Rita Barr

A growth factor- and hormone-stimulated NADH oxidase from rat liver plasma membrane

NADH oxidase activity (electron transfer from NADH to molecular oxygen) of plasma membranes purified from rat liver was characterized by a cyanide-insensitive rate of 1 to 5 nmol/min per mg protein. The activity was stimulated by growth factors (diferric transferrin and epidermal growth factor) and hormones (insulin and pituitary extract) 2- to 3-fold. In contrast, NADH oxidase was inhibited up to 80% by several agents known to inhibit growth or induce differentiation (retinoic acid, calcitriol, and the monosialoganglioside, GM3). The growth factor-responsive NADH oxidase of isolated plasma membranes was not inhibited by common inhibitors of oxidoreductases of endoplasmic reticulum or mitochondria. As well, NADH oxidase of the plasma membrane was stimulated by concentrations of detergents which strongly inhibited mitochondrial NADH oxidases and by lysolipids or fatty acids. Growth factor-responsive NADH oxidase, however, was inhibited greater than 90% by chloroquine and quinone analogues. Addition of coenzyme Q10 stimulated the activity and partially reversed the analogue inhibition. The pH optimum for NADH oxidase was 7.0 both in the absence and presence of growth factors. The Km for NADH was 5 microM and was increased in the presence of growth factors. The stoichiometry of the electron transfer reaction from NADH to oxygen was 2 to 1, indicating a 2 electron transfer. NADH oxidase was separated from NADH-ferricyanide reductase, also present at the plasma membrane, by ion exchange chromatography. Taken together, the evidence suggests that NADH oxidase of the plasma membrane is a unique oxidoreductase and may be important to the regulation of cell growth.

Electron and proton transport across the plasma membrane

Transplasma membrane electron transport in both plant and animal cells activates proton release. The nature and components of the electron transport system and the mechanism by which proton release is activated remains to be discovered. Reduced pyridine nucleotides are substrates for the plasma membrane dehydrogenases. Both plant and animal membranes have unusual cyanide-insensitive oxidases so oxygen can be the natural electron acceptor. Natural ferric chelates or ferric transferrin can also act as electron acceptors. Artificial, impermeable oxidants such as ferricyanide are used to probe the activity. Since plasma membranes containb cytochromes, flavin, iron, and quinones, components for electron transport are present but their participation, except for quinone, has not been demonstrated. Stimulation of electron transport with impermeable oxidants and hormones activates proton release from cells. In plants the electron transport and proton release is stimulated by red or blue light. Inhibitors of electron transport, such as certain antitumor drugs, inhibit proton release. With animal cells the high ratio of protons released to electrons transferred, stimulation of proton release by sodium ions, and inhibition by amilorides indicates that electron transport activates the Na+/H+ antiport. In plants part of the proton release can be achieved by activation of the H+ ATPase. A contribution to proton transfer by protonated electron carriers in the membrane has not been eliminated. In some cells transmembrane electron transport has been shown to cause cytoplasmic pH changes or to stimulate protein kinases which may be the basis for activation of proton channels in the membrane. The redox-induced proton release causes internal and external pH changes which can be related to stimulation of animal and plant cell growth by external, impermeable oxidants or by oxygen.

Redox reactions of plasma membranes isolated from soybean hypocotyls by phase partition

Ninety-five percent pure plasma membranes were isolated from the microsomal fraction of soybean hypocotyls (Glycine max L. Merr. cv. Wayne) by phase partition in an aqueous polymer system. It was found that isolated plasma membranes could reduce ferricyanide, cytochrome c or various iron complexes with NADH as an electron donor. The rates of these reactions varied from 300 nmol (mg protein)−1 min−1 for NADH-ferricyanide reductase to 21 nmol (mg protein)−1 min−1 for NADH-cytochrome c reductase. The flavin content on these membranes was 2.4 nmol flavin/mg protein. The membranes also showed evidence of a b-type cytochrome in the oxidized minus reduced difference spectrum (λmax 561 nm) upon addition of dithionite. The Soret band peak for this b-type cytochrome was at 428 nm in the difference spectrum. The cytochrome content of the isolated plasma membranes was 0.5 nmol/mg protein. The reductase activity of plasma membranes isolated from soybean hypocotyls by two-phase partition was stimulated from 88 to 175% by low concentrations of Triton X-100. The reductase reactions in these membranes were inhibited from 33 to 83% by several nucleotides, manganese and zinc ions, p-chloromercuribenzene sulfonate (PCMBS) and 4-nitrophenyl acetate. These inhibitions were affected differently by Triton X-100 in the assay.

Calmodulin antagonists inhibit electron transport in photosystem II of spinach chloroplasts

Abstract Chlorpromazine, phenothiazine and trifluoperazine, known as calmodulin antagonists, inhibit electron transport in Photosystem II of spinach chloroplasts in concentrations from 20–500 μM. The inhibition site is located on the diphenyl carbazide to indophenol pathway in Tris-treated chloroplasts, indicating that water oxidation is not affected by these drugs. Ca 2+ ions, bound to chloroplast membranes before the addition of calmodulin antagonists, can protect against inhibition up to 25% of the electron transport rate. In presence of A23187, the Ca 2+ -specific ionophore, Ca 2+ ions provide less protection against inhibition by the 3 calmodulin antagonists used. A possible role of a calmodulin-like protein in spinach chloroplasts is postulated.

Transmembrane ferricyanide reduction in carrot cells

Carrot cells (Daucus carota) grown in tissue culture are capable of reducing the non-permeable electron acceptor, ferricyanide, with concomitant proton extrusion from the cell. Optimum conditions for transmembrane ferricyanide reduction include a pH of 7.0-7.5 in a medium containing 10 mM each KCl, NaCl and CaCl2. Data are shown to prove that transmembrane ferricyanide reduction is an enzymatic process. It does not depend on the secretion of phenolics from the cell within the time limits of the assay (10 min). The presence of broken cells and cell fragments are excluded on the basis of stimulation or only slight inhibition by mitochondrial inhibitors. However, transmembrane ferricyanide reduction by carrot cells is inhibited about 50% by various glycolysis inhibitors, which are presumed to reduce the internal levels of NADH. Treatment of cells with p-diazoniumbenzenesulfonic acid, a non-permeant membrane modifying agent, also inhibits transmembrane ferricyanide reduction more than 90%. The data presented support the existence of a transplasma membrane redox system in carrot cells.

Redox reactions of tonoplast and plasma membranes isolated from soybean hypocotyls by free-flow electrophoresis.

Redox reactions were studied in more than 90% pure tonoplast and plasma membranes isolated by free-flow electrophoresis from soybean (Glycine max) hypocotyls. Both types of membrane contained a b-type cytochrome (alpha max = 561 nm) and a noncovalently bound flavin, two possible components of a transmembrane electron-transport chain. Isolated tonoplast and plasma membranes reduced ferricyanide, indophenol and various iron complexes with NADH or NADPH as electron donors. The redox activity was inhibited in tonoplast membranes by about 60% by 10 microM p-chloromercuribenzene sulfonate, 8% by 500 microM lanthanum nitrate and 10% by 100 microM nitrophenyl acetate. In contrast, the redox activity of isolated plasma membranes was inhibited by about 60% by 500 microM lanthanum nitrate or 100 microM nitrophenyl acetate, but only 25% by 10 microM p-chloromercuribenzene sulfonate. The results show that both tonoplast and plasma membranes of soybean contain active electron-transport systems, but that the two systems respond differently to inhibitors.

Photophosphorylation not coupled to DCMU-insensitive photosystem II oxygen evolution

Summary An abbreviated Photosystem II electron transport sequence from water to silicomolybdate plus ferricyanide functions in the presence of DCMU. This electron transfer was not coupled to photophosphorylation, and therefore places phosphorylation associated with Photosystem II (Site II) after the site of DCMU inhibition. Silicomolybdate per se was not inhibitory to phosphorylation in either the cyclic or noncyclic (water to methylviologen) electron transport mode.

NADH OXIDASE ACTIVITY PRESENT ON BOTH THE EXTERNAL AND INTERNAL SURFACES OF SOYBEAN PLASMA MEMBRANES

Abstract Soybean plasma membranes exhibit NADH oxidase activities accessible to NADH supplied to either the external or internal membrane surfaces. Activity at the external surface was demonstrated using plasma membranes of right side-out orientation prepared by aqueous two-phase partition and using intact soybean cells grown in culture. Activity at the internal membrane surface was demonstrated using vesicles of inside-out orientation obtained by preparative free-flow electrophoresis or by aqueous two-phase partition following freeze–thaw or Brij detergent treatment to invert some of the right side-out vesicles. The NADH oxidase activity of both membrane surfaces appeared to be stimulated by the synthetic auxin 2,4-dichlorophenoxyacetic acid (2,4-D). Following the freeze–thaw treatment utilized to evert the vesicles, however, the NADH oxidase activity of right side-out vesicles was greatly reduced. A 2,4-D-stimulated activity of these vesicles could be restored by treatment first with reduced glutathione and then with hydrogen peroxide or oxidized glutathione. Upon treatment with 0.1% Triton X-100, both right side-out and inside-out vesicles exhibited approximately the same specific activity and the same 2,4-D-stimulated component of activity equal to the sum of the activities of the right side-out and inside-out vesicles assayed separately. These findings suggest that a significant NADH oxidase activity of the soybean plasma membrane responsive to 2,4-D resides on the external plasma membrane surface. This latter activity is unlikely to function under physiological conditions in the direct oxidation of NADH and alternative functions, such as in protein disulfide–thiol interchange, would be more appropriate.

Plasma membrane oxidoreductases

Physiological roles have been proposed for several of these enzymes which include a hormone controlled transmembrane WADH oxidase, an iron chelate reductase, nitrate reductase, cyt b 5 reductase and peroxidase. The auxin stimulated oxidase has been proposed to be involved in control of cell elongation or proliferation and the iron chelate reductase in iron uptake. The peroxidase may be important in defense against pathogens

The plasma membrane NADH oxidase of soybean has vitamin K1 hydroquinone oxidase activity

Isolated plasma membrane vesicles and the plasma membrane NADH oxidase partially purified from soybean plasma membrane vesicles exhibited a cyanide-insensitive vitamin K(1) hydroquinone oxidase activity with isolated plasma membrane vesicles. Reduced vitamin K(1) (phylloquinol) was oxidized at a rate of about 10 nmol/min/mg protein as determined by reduced vitamin K(1) reduction or oxygen consumption. The K(m) for reduced K(1) was 350 microM. With the partially purified enzyme, reduced vitamin K(1) was oxidized at a rate of about 600 nmol/min/mg protein and the K(m) was 400 microM. When assayed in the presence of 1 mM KCN, activities of both plasma membrane vesicles and of the purified protein were stimulated (0.1 microM) or inhibited (0.1 mM) by the synthetic auxin growth factor 2, 4-dichlorophenoxyacetic acid. The findings suggest the potential participation of the plasma membrane NADH oxidase as a terminal oxidase of plasma membrane electron transport from cytosolic NAD(P)H via reduced vitamin K(1) to acceptors (molecular oxygen or protein disulfides) at the cell surface.