Ascorbate free radical and its role in growth control

Summary Ascorbate and its free radical potentiates proliferation of HL-60 cells in serum-limiting media. Dehydroascorbate does not affect growth. This stimulation of growth is due to a general shortening of the cell cycle. The incubation of HL-60 cells with ascorbate free radical produces a significant change of the redox potential of cells. The presence of cells in culture media avoids the total oxidation of ascorbate, and also HL-60 cells induce the short-term stabilization of ascorbate. Ascorbate free radical potentiates also the onset of DNA synthesis in CCL39 cells induced by fetal calf serum, although itself does not affect quiescense to proliferation transition. This transition induced by fetal calf serum also potentiates the capacity of CCL39 cells to stabilize ascorbate. We discuss here the role of ascorbate free radical on growth control by its reduction by the plasma membrane redox system and its meaning for cell physioslogy.     

Extracellular ascorbate stabilization: Enzymatic or chemical process?

Ascorbate is stabilized in the presence of HL-60 cells. This stabilization has been questioned as a simple chemical effect. Further properties and controls about the enzymatic nature of this stabilization are described and discussed. Our results showed that cAMP derivatives and cAMP-increasing agents stimulated the ability of HL-60 cells to stabilize ascorbate. On the other hand, tunicamycin, a glycosylation-interfering agent, inhibited this ability. These data, together with hormonal regulation, support the hypothesis of an enzymatic redox system located at the plasma membrane as being responsible for the extracellular ascorbate stabilization by HL-60 cells.     

Contribution of a plasma membrane redox system to the superoxide production by wheat root cells

Summary Wound stress activated wheat root cells to produce oxygen radicals. The production was accompanied by an increased permeability for potassium ions and a depolarization of the plasma membrane. Various electron donors, such as the nonpenetrating donor potassium ferrocyanide as well as NADH and NADPH, caused the amplification of superoxide production by root cells. The -generating system in wheat root cells was found to be considerably sensitive to diphenylene iodonium, which is generally considered as a suicide inhibitor of neutrophil NADPH oxidase, and to other inhibitors of flavoprotein activity, chlorpromazine and quinine. The xenobiotic compound amidopyrine caused activation of the -generating system, which was depressed by DPI. The -generating system in root cells was shown to be significantly dependent on calcium content. Calcium loading of the root cells induced a powerful increase of the superoxide release. Data obtained indicate that superoxide generation is one of the early events of the wound stress response. Redox systems of the plasma membrane may be involved in the superoxide production in response to wound stress and detoxification of xenobiotic compounds in root cells.Abbreviations DPI diphenylene iodonium - MP membrane potential - superoxide anion radical - ROS reactive-oxygen species - SOD superoxide dismutase     

Plasma membrane redox systems in tumor cells

Summary Plasma membrane redox systems in tumor cells are analyzed, their role in proton flux and tumor cell growth is described, and the modulation of their activity by antitumor drugs and growth factors is presented. As an example of the evolution of studies in the characterization of plasma membrane redox systems in tumor cells, we summarized our own results on the model system Ehrlich ascites carcinoma.     

The NADH oxidizing system of the plasma membrane and metabolic signal control

Summary The development of ideas concerning plasma membrane redox reactions in normal and transformed animal cells is described, with emphasis on transferrin and ceruloplasmin. Control by hormones and growth factors, as well as the NAD⁺/NADH ratio in the cell are important in distinguishing the two types of cells.     

Plasma membrane redox system during HL-60 induced differentiation

Summary HL-60 cells were induced to differentiate by exposure to TPA or 1,25-dihydroxyvitamin D₃ (calcitriol). Induction with TPA was in parallel with a modulation of transmembrane redox system. After addition of 2 ng/m1 TPA, transient increases in ferricyanide reductase activity, NAD(H) intracellular levels and short-term response of NAD(H) to 0.4 mM ferricyanide were observed. The role of ascorbate on the differentiation induced by calcitriol also was studied. When HL-60 cells were exposed to 10^–8 M calcitriol in the presence of 0.2 mM ascorbate, specific differentiation markers as NBT reduction or surface antigen CD11b increased significantly with respect to values obtained from treatments with calcitriol alone.     

A hypothesis for the minimal overall structure of the mammalian plasma membrane redox system

Summary.  After a long period of frustration, many components of the mammalian plasma membrane redox system are now being identified at the molecular level. Some are apparently ubiquitous but are necessary only for a subset of electron donors or acceptors; some are present only in certain cell types; some appear to be associated with proton extrusion; some appear to be capable of superoxide production. The volume and variety of data now available have begun to allow the formulation of tentative models for the overall network of interactions of enzymes and substrates that together make up the plasma membrane redox system. Such a model is presented here. The structure discussed here is of the mammalian system, though parts of it may apply more or less accurately to fungal and plant cells too. Judging from the history of mitochondrial oxidative phosphorylation, it may be hoped that the development of models of the whole system – even if they undergo substantial revision thereafter – will markedly accelerate the pace of research in plasma membrane redox, by providing a coherent basis for the design of future experiments. Received May 4, 2002; accepted July 26, 2002; published online May 21, 2003 RID="*" ID="*" Correspondence and reprints: Department of Genetics, University of Cambridge, Downing Street, Cambridge CB2 3EH, United Kingdom. E-mail: ag24@gen.cam.ac.uk     

Cyclic AMP induces the synthesis of developmentally regulated plasma membrane proteins in Dictyostelium

Dictyostelium discoideum slugs (pseudoplasmodia) were disaggregated and the resynthesis of developmentally regulated plasma membrane proteins examined. The synthesis of the majority of these proteins was inhibited when cells were overlaid with Cellophane and maintained as a monolayer. However, cell contact and movement did occur under the Cellophane. The inhibition of differentiation may result from the inability of the cells to organise specifically into multicellular aggregates. The addition of cyclic AMP (1–5 mM) induced the synthesis of certain developmentally regulated plasma membrane proteins in cells overlaid with Cellophane. Hence, this confirms other work showing that cyclic AMP is required for at least some post-aggregative gene expression. Specific cell organisation and interactions are apparently required for an increase in or maintenance of intracellular cyclic AMP levels.     

Effect of osmotic shock on the redox system in plasma membrane of Dunaliella salina

The unicellular halotolerant alga Dunaliella salina had the ability to oxidize NADH and reduce Fe(CN)6^3-.The redox reactions were to some extent stimulated by slight hyperosmotic shock (2.0mol/L→2.6mol/L NaCl),but markably inhibited by abrupt hyperosmotic shock (2.0mol/L→3.5mol/L NaCl) and hypoosmotic shock (2.0mol/L→1.0mol/L NaCl;2.0mol/L→0.67mol/L NaCl).With the adaptation of algal cells to osmotic shock by accumulating or degraging intracellular grycerol,the plasmalemma redox activities were also restored.The O2 uptake stimulated by NADH could be promoted by FA and SHAM.Hypoosmotic shock increases the basal respiration rate of alga cells,but weakened the stimulating effects of NADH,FA and SHAM on O2 uptake.On the other hand,hyperosmotic shock reduced the basal respiration rate,but relatively enhanced the above effects of NADH,FA and SHAM.H^ extrusion of alga cells was inhibited by NADH and stimulated by Fe(CN)6^3-.Vanadate and DES could inhibit H^ efflux,but had little effect in the presence of NADH and Fe(CN)6^3-.Both hyperand hypoosmotic shock stimulated H^ extrusion.This effect could be totally inhibited by vanadate and DES,but almost unaffected by 8-hydroxyquinoline.It was suggested that H^ -ATPase probably played a more important role in H^ extrusion and osmoregulation under the conditions of osmotic shock.     

Blue light effects on stomata are mediated by the guard cell plasma membrane redox system distinct from the proton translocating ATPase

Abstract. The effects of blue light on stomata are critically analysed. Blue-light-induced increase in stomatal conductance is preceded by membrane hyperpolarization, proton efflux, potassium uptake and malate synthesis in guard cells. Hypothetically, a flavin containing plasma membrane redox system can pump protons out of guard cells on illumination with blue light. It is proposed that this electrogenic proton pump requires NAD(P)H but does not involve ATP/ATPase.     

Iron at the cell surface controls both DNA synthesis and plasma membrane redox system

Summary Addition of the impermeable iron II chelator bathophenanthroline disulfonate (BPS) to cultured Chinese hamster lung fibroblast (CCL 39 cells) inhibits DNA synthesis but not protein synthesis or cytoplasmic alkalinization, when cell growth is initiated with growth factors such as EGF plus insulin, thrombin, or ceruloplasmin. The BPS inhibition is reversed by addition of stoichiometric ferrous iron at stoichiometric concentration. BPS does not inhibit cell growth stimulated by fetal calf serum. The effect of the BPS differs from the inhibition of growth by hydroxyurea which acts on the ribonucleotide reductase. The BPS treatment leads to release of iron from the cells as determined by BPS iron II complex formation over 90 min. Cells treated with BPS just during starvation period cannot re-initiate DNA synthesis after mitogen stimulation even if BPS is removed from the medium and cells are previously washed. BPS treatment also inhibits transplasma membrane electron which is restored by incubation of cells with 10 M ferric ammonium citrate. Growth factor stimulation of DNA synthesis is restored by addition of 1 M ferrous ammonium sulfate or ferric ammonium citrate, or 0.1 M diferric transferrin. Copper, cobalt, nickel, zinc, gallium, aluminum, or apotransferrin cannot restore the activity. The BPS effect is consistent with removal of iron from a site on the cell surface which controls electron transport and DNA synthesis.Abbreviations BCS bathocuproine disulfonate - BPS bathophenan-throline disulfonate - CUP ceruloplasmin - FCS fetal calf serum - Fe₂Tf diferric transferrin - EGF epidermal growth factor - HU hydroxyurea - THR -thrombin     

Stimulation of onion root elongation by ascorbate and ascorbate free radical inAllium cepa L.

Summary We report that ascorbate free radical stimulates onion root growth at 15 °C and 25 °C. The fully reduced form, ascorbate, also stimulates root elongation if culture conditions allow its oxidation. When ascorbate oxidation was inhibited, no stimulation of root growth was found. The effect of the fully oxidized form, dehydroascorbate, was inhibitory. We show also that ascorbate free radical generated by ascorbate oxidation, is reduced back probably by a transplasmalemma reductase. These results are discussed on the basis of an activation of a transplasma membrane redox system likely involved in processes related to cell growth.Abbreviations AFR ascorbate free radical - ASC ascorbate - DHA dehydroascorbate     

Ehrlich cell plasma membrane redox system is modulated through signal transduction pathways involvingcGMP and Ca2+ as second messengers

Ehrlich cell plasma membrane ferricyanide reductase activity increased in the presence of mastoparan, a generic activator of G proteins, using either whole cells or isolated plasma membrane fractions. Agents that increase intracellularcAMP also increased the rate of ferricyanide reduction by Ehrlich cells. For the first time, evidence is shown on a modulation of plasma membrane redox system bycGMP. In fact, permeant analogs ofcGMP, dibutyrylcGMP, and 8-bromo-cGMP increased the rate of ferricyanide reduction by the Ehrlich cell plasma membrane redox system. Furthermore, specific inhibition ofcGMP-phosphodiesterases by dipyridamole was also accompanied by an enhancement in the rate of ferricyanide reduction. On the other hand, treatments expected to increase cytoplasmic Ca²⁺ concentrations were accompanied by a remarkable stimulation of the reductase activity. Taking all these data together, it seems that the Ehrlich cell plasma membrane redox system is under a multiple and complex regulation by different signal transduction pathways involving G proteins, cyclic nucleotides, and Ca²⁺ ions.     

Nucleotide sequence of a yeast tRNAArg3A gene and its transcription in a homologous in vitro system

Neutrophil homogenates contained a high affinity guanosine triphosphatase (GTPase) that was stimulatable (+27%) by the addition of 100 nM N-formyl chemotactic peptide (CHO-pep), but not by 1 microgram X ml-1 phorbolmyristate acetate (PMA). Kinetic analysis of the stimulation demonstrated an apparent lagtime of 14.3 +/- 6.9 s between the addition of CHO-pep and the optimal GTPase stimulation. The GTPase activity (but not CHO-pep-stimulated GTPase activity) was preserved in a highly purified plasma membrane fraction of the homogenate. From these observations we suggest that both a high affinity guanine nucleotide binding protein and GTPase are closely associated with the plasma membrane CHO-pep receptor. The possibility that GTPase activity may influence guanine nucleotide regulation of adenylate cyclase during CHO-pep stimulation of neutrophils is discussed.     

Characterization of the cyclic 3′,5′-nucleotide phosphodiesterase activity associated with synaptosomal plasma membranes and synaptic junctions

Some characteristics of the cyclic 3′,5′-nucleotide phosphodiesterase (phosphodiesterase) activity associated with the synaptosomal plasma membrane (synaptic membrane) and the synaptic junction fractions of rat brain are reported. Kinetic analysis revealed that only one type of phosphodiesterase activity, with a K_m of 2 · 10^?4 M for cyclic AMP, is associated with both fractions. The specific activities of the phosphodiesterase in synaptic membranes and synaptic junctions have been estimated at 23.4 nmol/min per mg protein and 22.5 nmol/min per mg protein, respectively. The synaptic junction-associated activity undergoes a 30% stimulation by Ca²⁺ while no Ca²⁺ sensitivity of the synaptic membrane-associated activity could be detected. Cytochemical studies performed on the synaptic membrane fraction demonstrated a predominant localization of phosphodiesterase activity over postsynaptic densities, while dense deposits were sometimes observed over the synaptic cleft region.     

Compromising the plasma membrane as a secondary target in photodynamic therapy-induced necrosis

Photodynamic therapy (PDT) is a non-invasive treatment widely applied to different cancers. The goal of PDT is the photo-induced destruction of cancer cells by the activation of different cell death mechanisms, including apoptosis and/or necrosis. Recent efforts focusing on understanding the mechanisms of cell death activated by PDT find that it depends on the type of photosensitizer (PS), targeted organelles, and nature of the light used. It is generally accepted that very short incubation times are required to direct the PS to the plasma membrane (PM), while longer periods result in the accumulation of the PS in internal compartments such as the endoplasmic reticulum or mitochondria. Glycosylation of the PS targets cancer via saccharide receptors on the cell surface, and is generally assumed that these compounds rapidly internalize and accumulate, e.g. in the endoplasmic reticulum. Herein we demonstrate that a minor fraction of a glycosylated chlorin compound residing at the PM of cancer cells can activate necrosis upon illumination by compromising the PM independently of the length of the incubation period. The results presented here show that the PM can also be targeted by glycosylated PS designed to accumulate in internal organelles. PS activation to induce necrosis by compromising the plasma membrane has the benefits of fast cell death and shorter irradiation times. The findings described here expand our understanding of the cellular damage induced by phototherapies, presenting the possibility of activating another cell death mechanism based on the incubation time and type of light used.     

A link between transport and plasma membrane redox system(s) in carrot cells

Carrot (Daucus carota L.) cells grown in suspension culture oxidized exogeneous NADH. The NADH oxidation was able to stimulate K⁺ (⁸⁶Rb⁺) transport into cells, but it did not affect sucrose transport.N,N'-Dicyclohexyl-carbodiimide, diethylstilbestrol, and oligomycin, which only partially inhibited NADH oxidation, almost completely collapsed the K⁺ (⁸⁶Rb⁺) transport. Vanadate, which is less effective as an ion transport inhibitor, was less effective in inhibiting the NADH-driven transport of K⁺ (⁸⁶Rb⁺).p-Fluormethoxycarbonylcyanide phenylhydrazone inhibits the K⁺ transport over 90% including that induced by NADH. The results are interpreted as evidence that a plasma membrane redox system in root cells is closely associated with the ATPase which can drive K⁺ transport. Because of the inhibitor effects, it appears that membrane components common to the redox system and ATPase function in the transport of K⁺.     

Homocysteine is a potent modulator of plasma membrane electron transport systems

The deregulation of homocysteine metabolism leads to hyperhomocysteinemia, a condition described as an independent cardiovascular disease risk factor. Ubiquitous plasma membrane redox systems can play a dual pro-oxidant and anti-oxidant role in defense. In this study, we test the hypothesis that homocysteine, as a redox active compound, could modulate the endothelial plasma membrane redox system. We show that homocysteine behaves as a very potent stimulator of this activity. Furthermore, we show that this inducing effect is also produced on tumor cells and that it can be observed at both the activity and protein levels. On the other hand, homocysteine treatment decreases the activity of the specific ectocellular tumor NADH oxidase. Taken together, these results underscore a potential antitumoral action of homocysteine.     

Up-regulation of plasma membrane-associated redox activities in neuronal cells lacking functional mitochondria

Mitochondria-deficient cells (rho(o) cells) survive through enhanced glycolytic metabolism in the presence of pyruvate and uridine. The plasma membrane redox system (PMRS) contains several NAD(P)H-related enzymes and plays a key role in maintaining the levels of NAD(+)/NADH and reduced coenzyme Q. In this study, rho(o) cells were used to investigate how the PMRS is regulated under conditions of mitochondrial dysfunction. rho(o) cells exhibited a lower oxygen consumption rate and higher levels of lactate than parental cells, and were more sensitive to glycolysis inhibitors (2-deoxyglucose and iodoacetamide) than control cells. However, they were more resistant to H(2)O(2), consistent with increased catalase activity and decreased oxidative damage (protein carbonyls and nitrotyrosine). PM-associated redox enzyme activities were enhanced in rho(o) cells compared to those in control cells. Our data suggest that all PMRS enzymes and biomarkers tested are closely related to the ability of the PMs to maintain redox homeostasis. These results illustrate that an up-regulated PM redox activity can protect cells from oxidative stress as a result of an improved antioxidant capacity, and suggest a mechanism by which neurons adapt to conditions of impaired mitochondrial function.