanding SiNW arrays is presented in this Letter. At a fixed nanowire diameter, three different wire lengths reproducibly formed a cross point in their reflectance curve plots. The cross point wavelength corresponded to the optical bandgap, as verified by the classical Tauc's model. The optical bandgap of the SiNW arrays (112 nm in average diameter) was measured to be ~1.19 eV, which is larger than the ~1.08 eV bandgap of bulk Si. Further decreasing the wire diameter to 68 nm caused an increase of the bandgap to ~1.24 eV, which is closer to the optimal bandgap (~1.40 eV) required to achieve the highest conversion efficiency in single-junction photovoltaic devices. Our method suggests that the multijunction tandem structure can be realized via control of the diameter of SiNW arrays.

Epitaxial insertion of gold silicide nanodisks during the growth of silicon nanowires

Nanodisk-shaped, single-crystal gold silicide heterojunctions were inserted into silicon nanowires during vapor-liquid-solid growth using Au as a catalyst within a specific range of chlorine-to-hydrogen atomic ratio. The mechanism of nanodisk formation has been investigated by changing the source gas ratio of SiCl4 to H2. We report that an over-supply of silicon into the Au-Si liquid alloy leads to highly supersaturated solution and enhances the precipitation of Au in the silicon nanowires due to the formation of unstable phases within the liquid alloy. It is shown that the gold precipitates embedded in the silicon nanowires consisted of a metastable gold silicide. Interestingly, faceting of gold silicide was observed at the Au/Si interfaces, and silicon nanowires were epitaxially grown on the top of the nanodisk by vapor-liquid-solid growth. High resolution transmission electron microscopy confirmed that gold silicide nanodisks are epitaxially connected to the silicon nanowires in the direction of growth direction. These gold silicide nanodisks would be useful as nanosized electrical junctions for future applications in nanowire interconnections.

Optical properties of Si microwires combined with nanoneedles for flexible thin film photovoltaics

A combined wire structure, made up of longer periodic Si microwires and short nanoneedles, was prepared to enhance light absorption using one-step plasma etching via lithographical patterning. The combined wire array exhibited light absorption of up to ~97.6% from 300 to 1100 nm without an anti-reflection coating. These combined wire arrays on a Si substrate were embedded into a transparent polymer. A large-scale wire-embedded soft film was then obtained by peeling the polymer-embedded wire portion from the substrate. Optically attractive features were present in these soft films, making them suitable for use in flexible silicon solar cell applications.

A waferscale Si wire solar cell using radial and bulk p-n junctions

Silicon nanowires (NWs) and microwires (MWs) are cost-effectively integrated on a 4-inch wafer using metal-assisted electroless etching for solar cell applications. MWs are periodically positioned using low-level optical patterning in between a dense array of NWs. A spin-on-doping technique is found to be effective for the formation of heavily doped, thin n-type shells of MWs in which the radial doping profile is easily delineated by low voltage scanning electron microscopy. Controlled tapering of the NWs results in additional optical enhancement via optimization of the tradeoff between increased light trapping (by a graded-refractive-index) and increased reflectance (by decreasing areal density of NWs). Compared to single NW (or MW) arrayed cells, the co-integrated solar cells demonstrate improved photovoltaic characteristics, i.e. a short circuit current of 20.59 mA cm(-2) and a cell conversion efficiency of ∼ 7.19% at AM 1.5G illumination.

A strong antireflective solar cell prepared by tapering silicon nanowires

Vertically aligned silicon nanowires (SiNWs) were cost-effectively formed on a four-inch silicon wafer using a simple room temperature approach, i.e., metal-assisted electroless etching. Tapering the NWs by post-KOH dipping achieved separation of each NW from the bunched NW, resulting in a strong enhancement of broadband optical absorption. As electroless etching time increases, the optical crossover feature was observed in the tradeoff between enhanced light trapping (by graded-refractive index during initial tapering) and deteriorated reflectance (by decreasing the areal density of NWs during later tapering). Compared to the bunched SiNWs, tapered NW solar cells demonstrated superior photovoltaic characteristics, such as a short circuit current of 17.67 mA/cm² and a cell conversion efficiency of ~6.56% under 1.5 AM illumination.

Adaptive concentrations of hydrogen peroxide suppress cell death by blocking the activation of SAPK/JNK pathway

Low levels of H2O2 can induce cellular resistance to subsequent higher levels of H2O2. By using human U937 leukemia cells, it was previously shown that such an adaptive response can be induced without increasing the cellular capacity to degrade H2O2, thus conferring on the cells a cross-resistance to other stimuli such as serum withdrawal and C2-ceramide. In this study, it was found that stress-activated protein kinase/c-Jun N-terminal kinase (SAPK/JNK) acts as a common mediator of the cell death induced by high H2O2 concentrations, serum withdrawal and C2-ceramide. Although SAPK/JNK activation by H2O2 was mediated by two upstream mitogen-activated protein kinase (MAPK) kinases MKK4 and MKK7, only MKK7 played such a role in serum withdrawal and C2-ceramide. Interestingly, all these lethal stimuli failed to activate SAPK/JNK and its upstream kinases in the cells that were pretreated with low adaptive concentrations of H2O2. By contrast, the phosphorylation levels of extracellular signal-regulated kinase and p38 MAPK were not significantly influenced by this H2O2 pretreatment. Inducing the SAPK/JNK-suppressing effect of H2O2 required a time lag, which correlated with the time lag required for the induction of the adaptive response. Overall, the results suggest that H2O2 adaptation confers on cells a resistance to multiple stimuli by specifically blocking their ability to activate the SAPK/JNK pathways.

Constitutive hyperexpression of p21(WAF1) in human U266 myeloma cells blocks the lethal signaling induced by oxidative stress but not by Fas

p21(WAF1/CIP1) is expressed in a majority of myeloma cells. To investigate the role of p21 in myeloma cell death, comparative studies using two clones of myeloma cells, Fas-sensitive RPMI8226, and Fas-resistant U266 were performed. These latter cells were also resistant to H(2)O(2) up to 100 microM, whereas the former cells were not. SAPK/JNK was found to be a common mediator of RPMI8226 cell death induced by both H(2)O(2) and Fas. Interestingly, the concentrations of H(2)O(2) which activated SAPK/JNK in RPMI8226 cells failed to do so in U266 cells. In contrast, Fas ligation activated SAPK/JNK in both cells almost equally. U266 cells expressed p21 to levels much higher than in RPMI8226 cells. When the p21 levels were reduced using its antisense, H(2)O(2) killed U266 cells by activating SAPK/JNK. However, the reduction in p21 levels neither rendered the U266 cells susceptible to Fas-mediated cell death, nor significantly influenced Fas-induced SAPK/JNK activation. Overall, our data suggest that the p21 hyperexpression in U266 cells blocks the lethal signaling that is induced by H(2)O(2), but not by Fas. The mechanism whereby U266 cells resist Fas-mediated cell death is discussed.

NF-kappa B mediates the adaptation of human U937 cells to hydrogen peroxide

Low doses of oxidative stress can induce cellular resistance to subsequent higher doses of the same stress. By using human U937 leukemia cells, we previously demonstrated that H(2)O(2) can induce such an adaptive response without elevating the cellular capacity to degrade H(2)O(2), and were able to confer the cells a cross-resistance to an H(2)O(2)-independent lethal stimulus, C(2)-ceramide. In this study, it was found that the adaptation is accompanied by the translocation of cytoplasmic NF-kappa B to the nuclei. This event was promoted or abolished when either IKK alpha or a dominant negative mutant of I kappa B, respectively, was overexpressed. The overexpression of IKK alpha also resulted in the suppression of H(2)O(2)-induced cell death and DNA fragmentation, whereas these events were accelerated by the expression of the I kappa B mutant. The protective effect of IKK alpha was accompanied neither by an elevation of protein levels of various antioxidant enzymes such as catalase, superoxide dismutase, and glutathione peroxidase, nor by an increase in the cellular capacity to consume H(2)O(2). Moreover, the overexpression of IKK alpha resulted in an enhancement of H(2)O(2)-induced resistance to C(2)-ceramide. The overall data suggest that NF-kappa B mediates the H(2)O(2) adaptation induced in a manner independent of H(2)O(2)-degrading activity.

FLIP is constitutively hyperexpressed in Fas-resistant U266 myeloma cells, but is not induced by IL-6 in Fas-sensitive RPM18226 cells

Despite the expression of Fas, some clones of myeloma cells are resistant to Fas-mediated apoptosis. To define a cellular factor involved in the resistance, we performed a comparative study using two clones of myeloma cells, RPM18226 and U266. These cells were reported to express cell surface Fas at similar levels, but only RPM18226 cells lost their viability upon anti-Fas treatment. The resistance of U266 cells to anti-Fas did not appear to reflect dysregulation of Bcl-2, Bcl-X(L), and Bax, because these proteins were expressed in both RPM18226 and U266 cells to similar levels. Moreover, levels of those proteins were not significantly altered by treating RPM18226 cells with IL-6, a cytokine which suppresses the Fas-mediated death of RPM18226 cells. Interestingly, mRNA levels of FLIP(L), an endogenous inhibitor of Fas signaling, were constitutively elevated in U266 cells. Consistent with this observation, U266 cells expressed both FLIPL protein and its truncated 43 kDa product which is seen in FLIP(L)-overexpressing cells. The truncated form of FLIP(L) protein was not detected in RPM18226. Moreover, the levels of truncated FLIP(L) in U266 cells were considerably higher than those of pro-FLIP(L) in RPM18226. The overall data indicate that FLIPL is constitutively hyperexpressed in U266 cells. However, IL-6 failed to enhance the protein levels of FLIP molecules in either of the tested cells. It appears, therefore, that FLIP(L) plays a role in the intrinsic resistance of U266 cells to the apoptotic action of Fas, but is not involved in the protective action of IL-6.

Vitamin D3 up-regulated protein 1 mediates oxidative stress via suppressing the thioredoxin function

As a result of identifying the regulatory proteins of thioredoxin (TRX), a murine homologue for human vitamin D3 up-regulated protein 1 (VDUP1) was identified from a yeast two-hybrid screen. Cotransfection into 293 cells and precipitation assays confirmed that mouse VDUP1 (mVDUP1) bound to TRX, but it failed to bind to a Cys32 and Cys35 mutant TRX, suggesting the redox-active site is critical for binding. mVDUP1 was ubiquitously expressed in various tissues and located in the cytoplasm. Biochemical analysis showed that mVDUP1 inhibited the insulin-reducing activity of TRX. When cells were treated with various stress stimuli such as H2O2 and heat shock, mVDUP1 was significantly induced. TRX is known to interact with other proteins such as proliferation-associated gene and apoptosis signal-regulating kinase 1. Coexpression of mVDUP1 interfered with the interaction between TRX and proliferation-associated gene or TRX and ASK-1, suggesting its roles in cell proliferation and oxidative stress. To investigate the roles of mVDUP1 in oxidative stress, mVDUP1 was overexpressed in NIH 3T3 cells. When cells were exposed to stress, cell proliferation was declined with elevated apoptotic cell death compared with control cells. In addition, c-Jun N-terminal kinase activation and IL-6 expression were elevated. Taken together, these results demonstrate that mVDUP1 functions as an oxidative stress mediator by inhibiting TRX activity.

Caspase-dependent and -independent events in apoptosis induced by hydrogen peroxide

To define the role of caspase-3 in H2O2-induced apoptosis, we introduced caspase-3 cDNA into MCF-7 breast carcinoma cells that otherwise lack caspase-3 expression. H2O2 treatment induced DNA fragmentation and nuclear condensation in the caspase-3-expressing cells, but not in the caspase-3-deficient cells. This indicated that caspase-3 is essential for nuclear events. However, H2O2 induced an externalization of membrane phosphatidylserine (PS) and cell death regardless of caspase-3 expression. These events were not suppressed by Ac-DEVD-CHO and Z-VAD-fmk, which inhibit DEVD-specific caspases and a broad spectrum of caspases, respectively. In Jurkat T cells, these inhibitors abolished H2O2-induced PS relocalization, but not cell death. Therefore, caspases appear to be dispensable for lethality by H2O2, but required for PS redistribution in a cell-type-specific manner.

Hydrogen peroxide suppresses U937 cell death by two different mechanisms depending on its concentration

To investigate the mechanisms of H2O2 adaptation in mammalian cells, we exposed human U937 leukemia cells to 0.05 mM H2O2. This treatment significantly suppressed cell death and DNA fragmentation induced by a subsequent challenge with 1 mM H2O2. A more dramatic protection was observed when cells were pretreated with 0.25 mM H2O2. Pretreatment with either 0.05 or 0.25 mM H2O2 also imparted cells with a survival advantage against serum withdrawal and C2-ceramide treatment. H2O2 was found to be a mediator of cell death induced by serum withdrawal, but not by the addition of C2-ceramide. Interestingly, 0.25 mM H2O2 greatly induced glutathione peroxidase, a H2O2-consuming enzyme, whereas 0.05 mM H2O2 did not. Consistent with observation, pretreatment with 0.25 mM H2O2 resulted in a great reduction of cellular oxidant levels as determined by 2'7'-dichlorofluorescein fluorescence, and it also prevented elevation of oxidant levels upon subsequent challenge with 1 mM H2O2 or with serum withdrawal. These effects were not observed in cells pretreated with 0.05 mM H2O2. The sum of the data indicated that H2O2 suppresses cell death by two different mechanisms depending on its concentration: Relatively high concentrations enhance cellular antioxidant capacity, and lower concentrations block the lethal action of H2O2.

Fas mediates apoptosis in human monocytes by a reactive oxygen intermediate dependent pathway

Monocyte apoptosis has emerged as a central regulatory event in hemopoiesis and inflammation. Inflammatory cytokines can either promote or prevent monocyte apoptosis. To study the possible role of Fas Ag, a member of the TNF/nerve growth factor receptor family, in monocyte apoptosis, human peripheral blood monocytes activated by IL-1 beta or TNF-alpha were exposed to anti-Fas mAb. Engagement of the Fas Ag resulted in apoptosis of monocytes, as monitored by propidium iodide uptake, decrease in cell size, DNA fragmentation, and characteristic ultrastructural changes. The apoptotic action of Fas was abolished completely by antioxidants such as N-acetylcysteine and glutathione, suggesting a role for reactive oxygen intermediates (ROI) in the death process. Consistent with this observation, Fas stimulation enhanced the fluorescence associated with oxidation of 2',7'-dichlorofluorescein, indicating increased levels of intracellular ROI. Moreover, the exogenous addition of hydrogen peroxide or menadione, an intracellular generator of superoxide anion, was sufficient for the induction of monocyte apoptosis. These data indicate that ROI are key mediators of Fas-induced apoptosis. In contrast to IL-1 beta and TNF-alpha, LPS-treated monocytes were resistant to the apoptotic action of Fas. Under these conditions, LPS did not down-regulate Fas, but inhibited the Fas-dependent elevation of ROI. Therefore, monocytes appear to have a protective mechanism that can interfere directly with the Fas-induced pathway of cell suicide, thereby controlling their destiny.

Novel mechanisms of Escherichia coli succinyl-coenzyme A synthetase regulation

Low concentrations of ADP are shown to increase the rate of phosphoenzyme formation of E. coli succinyl-coenzyme A (CoA) synthetase (SCS) without altering the fraction of phosphorylated enzyme. This is true when either ATP or succinyl-CoA and Pi are used to phosphorylate the enzyme. The stimulatory effect of ADP is not altered by sample dilution, is retained upon partial purification of the enzyme, and reflects the binding of ADP to a site other than the catalytic site. GDP also alters the phosphorylation of the E. coli SCS but does so primarily by enhancing the level of the phosphoenzyme and only when ATP is used as the phosphate donor. GDP appears to function by neutralizing the action of a specific inhibitory protein. This inhibitor of SCS allows for interconversion of succinate and succinyl-CoA in a manner dissociated from changes in ATP-ADP metabolism. These previously unidentified and varied mechanisms by which SCS is regulated focus attention on this enzyme as an important control point in determining the cell's potential to meet its metabolic demands.

Fas mediates apoptosis in human monocytes by a reactive oxygen intermediate dependent pathway

Monocyte apoptosis has emerged as a central regulatory event in hemopoiesis and inflammation. Inflammatory cytokines can either promote or prevent monocyte apoptosis. To study the possible role of Fas Ag, a member of the TNF/nerve growth factor receptor family, in monocyte apoptosis, human peripheral blood monocytes activated by IL-1 beta or TNF-alpha were exposed to anti-Fas mAb. Engagement of the Fas Ag resulted in apoptosis of monocytes, as monitored by propidium iodide uptake, decrease in cell size, DNA fragmentation, and characteristic ultrastructural changes. The apoptotic action of Fas was abolished completely by antioxidants such as N-acetylcysteine and glutathione, suggesting a role for reactive oxygen intermediates (ROI) in the death process. Consistent with this observation, Fas stimulation enhanced the fluorescence associated with oxidation of 2',7'-dichlorofluorescein, indicating increased levels of intracellular ROI. Moreover, the exogenous addition of hydrogen peroxide or menadione, an intracellular generator of superoxide anion, was sufficient for the induction of monocyte apoptosis. These data indicate that ROI are key mediators of Fas-induced apoptosis. In contrast to IL-1 beta and TNF-alpha, LPS-treated monocytes were resistant to the apoptotic action of Fas. Under these conditions, LPS did not down-regulate Fas, but inhibited the Fas-dependent elevation of ROI. Therefore, monocytes appear to have a protective mechanism that can interfere directly with the Fas-induced pathway of cell suicide, thereby controlling their destiny.

Regulatory role of GDP in the phosphoenzyme formation of guanine nucleotide: specific forms of succinyl coenzyme A synthetase

We have previously shown that micromolar concentrations of GDP stimulate the GTP-mediated phosphorylation of p36, the alpha subunit of succinyl-CoA synthetase (SCS), in lysates prepared from Dictyostelium discoideum. In this study, we report that this phenomenon represents an enhanced catalytic capacity of SCS to form the phosphoenzyme intermediate. Low concentrations of GDP stimulate phosphoenzyme formation by either GTP, or succinyl-CoA and P(i). Under these conditions GDP enhances the apparent rate of phosphoenzyme formation but does not significantly alter the fraction of phosphorylated enzyme. This effect is retained during purification of the protein and is also observed with purified pig heart SCS, indicating that GDP directly alters the enzyme to enhance its rate of phosphorylation. Under these conditions, GDP does not function at the catalytic site, implying an allosteric regulation of SCS.

Evidence for allosteric regulation of succinyl-CoA synthetase

We have previously reported that distinctly different concentrations of GDP stimulate the phosphorylation and dephosphorylation of p36, the alpha-subunit of succinyl-CoA synthetase (SCS) in Dictyostelium discoideum. In this present study, we have investigated the mechanism underlying these dual effects of GDP. Dephosphorylation of p36 is induced by relatively high levels of GDP and is coincident with the formation of GTP. This indicates that, at high concentrations, GDP serves as a substrate of SCS. However, 100-fold lower concentrations of GDP, which do not bind to the catalytic site to induce SCS dephosphorylation, stimulate p36 phosphorylation. This stimulation is not diminished by dilution of the sample, and is retained during purification of the protein. Gel-filtration analyses indicate that SCS in our system behaves as a non-interacting alpha beta dimer, the hydrodynamic behaviour of which is not altered by the presence of added GDP. The data indicate that altered protein-protein interactions do not account for the stimulation of p36 phosphorylation by low GDP concentrations. We propose that GDP functions as an allosteric regulator of SCS, and experiments using guanosine 5'-[beta-thio]diphosphate (GDP[S]) are shown to distinguish further the allosteric and catalytic binding sites.

P36, a Dictyostelium discoideum protein whose phosphorylation is stimulated by GDP, is homologous to the alpha-subunit of succinyl-CoA synthetase

Previously, we reported the phosphorylation of a 36 kDa protein, p36, in crude membranes from the amoeba Dictyostelium discoideum (Anschutz, A.L., Howlett, A. and Klein, C. (1989) Proc. Natl. Acad. Sci. USA 86, 3665-3668). Here, we report the purification and identification of p36. The protein was purified approximately 35-40-fold with a yield of 8-10%. This material was then separated on 10% SDS-polyacrylamide gels and the band corresponding to p36 was isolated. Partial peptide sequencing of this band revealed p36 to be homologous to the alpha-subunit of succinyl-CoA synthetase. This identification of the protein was supported by the results of phosphorylation studies which examined the effects of substrates of succinyl-CoA synthetase on p36 phosphorylation. In crude sample preparations, p36 could be phosphorylated by both ATP or GTP and in either case, its phosphorylation was stimulated by low concentrations of GDP. Partially purified p36 retained its ability to be phosphorylated with GTP while exhibiting little or no phosphorylation with ATP. GDP still enhanced the rate of p36 phosphorylation with GTP. Therefore, the stimulation of p36 phosphorylation by GDP is not due to substrate conversion and is best explained by a regulatory mechanism.

Dual role of GDP in the regulation of the levels of p36 phosphorylation in Dictyostelium discoideum

We examined the dephosphorylation of p36, a protein of D. discoideum that has previously been shown to be phosphorylated in a GDP-dependent manner (Anschutz et al., 1989). Specific dephosphorylation of p36 was found to occur in cell preparations but the activity responsible was strongly dependent upon the concentration of proteins in those extracts. When preparations were diluted, this activity was no longer detectable and the radiolabeled phosphate incorporated into p36 was stable. In contrast, p36 phosphorylation was seemingly unaffected by this treatment. Under the conditions where endogenous dephosphorylating activity was not detectable, the addition of GDP to the reaction resulted in substantial dephosphorylation of p36. The stimulation of this dephosphorylation process occurred at concentrations of GDP that were distinct from those that led to an increased p36 phosphorylation due to the previously reported stimulation of p36 protein kinase activity. Characterization of the dephosphorylation of p36 indicates that the same enzyme is responsible for the endogenous and GDP-stimulated activities. Additionally, these activities are identical when assayed with p36 that had been phosphorylated with ATP or GTP. In contrast to p36 kinase activity, the dephosphorylation of p36 did not display any developmental changes with respect to its regulatory features.

Regulation of protein phosphorylation in Dictyostelium discoideum

We have examined the phosphorylation of the cyclic adenosine 3':5' monophosphate (cAMP) cell surface chemotactic receptor and a 36 kDa membrane-associated protein (p36) in Dictyostelium discoideum. The activity of CAR-kinase, the enzyme responsible for the phosphorylation of the cAMP receptor, was studied in plasma membrane preparations. It was found that, as in intact cells, the receptor was rapidly phosphorylated in membranes incubated with [gamma 32P] adenosine triphosphate (ATP) but only in the presence of cAMP. This phosphorylation was not observed in membranes prepared from cells which did not display significant cAMP binding activity. cAMP could induce receptor phosphorylation at low concentrations, while cyclic guanosine 3':5' monophosphate (cGMP) could elicit receptor phosphorylation only at high concentrations. Neither ConA, Ca2+, or guanine nucleotides had an effect on CAR-kinase. It was also observed that 2-deoxy cAMP but not dibutyryl cAMP induced receptor phosphorylation. The data suggest that the ligand occupied form of the cAMP receptor is required for CAR-kinase activity. Although the receptor is rapidly dephosphorylated in vivo, we were unable to observe its dephosphorylation in vitro. In contrast, p36 was rapidly dephosphorylated. Also, unlike the cAMP receptor, the phosphorylation of p36 was found to be regulated by the addition of guanine nucleotides. Guanosine diphosphate (GDP) enhanced the phosphorylation while guanosine triphosphate (GTP) decreased the radiolabeling of p36 indicating that GTP can compete with ATP for the nucleotide triphosphate binding site of p36 kinase. Thus was verified using radiolabeled GTP as the phosphate donor. Competition experiments with GTP gamma S, ATP, GTP, CTP, and uridine triphosphate (UTP) indicated that the phosphate donor site of p36 kinase is relatively non-specific.(ABSTRACT TRUNCATED AT 250 WORDS)

Activated macrophages use different cytolytic mechanisms to lyse a virally infected or a tumor target

Murine bone-marrow-culture-derived-macrophages can be differentially activated to lyse either vesicular stomatitis virus infected BALB/c3T3 cells or the tumor target P815. Macrophages were activated in a manner so that they could lyse both targets. The ability of this activated population to lyse either target type was differentially inhibited by varying the assay conditions. The lysis of P815 targets was more sensitive to inhibition by the proteinase inhibitor N-p-tosyl-L-lysine chloromethyl ketone than was the lysis of virally infected cells. On the other hand, reduction of the concentration of glucose in the assay medium, which inhibits the production of oxygen metabolites by the hexose monophosphate shunt, or the addition of anti-tumor necrosis factor (anti-TNF) serum were able to decrease the lysis of virally infected targets but not P815 targets. Thus, the observed differences in the lysis of these two targets were due to both the activation state of the macrophages and the differential susceptibility of the targets to different effector mechanisms.