Different susceptibilities to cell death induced by t-butylhydroperoxide could depend upon cell histotype-associated growth features

The effects of the oxidizing agent t-butylhydroperoxide (t-BHP) were investigated on three human cell lines of different origin and growth features (A431 epithelial cells, ADF astrocytoma cells and U937 leukemic cells) using electron microscopy and electron paramagnetic resonance spectroscopy. The results indicate that important biophysical and ultrastructural modifications are induced in the plasma and mitochondrial membranes of these cells and that these changes can ultimately lead to cell death. In addition, the cell cytoskeleton also appears to be a target of hydroperoxide-mediated stress. In particular, all three cell types undergo cytoskeletal alterations leading to surface blebbing, a typical characteristic of cell damage. However, the timing and extent of this damage as well as that occurring at the mitochondrial and plasma membrane levels seems to be different: cells with weak (ADF) or absent (U937) cell-to-cell and cell-substrate contacts and a poorly developed cytoskeleton appear to be more susceptible than other cell types (e.g., A431) to t-BHP-mediated injury. These diverse cell susceptibilities to hydroperoxide-mediated oxidative stress could thus depend upon cell histotype-associated growth featurs.Abbreviations t-BHP tert-butylhydroperoxide - DMEM Dulbecco's Modified Eagle's Medium - EPR electron paramagnetic resonance - GSH reduced glutathione - 5-NSA nitroxystearic acid - PBS phosphate-buffered saline     

Cytopathological features of cell suffering and death: Role of plasma membrane and cytoskeleton

Morphological and ultrastructural modifications related to the cell injury and leading to cell death have been investigated by using different compounds. Data obtained by treating various cultured cells with a quinone (menadione), a polar solvent (NMF) and a bacterial protein toxin (toxin B fromClostridium difficile) are here reported Differences seem to exist between such injuries, but changes in plasma membrane structure, called surface blebbing phenomenon, represent a common feature which can be in any case detected. Our results also allow to hypothesize an important role of cytoskeleton in such a process.     

Human Erythrocyte Insulin Receptor Processing Is Affected by the Oxidizing Agent Menadione

Insulin-induced down-regulation of erythrocyte insulin receptors is a simplified model that can provide useful information on the cell surface regulative phenomena and on role of the plasma membrane and cytoskeleton in such physiological processes. Oxidative imbalance was examined since it was shown to play an important role in numerous cellular pathologies as well as in cell aging. Specifically, the free radical inducer menadione was used in order to evaluate if this compound is able to modify (and in which manner) the down-regulation process. Biochemical, biophysical, and ultrastructural approaches were used. The results obtained seem to indicate that menadione-induced oxidative damage was able to decrease the insulin-induced down-regulation process, as measured by binding assays. This effect was accompanied by slight alterations in plasma membrane ultrastructure and insignificant variations in plasma membrane lipid composition. In addition, the decrease in membrane order, measured by electron paramagnetic resonance, which was shown to usually occur during the process of down-regulation, was not observed. In contrast, cytoskeletal protein assembly, as previously shown in other in vitro systems, appeared to be remarkably altered. Such changes in specific cytoskeletal elements could lead to the decrease of down-regulation phenomenon induced by menadione. Changes in electrophoretic pattern of some cytoskeletal proteins (e.g., spectrin) reenforce this hypothesis. Considering the importance of free radicals in cell injury, data reported here could represent a specific example of a general mechanism by which cell surface receptor expression and recycling can be modified by changes in some intracellular molecule redox status and cell ionic homeostasis.     

Superoxide dismutase and catalase conjugated to polyethylene glycol increases endothelial enzyme activity and oxidant resistance

Covalent conjugation of superoxide dismutase and catalase with polyethylene glycol (PEG) increases the circulatory half-lives of these enzymes from less than 10 min to 40 h, reduces immunogenicity, and decreases sensitivity to proteolysis. Because PEG has surface active properties and can induce cell fusion, we hypothesized that PEG conjugation could enhance cell binding and association of normally membrane-impermeable enzymes. Incubation of cultured porcine aortic endothelial cells with 125I-PEG-catalase or 125I-PEG-superoxide dismutase produced a linear, concentration-dependent increase in cellular enzyme activity and radioactivity. Fluorescently labeled PEG-superoxide dismutase incubated with endothelial cells showed a vesicular localization. Mechanical injury to cell monolayers, which is known to stimulate endocytosis, further increased the uptake of fluorescent PEG-superoxide dismutase. Endothelial cell cultures incubated with PEG-superoxide dismutase and PEG-catalase for 24 h and then extensively washed were protected from the damaging effects of reactive oxygen species derived from exogenous xanthine oxidase as judged by two criteria: decreased release of intracellular 51Cr-labeled proteins and free radical-induced changes in membrane fluidity, measured by electron paramagnetic resonance spectroscopy of endothelial membrane proteins covalently labeled with 4-maleimido-2,2,6,6-tetramethylpiperidinooxyl. Addition of PEG and PEG-conjugated enzymes perturbed the spin-label binding environment, indicative of producing an increase in plasma membrane fluidity. Thus, PEG conjugation to superoxide dismutase and catalase enhances cell association of these enzymes in a manner which increases cellular enzyme activities and provides prolonged protection from partially reduced oxygen species.     

Partial characterization of human choriocarcinoma cell line JAR cells in regard to oxidative stress

Characterization of free radical-induced cell injury processes of placenta cells is of vital importance for clinical medicine for the maintenance of intrauterine fetal life. The present study has analyzed cell injury processes in cells of the choriocarcinoma cell line JAR treated with menadione, an anticancer drug, and H(2)O(2) in comparison to osteosarcoma 143B cells using electron microscopic and flow cytometric techniques. Flow cytometry on JAR cells exposed to 100 muM menadione and double-stained with Annexin V and propidium iodide (PI) detected apoptotic cells reaching the maximum after 4 h of incubation with a rapid decrease thereafter. Viable cells became decreased to 46% of the control after 2 h of incubation, reaching 5% after 4 h. Cells stainable with both Annexin V and PI began to increase distinctly after 2 h of incubation, reaching 55% after 4 h. Electron microscopy showed that cells stainable with both dyes specified above had condensed nuclei and swollen cytoplasm, suggesting that they were undergoing a switch of the cell death mode from apoptosis to necrosis. On the other hand, 90% of 143B cells remained intact after 4 h of menadione treatment although the intracellular levels of superoxide were always higher than those of JAR cells treated with the drug. In contrast, JAR cells were more resistant than 143B cells to H(2)O(2)-induced cytotoxicity. These results may suggest that cytotoxicity of menadione cannot be explained simply by oxygen free radicals generated from the drug. The resistance of JAR cells to oxygen free radical-induced cytotoxicity may be advantageous for intrauterine fetal life.     

The Cytoskeleton As A Target In Quinone Toxicity

The exposure of mammalian cells to toxic concentrations of redox cycling and alkylating quinones causes marked changes in cell surface structure knoun as plasma membrane blebbing. These alterations are associated with the redistribution of plasma membrane proteins and the disruption of the normal organization of the cytoskeletal microfilaments which appears 10 be due mainly to actin cross-linking and dissociation of α-actinin from the actin network. The major hiochemical mechanisms responsible for these effects seem to involve the depletion of cytoskeletal protein dfhydryl groups and the increase cytosolic Ca²⁺ concentration following the alkylation/oxidation of free sulfhydryl groups in several Ca²⁺ transport systems. Depletion of intracellular ATP is also associated with quinone-induced plasma menibrane blebbing. However, ATP depletion occurs well after the onset of the morphological changes. and thus it does not seem to be causatively related to their appeardncc Thiol reductants. such as dithiothreitol. efficiently prevent the oxidation of cytoskeletal protein thiols. the increase in cytosolic free Ca²⁺ concentration and cell blebbing induced by redox cycling. but not alkylating. quinones. These results demonstrate that alkylating and redox cycling quinones cause siinilar structural and biochemical modifications of the cytoskeleton by means of different mechanisms. namely alkylation and oxidation of critical sulfhydryl groups     

Heat stress causes spatially-distinct membrane re-modelling in K562 leukemia cells

Cellular membranes respond rapidly to various environmental perturbations. Previously we showed that modulations in membrane fluidity achieved by heat stress (HS) resulted in pronounced membrane organization alterations which could be intimately linked to the expression and cellular distribution of heat shock proteins. Here we examine heat-induced membrane changes using several visualisation methods. With Laurdan two-photon microscopy we demonstrate that, in contrast to the enhanced formation of ordered domains in surface membranes, the molecular disorder is significantly elevated within the internal membranes of cells preexposed to mild HS. These results were compared with those obtained by anisotropy, fluorescence lifetime and electron paramagnetic resonance measurements. All probes detected membrane changes upon HS. However, the structurally different probes revealed substantially distinct alterations in membrane heterogeneity. These data call attention to the careful interpretation of results obtained with only a single label. Subtle changes in membrane microstructure in the decision-making of thermal cell killing could have potential application in cancer therapy.     

A 50-Hz magnetic field induces structural and biophysical changes in membranes

The effects of a 50-Hz extremely low frequency magnetic field on cultured K562 cells growing in suspension were studied by means of scanning electron microscopy and electron paramagnetic resonance spectroscopy. Exposure of K562 cells at 2.5 mT for periods to 96 hours induced significant changes in cell-surface structure and physiology without modification of proliferative capability as indicated by quantitative analysis. Thus extremely low frequency fields seem able to induce injurious, sublethal cell alterations, and the plasma membrane seems to play an important role in this effect. © 1993 Wiley-Liss, Inc.     

Cell Swelling, Blebbing, and Death Are Dependent on ATP Depletion and Independent of Calcium During Chemical Hypoxia in a Glial Cell Line (ROC-1)

The morphological and biochemical changes that occur during chemical hypoxic injury in a neural cell line were studied in the presence and absence of calcium. Oligodendroglial-glioma hybrid cells (ROC-1) were subjected to inhibitors of glycolytic and oxidative ATP synthesis (chemical hypoxia). Complete respiratory inhibition depleted [ATP] to less than 5% of control by 4 min. Blebs appeared on the cell surfaces and cells began to swell within a few minutes of ATP depletion. A 200% increase in cell volume and bleb coalescence preceded irreversible cell injury (lactate dehydrogenase release) which began at approximately 20 min with 50% cell death by 40 min. In energized cells an equivalent degree of osmotic swelling induced by ouabain inhibition of the Na+, K(+)-ATPase pump did not produce blebbing or cell death. Partial inhibition of respiration decreased [ATP] to approximately 10% of control by 40 min. Blebbing and swelling began at 40 min and bleb coalescence preceded plasma membrane disruption which began at approximately 55 min. ATP depletion, blebbing, swelling, and death followed similar time courses in the presence or absence of extracellular calcium ([Ca2+]e). Intracellular calcium ([Ca2+]i) was measured using fura-2. In calcium-containing medium metabolic inhibition caused a transient increase in resting [Ca2+]i (100 +/- 17 nM) followed by a low steady-state level preceding plasma membrane disruption. Following deenergization in calcium-free medium, [Ca2+]i remained below 60 nM throughout injury and death. These data suggest that decreased ATP initiates a sequence of events including bleb formation and cell swelling that lead to irreversible cell injury in the absence of large increases in [Ca2+]i.     

Ischemia/reperfusion-induced changes in membrane fluidity characteristics of brain capillary endothelial cells and its prevention by liposomal-incorporated superoxide dismutase.

The effect of global cerebral ischemia and reperfusion on cerebral capillary endothelial cell membrane fluidity was examined using electron paramagnetic resonance techniques following 8 minutes of global ischemia and 15 minutes of blood reperfusion. The luminal surface of the cerebral vasculature was perfused with a series of doxyl stearic acid reporters (5-, 12-, 16-doxyl stearic acid) which differ in the site of attachment of the nitroxide free radical on the fatty acid chain. Each doxyl stearic acid reports on membrane fluidity characteristics from different depths within the membrane. Ischemia/reperfusion produced a membrane ordering that was markedly dependent on intramembrane location, and was consistent with changes previously associated with lipid peroxidation. The effect of ischemia/reperfusion on membrane fluidity was maximal in the membrane environment reported by 12-doxyl stearic acid (12-DS). The utilization of a liposomal system was shown to enhance superoxide dismutase delivery to cerebral tissues as well as attenuating the change in membrane order seen following reperfusion-induced lipid peroxidation.     

The oxidizing agent menadione induces an increase in the intracellular molecular oxygen concentration in K562 and A431 cells: Direct measurement using the new paramagnetic EPR probe fusinite

The intracellular molecular oxygen concentration in control and menadione-treated K562 (an erythroleukemic cell line that grows in suspension) and A431 (an epidermal carcinoma that grows in monolayer) cells was measured directly by using the new electron paramagnetic resonance (EPR) probe fusinite. Because the oxidizing agent menadione is known to damage mitochondria and the cytoplasmic membrane in other cell systems, before conducting measurements of oxygen concentration in K562 and A431 cells, it was necessary to establish injury in these systems as well. Consequently, morphological and flow cytometric analyses were conducted after menadione treatment. The data presented here show that the two cell lines are heavily damaged by menadione. Once this menadione-induced injury was demonstrated, measurements of oxygen concentration were carried out in both K562 and A431 cells. Treatment with this quinone induces a sharp increase in intracytoplasmic molecular oxygen in both cell lines (from about 1% to about 10 and 15% in K562 and A431 cells, respectively). In addition, to gain a more complete understanding of the effects of menadione on cells, the extracellular molecular oxygen concentration and the oxygen consumption rate were also measured in control and menadione-treated K562 cells. These measurements demonstrate that menadione treatment results in an increase in the extracellular oxygen concentration (from about 5% in controls to 15% in treated cells) as well as a decrease in the oxygen consumption rate (from about 10 ng O/min/10⁶ cells in controls to 3 ng O/min/10⁶ cells after menadione exposure). The importance of the new EPR probe fusinite in monitoring directly cellular functions in which oxygen is involved and the effects of menadione on cellular oxygen balance are discussed.     

Cell membrane damage is involved in the impaired survival of bone marrow stem cells by oxidized low‐density lipoprotein

Cell therapy with bone marrow stem cells (BMSCs) remains a viable option for tissue repair and regeneration. A major challenge for cell therapy is the limited cell survival after implantation. This study was to investigate the effect of oxidized low‐density lipoprotein (ox‐LDL, naturally present in human blood) on BMSC injury and the effect of MG53, a tissue repair protein, for the improvement of stem cell survival. Rat bone marrow multipotent adult progenitor cells (MAPCs) were treated with ox‐LDL, which caused significant cell death as reflected by the increased LDH release to the media. Exposure of MAPCs to ox‐LDL led to entry of fluorescent dye FM1‐43 measured under confocal microscope, suggesting damage to the plasma membrane. Ox‐LDL also generated reactive oxygen species (ROS) as measured with electron paramagnetic resonance spectroscopy. While antioxidant N‐acetylcysteine completely blocked ROS production from ox‐LDL, it failed to prevent ox‐LDL‐induced cell death. When MAPCs were treated with the recombinant human MG53 protein (rhMG53) ox‐LDL induced LDH release and FM1‐43 dye entry were significantly reduced. In the presence of rhMG53, the MAPCs showed enhanced cell survival and proliferation. Our data suggest that membrane damage induced by ox‐LDL contributed to the impaired survival of MAPCs. rhMG53 treatment protected MAPCs against membrane damage and enhanced their survival which might represent a novel means for improving efficacy for stem cell‐based therapy for treatment of diseases, especially in setting of hyperlipidemia.     

Cell nucleus and DNA fragmentation are not required for apoptosis

Apoptosis is the predominant form of cell death and occurs under a variety of physiological and pathological conditions. Cells undergoing apoptotic cell death reveal a characteristic sequence of cytological alterations including membrane blebbing and nuclear and cytoplasmic condensation. Activation of an endonuclease which cleaves genomic DNA into internucleosomal DNA fragments is considered to be the hallmark of apoptosis. However, no clear evidence exists that DNA degradation plays a primary and causative role in apoptotic cell death. Here we show that cells enucleated with cytochalasin B still undergo apoptosis induced either by treatment with menadione, an oxidant quinone compound, or by triggering APO-1/Fas, a cell surface molecule involved in physiological cell death. Incubation of enucleated cells with the agonistic monoclonal anti-APO-1 antibody revealed the key morphological features of apoptosis. Moreover, in non-enucleated cells inhibitors of endonuclease blocked DNA fragmentation, but not cell death induced by anti-APO-1. These data suggest that DNA degradation and nuclear signaling are not required for induction of apoptotic cell death.     

Assessment of apoptosis in xenobiotic-induced immunotoxicity.

Generation of immunity is a highly complex process in which proliferation and differentiation of immune-competent cells regulated by cytokines and cell-cell interactions play a major role. Reducing the number of immune-competent cells or altering the function, selection, and differentiation of lymphocytes after xenobiotic treatment may lead to serious adverse effects. Programmed cell death, or apoptosis, is a highly regulated process by which an organism eliminates unwanted cells without eliciting an inflammatory response. However, xenobiotics are also able to trigger unwanted apoptosis or to alter the regulation of programmed cell death. Cytological characteristics of apoptosis are generally different from those seen in acute pathological cell death resulting from cell injury. The morphological characteristics of apoptosis are unique including cell shrinkage, membrane blebbing, chromatin condensation, DNA fragmentation, disruption of the nuclear lamina, nuclear fragmentation, and emergence of apoptotic bodies. It is now established that apoptosis plays a critical role in both development and homeostasis of the immune system: thymic selection, cytotoxicity, deletion of autoreactive cells, and regulation of the size of the lymphoid compartment. Assessment of apoptosis relies on the morphological and biochemical modifications of the dying cells. As a rule, and because an apoptotic cell rarely displays all of the characteristic apoptotic features, several criteria should be monitored in parallel including morphological examination. The techniques described in this paper have been divided into five categories: analysis of cell morphology by microscopy, identification of DNA fragmentation, determination of mitochondrial membrane potential, detection of plasma membrane changes, analysis of caspase activation.     

Structural bases of the cytolytic mechanisms of Entamoeba histolytica

The cellular bases of the powerful cytolytic activity of the human protozoan parasite Entamoeba histolytica were explored by studying the effect of the virulent strain HM1:IMSS on epithelial monolayers of MDCK cells using a combination of time-lapse microcinematography and transmission and scanning electron microscopy. Early alterations of the epithelial cell membranes were detected by measuring changes in the transepithelial electrical resistance of MDCK monolayers mounted in Ussing chambers. The aggressive mechanism of E. histolytica trophozoites was found to be a complex, multifactorial phenomenon that included hit-and-run damage to the plasma membrane of effector cells mediated through contact, phagocytosis of lysed or apparently intact, but detached, MDCK cells, and intracellular degradation of ingested cells. Following contact with amebas, the epithelial monolayers showed a pronounced lowering of transepithelial resistance, opening of tight junctions, distortion of microvilli, surface blebbing, and the presence of minute focal discontinuities in the plasma membrane. There was no evidence of amebic exocytosis, membrane fusion, or junction formation between the parasite and host plasma membranes. Although modifications in the epithelial cell membranes usually preceded lysis, the cytolytic activity of the parasite did not exclusively involve damage to the plasma membrane of the cultured host cells but also was mediated by avid phagocytosis, the displacement and separation of neighboring cells by means of pseudopodial activity, and the "pinching-off" of the peripheral cytoplasm of epithelial cells.     

Cell Blebbing and Membrane Area Homeostasis in Spreading and Retracting Cells

Cells remodel their plasma membrane and cytoskeleton during numerous physiological processes, including spreading and motility. Morphological changes require the cell to adjust its membrane tension on different timescales. While it is known that endo- and exocytosis regulate the cell membrane area in a timescale of 1 h, faster processes, such as abrupt cell detachment, require faster regulation of the plasma membrane tension. In this article, we demonstrate that cell blebbing plays a critical role in the global mechanical homeostasis of the cell through regulation of membrane tension. Abrupt cell detachment leads to pronounced blebbing (which slow detachment does not), and blebbing decreases with time in a dynamin-dependent fashion. Cells only start spreading after a lag period whose duration depends on the cell's blebbing activity. Our model quantitatively reproduces the monotonic decay of the blebbing activity and accounts for the lag phase in the spreading of blebbing cells.     

白藜芦醇以Caspase依赖和非依赖两种方式导致Jurkat细胞死亡

应用形态学观察、流式细胞仪检测、Western印迹和DNA凝胶电泳等方法研究白藜芦醇对Jurkat细胞的作用。发现白藜芦醇处理组中细胞有皱缩、出泡、染色质边集等现象,但染色质浓缩呈散在团块状且不致密。细胞质结构疏松,线粒体肿胀,脊消失。少见凋亡小体。在白藜芦醇处理组,Western印迹可检测到弱的17kDacaspase-3条带,DNA凝胶电泳可以检测到梯状DNA和弥散条带;流式细胞仪在白藜芦醇处理组检测到大量PI单阳性细胞和少量膜联蛋白V单阳性细胞。Z-VAD-FMK干预后可以发现细胞死亡率降低,同时该组梯状DNA消失,但是大分子量弥散DNA条带依然可以检测到。结果表明白藜芦醇可以通过caspase依赖和非依赖途径导致Jurkat细胞死亡。此分子机制的明确将为白藜芦醇应用于临床白血病的治疗打下理论基础。     

H2O2 intensifies CN−-induced apoptosis in pea leaves

H2O2 intensifies CN(-)-induced apoptosis in stoma guard cells and to lesser degree in basic epidermal cells in peels of the lower epidermis isolated from pea leaves. The maximum effect of H2O2 on guard cells was observed at 10(-4) M. By switching on non-cyclic electron transfer in chloroplasts menadione and methyl viologen intensified H2O2 generation in the light, but prevented the CN--induced apoptosis in guard cells. The light stimulation of CN- effect on guard cell apoptosis cannot be caused by disturbance of the ribulose-1,5-bisphosphate carboxylase function and associated OH* generation in chloroplasts with participation of free transition metals in the Fenton or Haber-Weiss type reactions as well as with participation of the FeS clusters of the electron acceptor side of Photosystem I. Menadione and methyl viologen did not suppress the CN(-)-induced apoptosis in epidermal cells that, unlike guard cells, contain mitochondria only, but not chloroplasts. Quinacrine and diphenylene iodonium, inhibitors of NAD(P)H oxidase of cell plasma membrane, had no effect on the respiration and photosynthetic O2 evolution by leaf slices, but prevented the CN(-)-induced guard cell death. The data suggest that NAD(P)H oxidase of guard cell plasma membrane is a source of reactive oxygen species (ROS) needed for execution of CN(-)-induced programmed cell death. Chloroplasts and mitochondria were inefficient as ROS sources in the programmed death of guard cells. When ROS generation is insufficient, exogenous H2O2 exhibits a stimulating effect on programmed cell death. H2O2 decreased the inhibitory effects of DCMU and DNP-INT on the CN(-)-induced apoptosis of guard cells. Quinacrine, DCMU, and DNP-INT had no effect on CN(-)-induced death of epidermal cells.     

Structural Bases of the Cytolytic Mechanisms of Entamoeba histolytica1

The cellular bases of the powerful cytolytic activity of the human protozoan parasite Entamoeba histolytica were explored by studying the effect of the virulent strain HM1:IMSS on epithelial monolayers of MDCK cells using a combination of time-lapse microcinematography and transmission and scanning electron microscopy. Early alterations of the epithelial cell membranes were detected by measuring changes in the transepithelial electrical resistance of MOCK monolayers mounted in Ussing chambers. The aggressive mechanism of E. histolytica trophozoites was found to be a complex, multifactorial phenomenon that included hit-and-run damage to the plasma membrane of effector cells mediated through contact, phagocytosis of lysed or apparently intact, but detached, MDCK cells, and inlracellular degradation of ingested cells. Following contact with amebas, the epithelial monolayers showed a pronounced lowering of transepithelial resistance, opening of tight junctions, distortion of microvilli, surface blebbing, and the presence of minute focal discontinuities in the plasma membrane. There was no evidence of amebic exocytosis, membrane fusion, or junction formation between the parasite and host plasma membranes. Although modifications in the epithelial cell membranes usually preceded lysis, the cytolytic activity of the parasite did not exclusively involve damage to the plasma membrane of the cultured host cells but also was mediated by avid phagocytosis, the displacement and separation of neighboring cells by means of pseudopodial activity, and the “pinching-off” of the peripheral cytoplasm of epithelial cells.     

Structural biology of endogenous membrane protein assemblies in native nanodiscs

The advent of amphiphilic copolymers enables integral membrane proteins to be solubilized into stable 10–30 nm native nanodiscs to resolve their multisubunit structures, post-translational modifications, endogenous lipid bilayers, and small molecule ligands. This breakthrough has positioned biological membrane:protein assemblies (memteins) as fundamental functional units of cellular membranes. Herein, we review copolymer design strategies and methods for the characterization of transmembrane proteins within native nanodiscs by cryo-electron microscopy (cryo-EM), transmission electron microscopy, nuclear magnetic resonance spectroscopy, electron paramagnetic resonance, X-ray diffraction, surface plasmon resonance, and mass spectrometry.