Changes in plasma membrane lipids, aquaporins and proton pump of broccoli roots, as an adaptation mechanism to salinity

Salinity stress is known to modify the plasma membrane lipid and protein composition of plant cells. In this work, we determined the effects of salt stress on the lipid composition of broccoli root plasma membrane vesicles and investigated how these changes could affect water transport via aquaporins. Brassica oleracea L. var. Italica plants treated with different levels of NaCl (0, 40 or 80 mM) showed significant differences in sterol and fatty acid levels. Salinity increased linoleic (18:2) and linolenic (18:3) acids and stigmasterol, but decreased palmitoleic (16:1) and oleic (18:1) acids and sitosterol. Also, the unsaturation index increased with salinity. Salinity increased the expression of aquaporins of the PIP1 and PIP2 subfamilies and the activity of the plasma membrane H⁺-ATPase. However, there was no effect of NaCl on water permeability (P_f) values of root plasma membrane vesicles, as determined by stopped-flow light scattering. The counteracting changes in lipid composition and aquaporin expression observed in NaCl-treated plants could allow to maintain the membrane permeability to water and a higher H⁺-ATPase activity, thereby helping to reduce partially the Na⁺ concentration in the cytoplasm of the cell while maintaining water uptake via cell-to-cell pathways. We propose that the modification of lipid composition could affect membrane stability and the abundance or activity of plasma membrane proteins such as aquaporins or H⁺-ATPase. This would provide a mechanism for controlling water permeability and for acclimation to salinity stress.     

Mechanism of proton transport by plant plasma membrane proton ATPases

The mechanism of proton translocation by P-type proton ATPases is poorly defined. Asp684 in transmembrane segment M6 of the Arabidopsis thaliana AHA2 plasma membrane P-type proton pump is suggested to act as an essential proton acceptor during proton translocation. Arg655 in transmembrane segment M5 seems to be involved in this proton translocation too, but in contrast to Asp684, is not essential for transport. Asp684 may participate in defining the E₁ proton-binding site, which could possibly exist as a hydronium ion coordination center. A model of proton translocation of AHA2 involving the side chains of amino acids Asp684 and Arg655 is discussed.     

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.     

Amino acid-dependent sodium transport in plasma membrane vesicles from rat liver

Summary Thel-alanine-dependent transport of sodium ions across the plasma membrane of rat-liver parenchymal cells was studied using isolated plasma membrane vesicles. Sodium uptake is stimulated specifically by thel-isomer of alanine and other amino acids, whose transport is sodium-dependent in rat-liver plasma membrane vesicles. Thel-alanine-dependent sodium flux across the membrane is inhibited by an excess of Li⁺ ions, but not by K⁺ or choline ions. Sodium transport is sensitive to-SH reagents and ionophores, and is an electrogenic process: a membrane potential (negative inside) can enhancel-alanine-dependent sodium accumulation. The data presented provide further evidence for a sodium-alanine cotransport mechanism.     

The ultrastructure of plasma and thylakoid membrane vesicles from the fresh water cyanobacteriumAnacystis nidulans adapted to salinity

Summary Photoautotrophically growing cultures of the fresh water cyanobacteriumAnacystis nidulans adapted to the presence of 0.4–0.5 M NaCl (about sea water level) with a lag phase of two days after which time the growth rate reassumed 80–90% of the control. Plasma and thylakoid membranes were separated from cell-free extracts of French pressure cell treatedAnacystis nidulans by discontinuous sucrose density gradient centrifugation and purified by repeated recentrifugation on fresh gradients. Identity of the plasma and thylakoid membrane fractions was confirmed by labeling of intact cells with impermeant protein markers prior to breakage and membrane isolation. Electron microscopy revealed that each type of membrane was obtained in the form of closed and perfectly spherical vesicles. Major changes in structure and function of the plasma membranes (and, to a much lesser extent, of the thylakoid membranes) were found to accompany the adaptation process. On the average, diameters of plasma membrane vesicles from salt adapted cells were only one-third of the diameters of corresponding vesicles from control cells. By contrast, the diameters of thylakoid membrane vesicles were the same in both cases.Freeze-etching the cells and counting the number of membrane-intercalating particles on both protoplasmic and exoplasmic fracture faces of plasma and thylakoid membranes indicated a roughly 50% increase of the particle density in plasma membranes during the adaptation process while that in thylakoid membranes was unaffected. Comparison between particle densities on isolated membranes and those on corresponding whole cell membranes permitted an estimate as to the percentage of inside-out and right-side-out vesicles. Stereometric measurement of particle sizes suggested that two distinct sub-populations of the particles in the plasma membranes increased during the adaptation process, tentatively correlated to the cytochrome oxidase and sodium-proton antiporter, respectively. The effects of salt adaptation described in this paper were fully reversed upon withdrawal of the additional NaCl from the growth medium (deadaptation). Moreover, they were not observed when the NaCl was replaced by KCl.Abbreviations CM cytoplasmic or plasma membrane - ICM intracytoplasmic or thylakoid membrane - EF exoplasmic fracture face - PF protoplasmic fracture face - DABS diazobenzosulfonate; Hepes N-2-hydroxyethylpiperazine-N-2-ethane-sulfonate - PMSF phenylmethylsulfonylfluoride Dedicated to the memory of Professor Oswald Kiermayer     

NADH-ascorbate free radical and -ferricyanide reductase activities represent different levels of plasma membrane electron transport

Plasma membranes isolated from rat liver by two-phase partition exhibited dehydrogenase activities for ascorbate free radical (AFR) and ferricyanide reduction in a ratio of specific activities of 1 : 40. NADH-AFR reductase could not be solubilized by detergents from plasma membrane fractions. NADH-AFR reductase was inhibited in both clathrin-depleted membrane and membranes incubated with anti-clathrin antiserum. This activity was reconstituted in plasma membranes in proportion to the amount of clathrin-enriched supernatant added. NADH ferricyanide reductase was unaffected by both clathrin-depletion and antibody incubation and was fully solubilized by detergents. Also, wheat germ agglutinin only inhibited NADH-AFR reductase. The findings suggest that NADH-AFR reductase and NADH-ferricyanide reductase activities of plasma membrane represent different levels of the electron transport chain. The inability of the NADH-AFR reductase to survive detergent solubilization might indicate the involvement of more than one protein in the electron transport from NADH to the AFR but not to ferricyanide.     

Interaction of heme and heme-hemopexin with an extracellular oxidant system used to measure cell growth-associated plasma membrane electron transport

Since redox active metals are often transported across membranes into cells in the reduced state, we have investigated whether exogenous ferri-heme or heme bound to hemopexin (HPX), which delivers heme to cells via receptor-mediated endocytosis, interact with a cell growth-associated plasma membrane electron transport (PMET) pathway. PMET reduces the cell-impermeable tetrazolium salt, WST-1, in the presence of the mandatory low potential intermediate electron acceptor, mPMS. In human promyelocytic (HL60) cells, protoheme (iron protoporphyrin IX; 2,4-vinyl), mesoheme (2,4-ethyl) and deuteroheme (2,4-H) inhibited reduction of WST-1/mPMS in a saturable manner supporting interaction with a finite number of high affinity acceptor sites (Kd 221 nM for naturally occurring protoheme). A requirement for the redox-active iron was shown using gallium-protoporphyrin IX (PPIX) and tin-PPIX. Heme-hemopexin, but not apo-hemopexin, also inhibited WST-1 reduction, and copper was required. Importantly, since neither heme nor heme-hemopexin replace mPMS as an intermediate electron acceptor and since inhibition of WST-1/mPMS reduction requires living cells, the experimental evidence supports the view that heme and heme-hemopexin interact with electrons from PMET. We therefore propose that heme and heme-hemopexin are natural substrates for this growth-associated electron transfer across the plasma membrane.     

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.     

Ruthenium ammine complexes as electron acceptors for growth stimulation by plasma membrane electron transport

Ammineruthenium(III) complexes have been found to act as electron acceptors for the transplasmalemma electron transport system of animal cells. The active complexes hexaammineruthenium(III), pyridine pentaammineruthenium(III), and chloropentaammineruthenium(III) range in redox potential (E ₀) from 305 to –42 mV. These compounds also act as electron acceptors for the NADH dehydrogenase of isolated plasma membranes. Stimulation of HeLa cell growth, in the absence of calf serum, by these compounds provides evidence that growth stimulation by the transplasma membrane electron transport system is not entirely based on reduction and uptake of iron.     

Changes in plasma osmolality and Na+/K+ ATPase activity of juvenile obscure puffer Takifugu obscurus following salinity challenge

The osmoregulatory capabilities of 6-month-old juvenile obscure puffer Takifugu obscurus, transferred directly from fresh water to different salinities (0‰, freshwater control; 10‰; 20‰ and 30‰), were studied over an 8-day period. After transfer, plasma osmolality of the fish at 30‰ was significantly higher than those at all other salinities throughout the experiment. The Na⁺/K⁺ ATPase activity in the gills of the fish treated with various salinities increased significantly, peaking at 48 h, then decreased gradually to the control level at 192 h. Similar fluctuation trends of the Na⁺/K⁺ ATPase activity were observed in the kidneys. Modified Gaussian model provided accurate fits for the time-course changes in the Na⁺/K⁺ ATPase activities after abrupt salinity challenge. The results demonstrated that obscure puffer has strong capacity to tolerate abrupt salinity changes and can osmoregulate well over a wide range of salinities even in juvenile stage.     

The plasma membrane proteome of Saccharomyces cerevisiae and its response to the antifungal calcofluor

Calcofluor is an antifungal compound known to induce structural perturbations of the cell wall by interfering with the synthesis of chitin microfibril. Proteins from a stripped plasma membrane fraction were solubilized with the neutral and non-denaturing detergent, the n-dodecyl beta-D-maltoside. Proteins were then resolved using a recently described ion-exchange chromatography (IEC)/lithium dodecyl sulfate (LDS)-PAGE procedure. Nearly 90 proteins were identified and clustered, based on their pI, molecular weight, abundance and/or hydrophobicity. This method was then applied to profile the plasma membrane response to calcofluor. The LDS-PAGE patterns obtained from whole plasma membrane proteins were similar for the non-treated and calcofluor-treated samples. However, IEC/LDS-PAGE analysis revealed subtle changes in the expression of several proteins of low abundance, in response to calcofluor. These proteins include Pil1p and Lsp1p, two sphingolipid long-chain base-responsive inhibitors of protein kinases involved in signaling pathways for cell wall integrity and Rho1p, a small GTPase. It was recently hypothesized that Pil1p and Lsp1p could associate with, and regulate, the plasma membrane beta-1-3-glucan synthase, responsible for the synthesis of another major microfibril for yeast cell wall. Results are discussed with respect to both calcofluor effects on the plasma membrane proteins and the power of the IEC/LDS-PAGE procedure in the search for new potential therapeutics targets.     

NaCl-induced changes in plasma membrane lipids and proteins of <Emphasis Type="Italic">Zea mays</Emphasis> L. cultivars differing in their response to salinity

Two contrasting maize (Zea mays L.) cultivars, i.e., Giza 2 (salt tolerant) and Trihybrid 321 (salt sensitive), were grown hydroponically to study NaCl effect (100 mM) on root plasma membrane (PM) lipid and protein alterations. The PM total sterols of Trihybrid 321 were decreased while that of Giza 2 was increased in response to salt. Salt imposition had no significant effect on PM total glycolipids and proteins of both cultivars. The PM total phospholipids were increased in Trihybrid 321 but it did not change significantly in Giza 2 after salinity stress. Molecular percentage of PM phospholipids and fatty acids of both cultivars was different in absence (0 mM) and presence (100 mM) of salt. The most abundant phospholipids in untreated Trihybrid 321 PM were phosphatidylglycerol (PG), phosphatidylcholine (PC), phosphatidylethanolamine (PE) and phosphatidylserine (PS), which changed into PG, PS, phosphatidylinositol (PI) and PC after salt treatment. However, the dominant phospholipids of the control PM of Giza 2 were PC, PE, PS and PG, which changed into PG, PE, PS and diphosphatidylglycerol (DPG) after salt imposition. Over 60% of the total fatty acids were saturated in control and salinized PM of both cultivars, which was increased after salt stress. The predominant fatty acid in the control and salinized PM of Trihybrid 321 was C18:1 and C17:0, respectively. However, in control and treated PM of Giza 2, the predominant fatty acid was C17:0 and C20:0, respectively. Qualitative and quantitative differences in PM protein patterns were found in both cultivars with and without salt. PM lipid changes enhanced membrane integrity, reflected in different ion accumulation (Mansour et al. 2005), and hence salt tolerance of Giza 2.     

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⁺.     

Cd2+-induced damage to yeast plasma membrane and its alleviation by Zn2+: studies on Schizosaccharomyces pombe cells and reconstituted plasma membrane vesicles

In Schizosaccharomyces pombe, Cd²⁺ shares the same uphill uptake system with Zn²⁺. Both heavy metals inhibited growth, respiration, H⁺/glucose uptake, and glucose-induced proton extrusion, Cd²⁺ being a 10–15-fold stronger inhibitor. In contrast, both had a similar effect on the plasma membrane H⁺-ATPase, enhancing its affinity for ATP and reducing the rate of ATP splitting. Cd²⁺ caused protracted strong fluidization of the plasma membrane of energized cells, whereas deenergized cells, phosphatidylcholine liposomes, and plasma membrane fragments, either purified or incorporated into the liposomes, exhibited only a short initial fluidization. Zn²⁺, which caused only a marginal membrane fluidization, suppressed the fluidizing action of Cd²⁺. The fluidizing effect of both heavy metals on liposomes was reduced by the presence of plasma membrane fragments in the liposome membrane. At 50 μM, Cd²⁺ brought about loss K⁺ (18 K⁺/1 Cd²⁺) from energized, but not from deenergized cells since Cd²⁺ must first accumulate in the cells before causing a detectable effect. A simple membrane disruption by external Cd²⁺ is, therefore, unlikely to be the main mechanism of cadmium-induced potassium loss in intact cells. Zn²⁺ had virtually no effect below 1 mM concentration, and it again weakened the K⁺-releasing effect of Cd²⁺. Cd²⁺ caused a strong loss of K⁺ also from K⁺-containing liposomes, probably because of a direct interaction with liposome phospholipids. Incorporation of plasma membrane fragments into the liposomes reduced the K⁺ loss sixfold. Received: 13 November 1995 / Accepted: 31 January 1996     

Large-scale preparation of plasma membrane vesicles from PC-12 Pheochromocytoma cells and their use in noradrenaline transport studies

Plasma membranes were isolated from rat pheochromocytoma cells (PC-12) grown in spinner culture. The rapid and simple isolation procedure consisted of a differential and isopycnic centrifugation (in a linear sucrose gradient) with the aid of a high capacity fixed angle rotor equipped with siliconized centrifuge tubes. The isolated membranes were closed and osmotically active vesicles (about 0.3 μm in diameter) with a mean intravesicular water space of 1.84 μl / mg protein. In the presence of an inward gradient of sodium chloride and an outward gradient of potassium, [³H]noradrenaline (50 nM) was taken up and accumulated 550-fold (at 31°C). The uptake and accumulation of [³H]noradrenaline was temperature-sensitive and inhibited by the tricyclic antidepressant desipramine. Membrane vesicles isolated from PC-12 cells represent a useful model for the investigation of the molecular mechanism of the neuronal noradrenaline transport system.     

Proton-coupled organic cation transport in renal brush-border membrane vesicles

We had previously proposed that organic cations are transported across the brush-border membrane in the canine kidney by a H⁺ exchange (or antiport) system (Holohan, P.D. and Ross, C.R. (1981) J. Pharmacol. Exp. Ther. 216, 294–298). In the present report, we demonstrate that in brush-border membrane vesicles the transport of organic cations is chemically coupled to the countertransport of protons, by showing that the uphill or concentrative transport of a prototypic organic cation, N¹-methylnicotinamide (NMN), is chemically coupled to the flow of protons down their chemical gradient. In a reciprocal manner, the concentrative transport of protons is coupled to the counterflow of organic cations down their concentration gradient. The transport of organic cations is monitored by measuring [³H]NMN while the transport of protons is monitored by measuring changes in acridine orange absorbance. The functional significance of the coupling is that a proton gradient lowers the K_m and increases the V_max for NMN transport.     

The plasma membrane transformation facilitates pregnancy in both reptiles and mammals

Mechanisms of placentation are very diverse in mammals and range from types in which the uterine epithelium is breached by the implanting blastocyst to those where the epithelium remains intact. Despite these differences in mechanisms, the initial response of the plasma membrane of uterine epithelial cells is remarkably similar across mammalian species which has led to the term 'plasma membrane transformation' to encapsulate the concept of a common beginning to implantation. Membrane phenomena similar to those of mammals have now been observed in some viviparous lizards at the ultrastructural level during early pregnancy, and we propose extending the concept of 'plasma membrane transformation' to lizards with live birth.     

The plasma membrane proteome of germinating barley embryos

Cereal seed germination involves a complex coordination between different seed tissues. Plasma membranes must play crucial roles in coordination and execution of germination; however, very little is known about seed plasma membrane proteomes due to limited tissue amounts combined with amphiphilicity and low abundance of membrane proteins. A fraction enriched in plasma membranes was prepared from embryos dissected from 18 h germinated barley seeds using aqueous two‐phase partitioning. Reversed‐phase chromatography on C₄ resin performed in micro‐spin columns with stepwise elution by 2‐propanol was used to reduce soluble protein contamination and enrich for hydrophobic proteins. Sixty‐one proteins in 14 SDS‐PAGE bands were identified by LC‐MS/MS and database searches. The identifications provide new insight into the plasma membrane functions in seed germination.     

An investigation into the feasibility of using yeast protoplasts to study the ion transport properties of the plasma membrane

A method for studying ion uptake in enzymatically isolated protoplasts from the yeast, Saccharomyces cerevisiae, is described. The kinetics of K⁺ and Rb⁺ uptake, metabolic proton extrusion and cell electrophoretic mobility bave been determined. Enzymic removal of the cell wall does not significantly alter the above-mentioned properties of the yeast cells. It is concluded that studies of these properties can be performed equally well with intact yeast cells or protoplasts. However, in studies aimed at determining effects of complex organic substances, e.g., antibiotics, on plasma membrane function the use of protoplasts is recommended. The effectiveness of the antibiotic, Dio-9, for example, in reversing the metabolic proton extrusion into a net proton influx is at least 50 times higher after enzymic removal of the yeast cell wall.