Inhibitors of the plasma membrane redox system of Zea mays L. roots. The vitamin K antagonists dicumarol and warfarin.

The action of the 4-hydroxycoumarins dicumarol and warfarin, antagonists of probable vitamin K type components of the plasma membrane electron-transport system, on plasma membrane redox activity of intact maize roots was compared. Both effectors inhibited electron transfer to extracellular hexacyanoferrate III. While the effect of the strongly lipophilic dicumarol on the electron-transport system was irreversible by rinsing, the inhibition caused by the hydrophilic warfarin could be reverted completely by exchange of the incubation medium. We take these results as possible evidence for the integration of dicumarol into the plasma membrane. The action of warfarin may be confined to enzymic sites freely accessible from the aqueous apoplasmic solution.

Oxidoreductases in plant plasma membranes.

Electron transporting oxidoreductases at biological membranes mediate several physiological processes. While such activities are well known and widely accepted as physiologically significant for other biological membranes, oxidoreductase activities found at the plasma membrane of plants are still being neglected. The ubiquity of the oxidoreductases in the plasma membrane suggests that the activity observed is of major importance in fact up to now no plant without redox activity at the plasmalemma is known. Involvement in proton pumping, membrane energization, ion channel regulation, iron reduction, nutrient uptake, signal transduction, and growth regulation has been proposed. However, positive proof for one of the numerous theories about the physiological function of the system is still missing. Evidence for an involvement in signalling and regulation of growth and transport activities at the plasma membrane is strong, but the high activity of the system displayed in some experiments also suggests function in defense against pathogens.

Penetration by Artificial Electron Acceptors of the Plasma Membrane-Bound Redox System into Intact Zea mays L. Roots Investigated by Proton-Induced X-Ray Emission.

Proton-induced x-ray emission was used to investigate the penetration of compounds of the membrane-impermeant electron acceptors hexabromoiridate IV, hexachloroiridate IV, and hexacyanoferrate III into corn (Zea mays L.) roots. Maps of the heavy element distribution in cross-sections of fixed, epoxy-embedded roots showed for hexabromoiridate IV small amounts of Br in samples treated for 24 h with concentrations normally used in physiological experiments (0.02 mM). After treatment with high concentrations (0.8 mM) of these complexes, Fe and Ir as well as Br were found in root cross-sections. In samples taken at a distance of 5 mm behind the root tip, we found an even distribution of Fe, Ir, and Br over the whole cross-section. In samples taken 15 mm behind the root tip, about 99% of both Br and Ir was confined to the rhizodermal cell layer. The distribution did not change with the complex used. These data are consistent with the view that apoplastic diffusion of the electron acceptors was blocked by the hypodermal Casparian band.

Phylloquinone, what can we learn from plants?

The plant plasma membrane contains redox proteins able to mediate a trans-membrane electron flow. This electron flow might be responsible for the generation of the active oxygen species observed as a reaction to pathogen attack or stress. Vitamin K1 could be identified as a possible lipid soluble electron carrier in plant plasma membrane preparations. Such a function would be analogous to coenzyme Q in animal plasma membranes. What we are going to outline in this contribution is a concept of how the electron transport system of the plant plasma membrane could interact with quinones, thus contributing to the metabolism of free radicals in plants.

[Is arthroscopy always justified in traumatic hemarthrosis of the knee joint?]. / Hat die Arthroskopie beim traumatischen Hämarthros des Kniegelenkes immer ihre Berechtigung?

Analysis of 100 consecutive arthroscopies in patients with traumatic hemarthrosis of the knee joint demonstrates the importance of arthroscopy in diagnosis and therapy. In 48 cases injuries of the anterior cruciate ligament, isolated and in combination with lesions of other structures, were found. In 47 cases an operation was necessary. In 21 cases the reason for the hemarthrosis was luxation of the patella, in 6 cases with a flake fracture. Isolated lesions of one of the menisci were found in 11 cases and treated arthroscopically in all cases (2 meniscopexies, 1 total meniscectomy , 8 partial meniscectomies). Only in 8 cases unimportant injuries or lesions were found to have caused the hemarthrosis.

Effect of D2O on maize plasmalemma ATPase and electron transport coupled proton pumping.

Heavy water (D2O) has been used as a putative inhibitor of the plasma membrane H(+)-ATPase and the plasma membrane redox system. Concentrations above 50% D2O inhibited H+ secretion and the plasma membrane redox system of Zea mays L. roots. Inhibition of H+ secretion by vanadate was reduced in presence of D2O. The plasma membrane of roots was transiently depolarized after the addition of heavy water in concentrations above 5%. The repolarization of the plasma membrane that takes place while the H+ secretion is still reduced by heavy water indicates that, despite the overall inhibiting effect of D2O, the plant is still able to regulate the membrane potential.

Molecular components and biochemistry of electron transport in plant plasma membranes (review).

It is worthwhile emphasizing the importance of electron transport across lipid membranes. Mitochondrial and electron transport in chloroplasts were elucidated in great detail many years ago. Plasma membrane-bound electron transfer may be involved in several processes such as membrane energization, signalling, regulation of transport and/or growth, and generation or scavenging of free radicals. We here give an overview of plasma membrane-bound electron transfer, of possible compounds of the electron transporting systems isolated from plasma membranes, and of their biochemical characteristics. Both the progress made in purification of redox enzymes and compounds and data from biochemical characterization of the activities found, support the discussion concerning models of the molecular structure of the electron transport systems of plant plasma membranes.

Inhibition of trans-membrane hexacyanoferrate III reductase activity and proton secretion of maize (Zea mays L.) roots by thenoyltrifluoroacetone.

Intact plants can reduce external oxidants by an appearingly trans-membrane electron transport. In vivo an increase in net medium acidification accompanies the reduction of the apoplastic substrate. Up to now, several NAD(P)H dehydrogenases, b-type cytochromes, and a phylloquinone have been identified and partially purified from plant plasma membranes. The occurrence of a quinone in the plasma membrane of maize roots supports the hypothetical model of a proton-transferring redox system, i.e., an electron transport chain with a quinone as mobile electron and proton carrier. In the present study the trans-membrane electron transport system of intact maize (Zea mays L.) roots was investigated. Flow-through and ionostat systems have been used to estimate the electron and proton transport activity of this material. Application of 4,4,4-trifluoro-1-(2-thienyl)-butane-1,3-dione (thenoyltrifluoroacetone) inhibited the reduction of ferricyanide in the incubation solution of intact maize roots up to 70%. This inhibition could not be washed off by rinsing the roots with fresh incubation medium. The acidification of the medium induced after ferricyanide application was inhibited to about 62%. The effects of thenoyltrifluoroacetone on proton fluxes in the absence of ferricyanide have been characterized in a pH-stat system. The net medium acidification by maize roots was inhibited up to 75% by thenoyltrifluoroacetone in the absence of ferricyanide, while dicumarol inhibited net acidification completely. The inhibition of H(+)-ATPase activity was estimated with plasma membrane vesicles isolated by phase partitioning and treated with 0.05% (w/v) Brij 58. ATP-dependent proton gradients and Pi release were measured after preincubation with the effectors. The proton pumping activity by those plasma membrane vesicles was inhibited by dicumarol (53.6%) and thenoyltrifluoroacctone (77.8%), while the release of Pi was unaffected by both inhibitors.

Interaction between electron transport at the plasma membrane and nitrate uptake by maize (Zea mays L.) roots.

In the present study nitrate uptake by maize (Zea mays L.) roots was investigated in the presence or absence of ferricyanide (hexacyanoferrate III) or dicumarol. Nitrate uptake caused an alkalization of the medium. Nitrate uptake of intact maize seedlings was inhibited by ferricyanide while the effect of dicumarol was not very pronounced. Nitrite was not detected in the incubation medium, neither with dicumarol-treated nor with control plants after application of 100 microM nitrate to the incubation solution. In a second set of experiments interactions between nitrate and ferricyanide were investigated in vivo and in vitro. Nitrate (1 or 3 mM) did neither influence ferricyanide reductase activity of intact maize roots nor NADH-ferricyanide oxidoreductase activity of isolated plasma membranes. Nitrate reductase activity of plasma-membrane-enriched fractions was slightly stimulated by 25 microM dicumarol but was not altered by 100 microM dicumarol, while NADH-ferricyanide oxidoreductase activity was inhibited in the presence of dicumarol. These data suggest that plasma-membrane-bound standard-ferricyanide reductase and nitrate reductase activities of maize roots may be different. A possible regulation of nitrate uptake by plasmalemma redox activity, as proposed by other groups, is discussed.