The oxidation of extracellular NADH by sugarcane cells: Coupling to ferricyanide reduction,oxygen uptake and pH change

Suspension-cultured cells of sugarcane (Saccharum sp. hybrids) did not oxidize exogenously supplied NADH in the absence of ferricyanide (potassium hexacyanoferrate [III]), whereas they did at a low rate in the presence of ferricyanide. Concomitantly, ferricyanide was reduced at a slow rate. Neither a pH change nor a change in respiration was caused by the addition of NADH and-or ferricyanide, but ferricyanide was a strong inhibitor of sugar transport. In contrast to cells, protoplasts rapidly oxidized exogenous NADH. This oxidation was accompanied by an increase in oxygen consumption and a net proton disappearance from the medium. Exogenous ferricyanide was reduced only slowly by protoplasts. Simultaneous presence of NADH and ferricyanide produced two effects: 1) a very rapid stoichiometric oxidation of NADH and reduction of ferricyanide until one of the reaction compounds was exhausted, and 2) a nearly instantaneous inhibition of the slower phase of NADH oxidation, which was observed in the presence of NADH but absence of ferricyanide. The extra oxygen consumption and the alkalinization of the medium, as observed with NADH, were also immediately stopped by ferric ions and ferrous ions. The presence of NADH and ferricyanide caused a fast stoichiometric acidification of the medium. These results were taken as evidence that the oxidation of NADH in the absence of ferricyanide is not related to the NADH-ferricyanide-coupled redox reaction. Furthermore, addition of NADH caused some uncoupling of the protoplasts, an effect which would explain the strong acidification of the cell cytoplasm and the inhibition of various transport systems. The NADH-oxidizing systems oxidized both the -configurated pyridine nucleotide and the -configurated form. Since NADH-linked dehydrogenases usually do not work with -NADH (with the exception of the endoplasmic-reticulum-bound electron-transport system), the observed activities could have been derived from contaminating membranes and dying protoplasts in the suspension. All reported reactions partly or predominantly occurred in the supernatant of the protoplast suspension and increased considerably during incubation of the protoplasts. The rates and quantities of oxygen consumption, pH change, and ferricyanide reduction fitted with NADH oxidation in a stoichiometric ratio, which implied that all these reactions occurred in the extracellular space, without involving transmembrane steps. No evidence for a physiological role in energization of the plasmalemma was found.Abbreviation NADH -nicotinamide adenine dinucleotide reduced form     

Electron transport across the plasmalemma of Lemna gibba G1

Lemna gibba L., grown in the presence or absence of Fe, reduced extracellular ferricyanide with a V _max of 3.09 mol · g^-1 fresh weight · h^-1 and a K _m of 115 M. However, Fe³⁺-ethylenediaminetetraacetic acid (EDTA) was reduced only after Fe-starvation. External electron acceptors such as ferricyanide, Fe³⁺-EDTA, 2,6-dichlorophenol indophenol or methylene blue induced a membrane depolarization of up to 100 mV, but electron donors such as ferrocyanide or NADH had no effect. Light or glucose enhanced ferricyanide reduction while the concomitant membrane depolarization was much smaller. Under anaerobic conditions, ferricyanide had no effect on electrical membrane potential difference (E_m). Ferricyanide reduction induced H⁺ and K⁺ release in a ratio of 1.16 H⁺+1 K⁺/2 e^- (in +Fe plants) and 1.28 H⁺+0.8 K⁺/2 e^- (in -Fe plants). Anion uptake was inhibited by ferricyanide reduction. It is concluded that the steady-state transfer of electrons and protons proceeds by separate mechanisms, by a redox system and by a H⁺-ATPase.Abbreviations E _m electrical membrane potential difference - EDTA ethylenediaminetetraacetic acid - DCPIP dichlorophenol indophenol - +Fe control plant - -Fe iron-deficient plant - FW fresh weight - H⁺ electrochemical proton gradient     

Ferricyanide reductase of rose plasma membranes is regulated by nitrogen supply

Summary The ability of suspension-cultured rose (Rosa damascena Mill. cv Gloire de Guilan) cells to reduce ferricyanide is decreased by 50% during an overnight incubation in a low-nutrient (1 mM CaCl₂, 0.1 mM KCl) solution. This loss is not observed when nitrate and/or glutamate is added to the low-nutrient medium, but it occurs in medium containing all the components needed for normal growth except nitrate plus glutamate. Thus, the cells possess both constitutive and inducible enzymes for the reduction of ferricyanide, and nitrate or glutamate is both necessary and sufficient to stimulate the production of the inducible enzyme.     

Human red blood cells as a natural flavonoid reservoir

Quercetin is rapidly and avidly taken up by human red blood cells (RBC) via a passive diffusion mechanism, driven by flavonoid binding to haemoglobin and resulting in an almost quantitative accumulation of the flavonoid. Heamoglobin-free resealed ghosts accumulated quercetin exclusively in the membrane fraction. Cell-associated quercetin was biological active and could be quantitatively utilised to support the reduction of extracellular oxidants mediated by a transplasma-membrane oxido-reductase. Additional experimental evidence revealed that quercetin uptake declined in the presence of albumin and that, under these conditions, the amount of cell-associated quercetin is enhanced by increasing the RBC number. Quercetin release from flavonoid-preloaded RBC was observed only in the presence of albumin (or in human plasma) and this response was progressively inhibited upon incubation in solutions containing albumin previously exposed to increasing concentrations of quercetin and cleared of the unbound fraction of the flavonoid. Furthermore, exposure to quercetin pre-saturated albumin promoted accumulation of the flavonoid in fresh RBC and this response was a direct function of the extent of albumin saturation. These results, indicating a flow of quercetin from albumin to haemoglobin, and vice versa, are therefore consistent with the possibility that human RBC play a pivotal role in the distribution and bioavailability of circulating flavonoids.     

Iron limitation results in induction of ferricyanide reductase and ferric chelate reductase activities in Chlamydomonas reinhardtii

The green alga Chlamydomonas reinhardtii Dangeard CW-15 exhibited very low rates of plasma-membrane Fe(III) reductase activity when grown under Fe-sufficient conditions. After switching the medium to an Fe-free formulation, both ferricyanide reductase and ferric chelate reductase activities rapidly increased, reaching a maximum after 3 d under iron-free conditions. Both of the Fe(III) reductase activities increased in parallel over time, they exhibited similar K _m values (approximately 10 μM) with respect to Fe(III), displayed the same pH profile of activity, and both exhibited the same degree of light stimulation which could be inhibited by 3-(3′,4′-dichlorophenyl)-1,1-dimethylurea (DCMU). Furthermore, ferricyanide competitively inhibited ferric chelate reduction by iron-limited cells. These results indicate that both Fe(III) reductase activities were mediated by the same iron-limitation-induced plasma-membrane reductase. No evidence was found for the presence of Fe(III)-reducing substances in the culture medium, or for the involvement of active oxygen species in the process of Fe(III) reduction. Chlamydomonas reinhardtii appears to respond to iron limitation in a manner similar to Strategy I higher plants. Received: 24 June 1997 / Accepted: 2 August 1997     

Self-assembly of three hetero- and homopolynuclear cyanide bridged complexes of Fe-Cu and Cu: hydrothermal syntheses, structural characterization and properties

Reaction of Cu^II, K₃ [Fe(CN)₆] and bidentate diimine ligands by hydrothermal synthesis under different conditions affords one novel heteronuclear Fe^II-Cu^I complex, (bipy = 2,2′-bipyridine), and two homonuclear Cu^I complexes, [Cu^I(μ-CN)(bipy)]_n (2) and (3) (phen = 1,10-phenanthroline). Although all the three complexes are 1D cyanide bridged helical chains, they have different helicoids of pseudo-square, pseudo-trigonal and head-to-head bistrigonal for 1, 2 and 3, respectively. The structure of 1 is extended to 2D hexagonal meshed layers by the hydrogen bonding between terminal cyanides and lattice water molecules, which also contain π-π interactions between adjacent sheets. Cu^I ions in 1 are distorted trigonal planar coordinated by two bridging cyanides and one terminal cyanide, whereas that in 2 and 3 are pseudo-tetrahedral coordinated by two bridging cyanides and two N atoms of a diimine. Both the latter homometallic polymers exhibit similar chain structure, and these chains are close packed with their six adjacent chains in a parallel fashion along the c-axis to form a honeycomb network. It should be noted that complex 1 is the first cyanide bridged Fe^II-Cu^I complex of helical chain structure. The spectroscopic properties of complexes 1-3 have also been investigated.     

A method for in-gel fluorescent visualization of proteins after native and sodium dodecyl sulfate polyacrylamide gel electrophoresis

We have developed a simple one-step 30-min method for fluorescent visualization of proteins in native and sodium dodecyl sulfate polyacrylamide gel electrophoresis (PAGE) gels. The method is based on formation of strong fluorophores via potassium ferricyanide-provoked oxidation of tryptophan (Trp). Following PAGE, gels are soaked in water solution of potassium ferricyanide (100 mM) and NaOH (1 M) and are kept in the dark for 30 min. Gels are then transferred to water and scanned. The sensitivity of the method was slightly lower compared with standard Coomassie Brilliant Blue (CBB) staining. The method can be useful when rapid acquisition of data is of the essence. After preview, gels can be post-stained using the CBB protocol for further analysis. The intensity of fluorescence is dependent on Trp number, so the protocol might find application in the quantification of Trp residues as illustrated here. Importantly, there is room for improvement of the method. Namely, according to excitation–emission matrix analysis of stained protein bands, maximal fluorescence intensity (at 345/460 nm) was 3.5-fold higher compared with the settings that were available on a commercial imager (395/525 nm). As a supplement, we present an upgrade of the previously described method for in-gel detection of non-heme iron-binding proteins that also employs potassium ferricyanide.     

A highly sensitive colorimetric microplate ferrocyanide assay applied to ascorbate-stimulated transplasma membrane ferricyanide reduction and mitochondrial succinate oxidation

Ferricyanide reduction frequently is analyzed to determine the activity of membraneous reductases. An improved, highly sensitive, and rapid method for quantitative endpoint determination of ferrocyanide is presented. Ferrocyanide is oxidized by Fe(3+) in the presence of Ferene-S under acid conditions to form a chromogenic Ferene-S/Fe(2+) complex. The latter is quantitated at 593 nm with a sensitivity of 33.2 mM(-1) . cm(-1). The assay is 60% more sensitive to ferrocyanide (and with a 50% lower detection limit) than the prevailing method of Avron and Shavit, which employs sulfonated bathophenanthroline as the ferrous chromogen. Both pH dependence and potential sources of interference are discussed. Using the method, a sulfhydryl-sensitive, ascorbate-stimulated transplasma membrane ferricyanide reductase was assayed in human chronic myeloid (K562) leukemia cells. Furthermore, malonate-sensitive succinate dehydrogenase activity of heart mitochondria was easily assayed with ferricyanide as terminal electron acceptor. The current method will suit routine applications demanding high throughput, robustness, and sensitivity in a 96-well plate format.