Membrane transport of singlet oxygen monitored by dipole potential measurements

The efficiency of photodynamic reactions depends on 1), the penetration depth of the photosensitizer into the membrane and 2), the sidedness of the target. Molecules which are susceptible to singlet oxygen (¹O₂) experience less damage when separated from the photosensitizer by the membrane. Since ¹O₂ lifetime in the membrane environment is orders of magnitude longer than the time required for nonexcited oxygen (O₂) to cross the membrane, this observation suggests that differences between the permeabilities or membrane partition of ¹O₂ and O₂ exist. We investigated this hypothesis by releasing ¹O₂ at one side of a planar membrane while monitoring the kinetics of target damage at the opposite side of the same membrane. Damage to the target, represented by dipole-modifying molecules (phloretin or phlorizin), was indicated by changes in the interleaflet dipole potential difference Δφ_b. A simple analytical model allowed estimation of the ¹O₂ interleaflet concentration difference from the rate at which Δφ_b changed. It confirmed that the lower limit of ¹O₂ permeability is ∼2 cm/s; i.e., it roughly matches O₂ permeability as predicted by Overton's rule. Consequently, the membrane cannot act as a barrier to ¹O₂ diffusion. Differences in the reaction rates at the cytoplasmic and extracellular membrane leaflets may be attributed only to ¹O₂ quenchers inside the membrane.     

Inhibitory effects of tannin on human salivary alpha-amylase

Here, we first report on the effectiveness and specificity of tannin inhibition of 2-chloro-4-nitrophenyl-4-O-β-d-galactopyranosylmaltoside hydrolysis that is catalyzed by human salivary α-amylase (HSA). Tannin was gallotannin in which quinic acid was esterified with 2-7 units of gallic acid. A number of studies establish that polyphenols—like tannins—may prevent oral diseases, e.g., dental caries. Kinetic analyses confirmed that the inhibition of hydrolysis is a mixed non-competitive type and only one molecule of tannin binds to the active site or the secondary site of the enzyme. Since Dixon plots were linear, product formation could be excluded from the enzyme-substrate-inhibitor complex (ESI). Kinetic constants calculated from secondary plots and non-linear regression are almost identical, thereby confirming the suggested model. Kinetic constants (K_EI=9.03 μg mL⁻¹, K_ESI=47.84 μg mL⁻¹) show that tannin is as an effective inhibitor of HSA as acarbose and indicate a higher stability for the enzyme-inhibitor complex than ESI.     

Competitive Model on Denaturant-Mediated Protein Unfolding

A denaturant-mediated protein unfolding model, which is different from already existing ones based on the assumption that denaturant competes for water molecules to interact and thus reduces water–protein interactions, which leads to unfolding phenomenon, has been developed with a detailed mathematical justification. Theoretical results suggested that the parameter (m_u) obtained from the usual linear extrapolation model must be a linear function of the number of bound water molecules (n) on protein with a zero intercept. However, application of this theory to a set of proteins for which m_u values for urea denaturation are already known showed that m_u was a linear function of n but with a nonzero intercept. Finally this nonzero intercept was attributed to binding of denaturant to protein at n = 0. Detailed investigation of this factor showed that average equilibrium constant for binding of urea with aromatic side chains (generally nonpolar side chains) was k_b ≈ 0.65 ± 0.45 mol⁻¹, which agreed well with earlier experimental estimations, and also suggested that an integrated approach was necessary to avoid discrepancy in ΔG^H₂O estimated from different models.     

Influence of polyphenols on Escherichia coli resistance to oxidative stress

Among all polyphenols tested (tannic acid and flavonoids belonging to different subclasses) only tannin and quercetin significantly enhanced resistance of Escherichia coli to peroxide stress. Pretreatment of the cells with quercetin and tannin resulted in a decrease in the growth arrest duration under moderate H₂O₂ concentration (2 mM) and an increase in survival under high (10 mM) doses. The shorter growth recovery period in pretreated cells was connected with more rapid H₂O₂ elimination because of induced activity of scavenging enzymes. This effect was absent in the ΔoxyR mutant, which was unable to induce genes responding to peroxide stress. The data obtained suggest that the observed protection was a result of two overlapping effects: induction of OxyR regulon by low concentrations of H₂O₂, accumulated during extracellular autoxidation of quercetin and tannin, and protection of synthesis of OxyR-regulated antioxidant enzymes during H₂O₂ stress because of intracellular binding of iron by quercetin and tannin and suppressing Fenton chemistry.     

The oxidative burst protects plants against pathogen attack: Mechanism and role as an emergency signal for plant bio-defence — a review

Various aspects, mechanisms and functions of the oxidative burst with generation of O₂⁻ superoxide anions in plant cells, which is stimulated by active defence-inducing agents such as fungal infection or elicitor treatment, were reviewed mainly on the basis of experimental evidence obtained in a system of Solanaceae plants and Phytophthora spp. The oxidative burst may be due to an O₂⁻-generating NADPH oxidase in the plasma membrane, which is activated with combinations of cytosolic proteins, Ca²⁺, calmodulin and protein kinase, following stimulation by elicitor molecules. The oxidative burst may play the role of an internal emergency signal for induction of the metabolic cascade for active defence.     

Dependence of membrane potential on Ca2+ transport in cultured cytotrophoblasts of human immature placentas

The electrical membrane properties of cultured human cytotrophoblast were examined by means of a standard electrophysiological technique. The mean values of the membrane potential (E_m) and the membrane resistance in a physiological medium were around ?49 mV and 12 MΩ, respectively. The membrane potential was dependent, to a large extent, on the external Ca²⁺ concentration ([Ca²⁺]₀). Deprivation of external Ca²⁺ reduced membrane potential to about ?20 mV, and an increase in [Ca²⁺]₀ caused a hyperpolarization in a saturable manner. The Ca²⁺-dependency of membrane potential was affected remarkably by [K⁺]₀, but not by [Na⁺]₀ or [Cl^?]₀. The intracellular Ca²⁺ injection hyperpolarized the membrane in a Ca²⁺-free medium. A Ca²⁺ channel blocker, verapamil, completely abolished the Ca²⁺-dependent E_m. The Ca²⁺-dependent E_m was also suppressed by cooling or by the application of metabolic inhibitors. It is suggested that the Ca²⁺-dependent E_m in cultured human cytotrophoblast is caused by a Ca²⁺ influx which, in turn, increases the K⁺ conductance of the cell membrane, presumably due to stimulation of Ca²⁺-activated K⁺ channel.     

Influence of trifluoroethanol on membrane interfacial anchoring interactions of transmembrane alpha-helical peptides

Interfacial anchoring interactions between aromatic amino acid residues and the lipid-water interface are believed to be important determinants for membrane protein structure and function. Thus, it is possible that molecules that partition into the lipid-water interface can influence membrane protein activity simply by interfering with these anchoring interactions. Here we tested this hypothesis by investigating the effects of 2,2,2-trifluoroethanol (TFE) on the interaction of a Trp-flanked synthetic transmembrane peptide (acetyl-GW₂(LA)₈LW₂A-NH₂) with model membranes of dimyristoylphosphatidylcholine. Two striking observations were made. First, using ²H nuclear magnetic resonance on acyl chain deuterated lipids, we found that addition of 4 or 8 vol % of TFE completely abolishes the ability of the peptide to order and stretch the lipid acyl chains in these relatively thin bilayers. Second, we observed that addition of 8 vol % TFE reduces the tilt angle of the peptide from 5.3° to 2.5°, as measured by ²H NMR on Ala-d₄ labeled peptides. The “straightening” of the peptide was accompanied by an increased exposure of Trp to the aqueous phase, as shown by Trp-fluorescence quenching experiments using acrylamide. The observation of a reduced tilt angle was surprising because we also found that TFE partioning results in a significant thinning of the membrane, which would increase the extent of hydrophobic mismatch. In contrast to the Trp-flanked peptide, no effect of TFE was observed on the interaction of a Lys-flanked analog (acetyl-GK₂(LA)₈LK₂A-NH₂) with the lipid bilayer. These results emphasize the importance of interfacial anchoring interactions for membrane organization and provide new insights into how molecules such as TFE that can act as anesthetics may affect the behavior of membrane proteins that are enriched in aromatic amino acids at the lipid-water interface.     

Macrophage membrane proteins: Possible role in the regulation of priming for enhanced respiratory burst activity

Brief exposure of macrophages to the proteolytic enzymes papain, elastase, or trypsin primed them for enhanced production of superoxide anion (O₂⁻) in response to stimulation by phorbol myristate acetate (PMA). Priming by trypsin was achieved at 0 °C, at which temperature trypsin functions as a protease but is not internalized, supporting the concept that protease priming depends on modification of the plasma membrane. Analysis of external membrane proteins after radioiodination of intact cells and separation by gel electrophoresis indicated that papain treatment of macrophages resulted in the cleavage of a membrane protein with a molecular weight of approximately 305K. Membranes from macrophages primed by elicitation with Corynebacterium parvum also demonstrated a reduced amount of the membrane protein at approximately 305 kDa, as well as a reduction of a protein at about 270 kDa. Lipopolysaccharideelicited macrophages showed a reduced amount of a protein at about 175 kDa. Continuous spectrophotometric assays of O₂⁻ release from adherent macrophages indicated that after exposure to a stimulus, protease-treated cells produced O₂⁻ more quickly than did control cells (reduced lag time). Inhibitors of protein synthesis augmented the priming effect of papain when added with the protease. These results suggest that protease-induced priming results from inactivation of a membrane protein (or proteins) that exerts a down-regulating effect on the respiratory burst.     

Complexes of telomeric oligonucleotide d(TTAGGG)4 with the new recombinant protein vector PGEk carrying nucleic acids into proliferating cells

A study was made of the complexation of the protein vector PGEk, which transfers nucleic acids into the nuclei of cancer cells, with phosphodiester d(TTAGGG)₄ (TMO) and phosphorothioate Sd(TTAGGG)₄ (TMS) oligonucleotides, which inhibit telomerase. PGEk (64 amino-acid residues) contains a hydrophobic domain that originates from the human epidermal growth factor (hEGF) and is responsible for the receptor-mediated transfer of PGEk across the cell membrane, and the hydrophilic domain, which is a nuclear localization signal (NLS) and serves to bind DNA and deliver it to the cell nucleus. Experiments were performed in 0.01-M Na-phosphate and 0.1-M NaCl at 37°C. An analysis of the circular dichroism (CD) spectra showed that TMO forms an antiparallel G-quadruplex, while TMS occurs in the form of unfolded strands. The number of PGEk molecules adsorbed on oligonucleotides was estimated from the quenching of PGEk fluorescence and the increase in its polarization upon titration with oligonucleotides. Adsorption isotherms were plotted in Scatchard coordinates. Adsorption of the first two PGEk molecules on TMO and TMS followed a noncooperative mechanism and was characterized by high association constants: K _1(TMO) = (7 ± 1) · 10⁷ M^?1 and K _1(TMS) = (3 (± 0.5) · 10⁷ M^?1. Further adsorption, up to five or six PGEk molecules per TMO molecule, showed high cooperation and K _2(TMO) = (4.0 ± 1.5) · 10⁶ M^?1. Unlike TMO, TMS only weakly bound the third PGEk molecule: K _2(TMS) = (8 ± 2) · 10⁵ M^?1. An analysis of the CD spectra showed that PGEk partly unfolded the G-quadruplex formed by TMO and did not have an effect on the single-stranded structure of TMS. The secondary structure of DNA and the number of protein subunits were established for the biologically active complexes PGEk-TMO and PGEk-TMS, which efficiently pass across the membrane of cancer cells and inhibit their proliferation.     

Deciphering the potential involvement of PXMP2 and PEX11B in hydrogen peroxide permeation across the peroxisomal membrane reveals a role for PEX11B in protein sorting

Peroxisomes have the intrinsic ability to produce and scavenge hydrogen peroxide (H₂O₂), a diffusible second messenger that controls diverse cellular processes by modulating protein activity through cysteine oxidation. Current evidence indicates that H₂O₂, a molecule whose physicochemical properties are similar to those of water, traverses cellular membranes through specific aquaporin channels, called peroxiporins. Until now, no peroxiporin-like proteins have been identified in the peroxisomal membrane, and it is widely assumed that small molecules such as H₂O₂ can freely permeate this membrane through PXMP2, a non-selective pore-forming protein with an upper molecular size limit of 300–600 Da. By employing the CRISPR-Cas9 technology in combination with a Flp-In T-REx 293 cell line that can be used to selectively generate H₂O₂ inside peroxisomes in a controlled manner, we provide evidence that PXMP2 is not essential for H₂O₂ permeation across the peroxisomal membrane, neither in control cells nor in cells lacking PEX11B, a peroxisomal membrane-shaping protein whose yeast homologue facilitates the permeation of molecules up to 400 Da. During the course of this study, we unexpectedly noted that inactivation of PEX11B leads to partial localization of both peroxisomal membrane and matrix proteins to mitochondria and a decrease in peroxisome density. These findings are discussed in terms of the formation of a functional peroxisomal matrix protein import machinery in the outer mitochondrial membrane.     

Lysosome-membrane fusion mediated superoxide production in hyperglycaemia-induced endothelial dysfunction

Lysosomal exocytosis and fusion to cellular membrane is critical in the oxidative stress formation of endothelium under apoptotic stimulus. We investigated the role therein of it in hyperglycaemia-induced endothelial dysfunction. The lysosome-membrane fusion was shown by the expression of lamp1, the lysosomal membrane marker, on cellular membrane and the transportation of lysosomal symbolic enzymes into cultural medium. We also examined the ceramide production, lipid rafts (LRs) clustering, colocalization of gp91^phox, a NADPH oxidase subunit (NOX) to LRs clusters, superoxide (O₂ ^{. -}) formation and nitric oxide (NO) content in human umbilical vein endothelial cells (HUVEC) and the endothelium-dependent NO-mediated vasodilation in isolated rat aorta. As compared to normal glucose (5.6 mmol/l, Ctrl) incubation, high glucose (22 mmol/l, HG) exposure facilitated the lysosome-membrane fusion in HUVEC shown by significantly increased quantity of lamp1 protein on cellular membrane and enhanced activity of lysosomal symbolized enzymes in cultural medium. HG incubation also elicited ceramide generation, LRs clustering and gp91^phox colocalization to LRs clusters which were proved to mediate the HG induced O₂ ^{. -} formation and NO depletion in HUVEC. Functionally, the endothelium-dependent NO-mediated vasodilation in aorta was blunted substantially after HG incubation. Moreover, the HG-induced effect including ceramide production, LRs clustering, gp91^phox colocalization to LRs clusters, O₂ ^{. -} formation and endothelial dysfunction could be blocked significantly by the inhibition of lysosome-membrane fusion. We propose that hyperglycaemia-induced endothelial impairment is closely related to the lysosome-membrane fusion and the following LRs clustering, LRs-NOX platforms formation and O₂ ^{. -} production.     

Effect of action potential on photosynthesis and spatially distributed H+ fluxes in cells and Chloroplasts of Chara corallina

When exposed to light, the cells of characean algae produce intermittent regions of H⁺ extrusion and H⁺ absorption, featuring different photosynthetic activities. Methods for local measurements of outer pH, O₂ content, and photochemical activity of photosystem II (PSII) were applied to examine microscopic regions of Chara coralline Klein ex Willd. internodes. The results show that the functional spatial heterogeneity of these excitable cells is controlled not only by light but also by electric excitation of the plasma membrane. Generation of a single action potential (AP) induced a reversible transition to the state with homogenous pH distribution and had different effects on photosynthesis in cell regions producing alkaline and acid zones. The effective quantum yield of PSII primary processes and the maximal chlorophyll fluorescence decreased after AP in the alkaline cell regions but were almost unaffected in the acidic cell regions. The suppression of photosynthesis after AP was also evident in the decrease of photosynthetic O₂ evolution. The results provide evidence that electric signals arising at the plasmalemma are transmitted to the level of thylakoid membranes. The effects of electric excitation on fluorescence and the quantum yield of PSII photochemistry were best pronounced at low light intensities and low level of nonphotochemical quenching. The sensitivity of chlorophyll fluorescence in resting and excited cells to light intensity and protonophores indicates that the AP-induced fluorescence changes derive from the increase in pH gradient at the thylakoid membrane. The temporal elimination of alkaline zones and inhibition of photosynthesis apparently arise from parallel operational sequences that have a common initial stage. A possible role of cytosolic Ca²⁺ rise in the mechanism of photosynthesis suppression after electric excitation of the plasma membrane is discussed.     

En Face Detection of Nitric Oxide and Superoxide in Endothelial Layer of Intact Arteries

Endothelium-derived nitric oxide (NO) produced from endothelial NO-synthase (eNOS) is one of the most important vasoprotective molecules in cardiovascular physiology. Dysfunctional eNOS such as uncoupling of eNOS leads to decrease in NO bioavailability and increase in superoxide anion (O₂^.−) production, and in turn promotes cardiovascular diseases. Therefore, appropriate measurement of NO and O₂^.− levels in the endothelial cells are pivotal for research on cardiovascular diseases and complications. Because of the extremely labile nature of NO and O₂^.−, it is difficult to measure NO and O₂^.− directly in a blood vessel. Numerous methods have been developed to measure NO and O₂^.− production. It is, however, either insensitive, or non-specific, or technically demanding and requires special equipment. Here we describe an adaption of the fluorescence dye method for en face simultaneous detection and visualization of intracellular NO and O₂^.− using the cell permeable diaminofluorescein-2 diacetate (DAF-2DA) and dihydroethidium (DHE), respectively, in intact aortas of an obesity mouse model induced by high-fat-diet feeding. We could demonstrate decreased intracellular NO and enhanced O₂^.− levels in the freshly isolated intact aortas of obesity mouse as compared to the control lean mouse. We demonstrate that this method is an easy technique for direct detection and visualization of NO and O₂^.− in the intact blood vessels and can be widely applied for investigation of endothelial (dys)function under (physio)pathological conditions.     

Singlet oxygen-mediated signaling in plants: moving from flu to wild type reveals an increasing complexity

Singlet oxygen (¹O₂)-mediated signaling has been established in the conditional fluorescent (flu) mutant of Arabidopsis. In the dark, the flu mutant accumulates free protochlorophyllide (Pchlide), a photosensitizer that in the light generates ¹O₂. The release of ¹O₂ leads to growth inhibition of mature plants and bleaching of seedlings. These ¹O₂-mediated responses depend on two plastid proteins, EXECUTER (EX) 1 and 2. An ex1/ex2/flu mutant accumulates in the dark Pchlide and upon illumination generates similar amounts of ¹O₂ as flu, but ¹O₂-mediated responses are abrogated in the triple mutant. The ¹O₂- and EX-dependent signaling pathway operates also in wild type placed under light stress. However, it does not act alone as in flu, but interacts with other signaling pathways that modulate ¹O₂-mediated responses. Depending on how severe the light stress is, ¹O₂- and EX-dependent signaling may be superimposed by ¹O₂-mediated signaling that does not depend on EX and is associated with photo-oxidative damage. Because of its high reactivity and short half-life, ¹O₂ is unlikely to be a signal that is translocated across the chloroplast envelope, but is likely to interact with other plastid components close to its site of production and to generate more stable signaling molecules during this interaction. Depending on the site of ¹O₂ production and the severity of stress, different signaling molecules may be expected that give rise to different ¹O₂-mediated responses.     

Radiorespirometer for continuous monitoring of chick embryo development.

A radiorespirometer is described that is capable of continuous monitoring of O₂ utilization, CO₂ and/or ¹⁴CO₂ production per minute, heart rate, and body activity of an embryonated egg while it develops for several days in a closed chamber with near normal pO₂ or other desired pO₂. Oxygen is supplied to the embryo by an electrolytic cell, and CO₂ is removed by a KOH solution flowing through a diffusion cell separated from the embryo chamber by a CO₂ permeable rubber membrane. The instrument permits selecting embryos for viability and developmental stage, according to their O₂ utilization per minute and respiratory quotient, without breaking the eggshell. Inoculation of the embryonated egg with ¹⁴C-labeled substrates, drugs, or toxins can occur without interfering with continuous recording of metabolic activity.     

Photooxidase activity of Rhodospirillum rubrum chromatophores and reaction center complexes. The role of non-cyclic electron transfer in generation of the membrane potential

The mechanism of light-induced O₂ uptake by chromatophores and isolated P-870 reaction center complexes from Rhodospirillum rubrum has been investigated.The process is inhibited by o-phenanthroline and also by an extraction of loosely bound quinones from chromatophores. Vitamin K-3 restored the o-phenanthroline-sensitive light-induced O₂ uptake by the extracted chromatophores and stimulated the O₂ uptake by the reaction center complexes. It is believed that photooxidase activity of native chromatophores is due to an interaction of loosely bound photoreduced ubiquinone with O₂. Another component distinguishable from the loosely bound ubiquinone is also oxidized by O₂ upon the addition of detergents (lauryldimethylamine oxide or Triton X-100) to the illuminated reaction center complexes and to the extracted or native chromatophores treated by o-phenanthroline. Two types of photooxidase activity are distinguished by their dependence on pH.The oxidation of chromatophore redox chain components due to photooxidase activity as well as the over-reduction of these components in chromatophores, incubated with 2,3,5,6-tetramethyl-p-phenylenediamine (Me₄Ph(NH₂)₂) or N,N,N′,N′-tetramethyl-p-phenylenediamine (TMPD) (plus ascorbate) in the absence of exogenous electron acceptors, leads to an inhibition of the membrane potential generation, as measured by the light-induced uptake of penetrating phenyldicarbaundecaborane anions (PCB^?) and tetraphenylborate anions. The inhibition of the penetrating anion responses observed under reducing conditions is removed by oxygen, 1,4-naphthoquinone, fumarate, vitamin K-3 and methylviologen, but not by NAD⁺ or benzylviologen. Since methylviologen does not act as an electron acceptor with the extracted chromatophores, it is believed that this compound, together with fumarate and O₂, gains electrons at the level of the loosely bound ubiquinone. Data on the relationship between photooxidase activity and membrane potential generation by the chromatophores show that non-cyclic electron transfer from reduced Me₄Ph(NH₂)₂ to the exogenous acceptors is an electrogenic process, whereas non-cyclic electron transfer from reduced TMPD is non-electrogenic.Being oxidized, Me₄Ph(NH₂)₂ and TMPD are capable of the shunting of the cyclic redox chain of the chromatophores. Experiments with extracted chromatophores show that the mechanisms of the shunting by Me₄Ph(NH₂)₂ and TMPD are different.     

Propidium uptake and ATP release in A549 cells share similar transport mechanisms

The lipid bilayer of eukaryotic cells’ plasma membrane is almost impermeable to small ions and large polar molecules, but its miniscule basal permeability in intact cells is poorly characterized. This report describes the intrinsic membrane permeability of A549 cells toward the charged molecules propidium (Pr²⁺) and ATP^4?. Under isotonic conditions, we detected with quantitative fluorescence microscopy, a continuous low-rate uptake of Pr (～150 × 10^?21 moles (zmol)/h/cell, [Pr]_o = 150 μM, 32°C). It was stimulated transiently but strongly by 66% hypotonic cell swelling reaching an influx amplitude of ～1500 (zmol/h)/cell. The progressive Pr uptake with increasing [Pr]_o (30, 150, and 750 μM) suggested a permeation mechanism by simple diffusion. We quantified separately ATP release with custom wide-field-of-view chemiluminescence imaging. The strong proportionality between ATP efflux and Pr²⁺ influx during hypotonic challenge, and the absence of stimulation of transmembrane transport following 300% hypertonic shock, indicated that ATP and Pr travel the same conductive pathway. The fluorescence images revealed a homogeneously distributed intracellular uptake of Pr not consistent with high-conductance channels expressed at low density on the plasma membrane. We hypothesized that the pathway consists of transiently formed water pores evenly spread across the plasma membrane. The abolition of cell swelling-induced Pr uptake with 500 μM gadolinium, a known modulator of membrane fluidity, supported the involvement of water pores whose formation depends on the membrane fluidity. Our study suggests an alternative model of a direct permeation of ATP (and other molecules) through the phospholipid bilayer, which may have important physiological implications.     

The Respiratory Burst and Electrolyte Leakage Induced by Sulfhydryl Blockers in Egeria densa Leaves Are Associated with H2O2 Production and Are Dependent on Ca2+ Influx

In leaves of Egeria densa Planchon, N-ethylmaleimide (NEM) and other sulfhydryl-binding reagents induce a temporary increase in nonmitochondrial respiration (ΔQO₂) that is inhibited by diphenylene iodonium and quinacrine, two known inhibitors of the plasma membrane NADPH oxidase, and are associated with a relevant increase in electrolyte leakage (M. Bellando, S. Sacco, F. Albergoni, P. Rocco, M.T. Marré [1997] Bot Acta 110: 388–394). In this paper we report data indicating further analogies between the oxidative burst induced by sulfhydryl blockers in E. densa and that induced by pathogen-derived elicitors in animal and plant cells: (a) NEM- and Ag⁺-induced ΔQO₂ was associated with H₂O₂ production and both effects depended on the presence of external Ca²⁺; (b) Ca²⁺ influx was markedly increased by treatment with NEM; (c) the Ca²⁺ channel blocker LaCl₃ inhibited ΔQO₂, electrolyte release, and membrane depolarization induced by the sulfhydryl reagents; and (d) LaCl₃ also inhibited electrolyte leakage induced by the direct infiltration of the leaves with H₂O₂. These results suggest a model in which the interaction of sulfhydryl blockers with sulfhydryl groups of cell components would primarily induce an increase in the Ca²⁺ cytosolic concentration, followed by membrane depolarization and activation of a plasma membrane NADPH oxidase. This latter effect, producing active oxygen species, might further influence plasma membrane permeability, leading to the massive release of electrolytes from the tissue.