Sidedness of plant plasma membrane vesicles altered by conditions of preparation

Right-side-out vesicles of plasma membrane from soybean (Glycine max Merr.) were isolated by aqueous two-phase partition. Inside-out vesicles were formed when these preparations were diluted or frozen and thawed. Sidedness (orientation) was determined by preparative free-flow electrophoresis, concanavalin A binding, and ATPase latency. Under usual conditions of aqueous two-phase partition, the bulk of the vesicles were strongly reactive with concanavalin A-peroxidase and showed a high level of structure-linked latency as expected of a right-side-out (cytoplasmic-side-in) orientation. The vesicles migrated as a single electrophoretic peak. When frozen and thawed, vesicle diameters were reduced and a second population of vesicles of increased electrophoretic mobility was obtained. This second population of vesicles was weakly reactive with concanavalin A-peroxidase and showed low latency as expected of an inside-out (cytoplasmic-side-out) orientation. If the plasma membrane vesicles were diluted with water, a mixture of right-side-out and inside-out vesicles again was obtained. However, some of the cytoplasmic-side-out vesicles that were concanavalin A-unreactive and had low ATPase latency migrated more slowly as a second, less electronegative peak, upon free-flow electrophoresis. The results suggest that right-side-out and inside-out plasma membrane vesicles differ in electrophoretic mobility but that both the orientation and the absolute electrophoretic mobility of the differently oriented vesicles may be influenced by the preparative conditions.     

Localization of plasma membrane t-SNAREs syntaxin 2 and 3 in intracellular compartments

Background  

Membrane fusion requires the formation of a complex between a vesicle protein (v-SNARE) and the target membrane proteins (t-SNAREs). Syntaxin 2 and 3 are t-SNAREs that, according to previous over-expression studies, are predominantly localized at the plasma membrane. In the present study we investigated localization of the endogenous syntaxin 2 and 3.     

Effect of lysophosphatidylcholine on salt permeability through the erythrocyte membrane under haemolytic conditions

Human erythrocytes were incubated in haemolytic salt or sucrose media and the amount of potassium and haemoglobin released were monitored. In hypotonic NaCl and KCl solutions potassium release and haemolysis increased with time showing that the cell membrane had been injured and became permeable to intra- and extracellular cations which, due to intracellular haemoglobin, causes water influx and continuous haemolysis. Both potassium release and haemolysis remained, however, at their 2-minute level in the presence of LPC. Thus, LPC could reseal the membrane and prevent continuous salt fluxes. It protected erythrocytes from hypotonic haemolysis and the protection was more efficient in NaCl than in sucrose media. This suggests that the increase in the critical volume of erythrocytes caused by LPC occurs both in electrolyte and sucrose media, and the additional protection observed in electrolyte media is due to the resealing of the injured cell membrane by LPC. The repairing mechanism was mediated via the membrane lipids or integral proteins, since the time-course of haemolysis of erythrocytes swollen in NaCl media at the spectrin-denaturing temperature of 49.5 degrees C was similar to that at room temperature with and without LPC. LPC did not protect erythrocytes from colloid osmotic haemolysis caused by ammonia influx in an isotonic NH4Cl medium, but protected the cells from colloid osmotic haemolysis caused by sodium influx through nystatin-channels in NaCl media without any area or volume increase. Hence, LPC could not prevent ammonia influx through the lipid bilayer, but suppressed sodium influx through nystatin-channels presumably via LPC interference with cholesterol.     

New Salmonella typhimurium mutants with altered outer membrane permeability

We describe three new classes of Salmonella typhimurium mutants with increased sensitivity to hydrophobic agents. In contrast to many previously described mutants, the phage sensitivity pattern of these mutants did not give any indication of defective lipopolysaccharide. Furthermore, they had no detectable changes in their phospholipid or outer membrane protein composition, and their growth rate and cell morphology were normal. Class B mutants were nearly as sensitive to novobiocin, fusidic acid, erythromycin, rifampin, and clindamycin as are deep rough (heptoseless) mutants; in addition they were sensitive to methicillin, penicillin (to which heptoseless mutants are resistant), gentian violet, and anionic and cationic detergents. Class A and C mutants had less sensitive, but characteristic phenotypes. None of the three classes were sensitive to serum bactericidal action. The class B mutation mapped between map positions 7 and 11 on the S. typhimurium chromosome, and the class C mutation mapped between positions 5 and 7. The map position for the class A mutation remained undefined, but it was separate from the class B and C mutations and, like those, did not correspond to any gene loci known to participate in the synthesis of major outer membrane constituents.     

Short-term control of maize cell and root water permeability through plasma membrane aquaporin isoforms

Although it is widely accepted that aquaporins are involved in the regulation of root water uptake, the role of specific isoforms in this process is poorly understood. The mRNA expression and protein level of specific plasma membrane intrinsic proteins (PIPs) were analysed in Zea mays in relation to cell and root hydraulic conductivity. Plants were analysed during the day/night period, under different growth conditions (aeroponics/hydroponics) and in response to short-term osmotic stress applied through polyethylene glycol (PEG). Higher protein levels of ZmPIP1;2, ZmPIP2;1/2;2, ZmPIP2;5 and ZmPIP2;6 during the day coincided with a higher water permeability of root cortex cells during the day compared with night period. Similarly, plants which were grown under aeroponic conditions and which developed a hypodermis ('exodermis') with Casparian bands, effectively forcing more water along a membranous uptake path across roots, showed increased levels of ZmPIP2;5 and ZmPIP1;2 in the rhizodermis and exodermis. When PEG was added to the root medium (2-8 h), expression of PIPs and cell water permeability in roots increased. These data support a role of specific PIP isoforms, in particular ZmPIP1;2 and ZmPIP2;5, in regulating root water uptake and cortex cell hydraulic conductivity in maize.     

Ca2+ control of electrolyte permeability in plasma membrane vesicles from cat pancreas

Summary The influence of Ca²⁺ and other cations on electrolyte permeability has been studied in isolated membrane vesicles from cat pancreas.Ca²⁺ in the micromolar to millimolar concentration range, as well as Mg²⁺, Sr²⁺, Mn²⁺ and La³⁺ at a tested concentration of 10^–4m, increased Na⁺ permeability when applied at the vesicle inside. When added to the vesicle outside, however, they decreased Na⁺ permeability. Ba²⁺ was effective from the outside but not from the vesicle inside.When Ca²⁺ was present at both sides of the membrane, Na⁺ efflux was not affected as compared to that in the absence of Ca²⁺. Monovalent cations such as Rb⁺, Cs⁺, K⁺, Tris⁺ and choline⁺ decreased Na⁺ permeability when present at the vesicle outside at a concentration range of 10 to 100mm. Increasing Na⁺ concentrations from 10 to 100mm at the vesicle inside increased Na⁺ permeability.The temperature dependence of Na⁺ efflux revealed that the activation energy increased in the lower temperature range (0 to 10°C) when Ca²⁺ was present at the outside or at both sides, but not when present at the vesicle inside only or in the absence of Ca²⁺.The results suggest that the Ca²⁺ outside effect is due to binding of calcium to negatively charged phospholipids with a consequent reduction of both fluidity and Na⁺ permeability of the membrane. The Ca²⁺-inside effect most likely involves interaction with proteins with consequent increase in Na⁺ permeability.The data are consistent with current hypotheses on secretagogue-induced fluid secretion in acinar cells of the pancreas according to which secretagogues elicit NaCl and fluid secretion by liberating Ca²⁺ from cellular membranes and by stimulating Ca²⁺ influx into the cell. The increased intracellular Ca²⁺ concentration in turn increases the contraluminal Na⁺ permeability which leads to NaCl influx. The luminal sodium pump finally transports Na⁺ ions into the lumen.     

Characterization of H(+)-ATPase activity in plasma membrane from pea seedlings under altered gravity

The specific properties and characteristics of the H+-ATPase, lipid and fatty acids content and composition in plasma membrane vesicles isolated from pea seedlings grown under clinorotation (2 rev/min) and stationary conditions were studied.     

Importance of intracellular water apparent diffusion to the measurement of membrane permeability

The exchange of water across biological membranes is of fundamental significance to both animal and plant physiology. Diffusional membrane permeability (P(d)) for the Xenopus oocyte, an important model system for water channel investigation, is typically calculated from intracellular water pre-exchange lifetime, cell volume, and cell surface area. There is debate, however, whether intracellular water motion affects water lifetime, and thereby P(d). Mathematical modeling of water transport is problematic because the intracellular water diffusion rate constant (D) for cells is usually unknown. The measured permeability may be referred to as the apparent diffusional permeability, P, to acknowledge this potential error. Herein, we show that magnetic resonance (MR) spectroscopy can be used to measure oocyte water exchange with greater temporal resolution and higher signal-to-noise ratio than other methods. MR imaging can be used to assess both oocyte geometry and intracellular water diffusion for the same single cells. MR imaging is used to confirm the dependence of intracellular water lifetime on intracellular diffusion. A model is presented to relate intracellular lifetime to true membrane diffusional permeability. True water diffusional permeability (2.7 +/- 0.4 microm/s) is shown to be 39 +/- 6% greater than apparent diffusional permeability for 8 oocytes. This discrepancy increases with cell size and permeability (such as after water channel expression) and decreases with increasing intracellular water D.     

Proton permeability of the plasma membrane of rat cortical synaptosomes

1. Transmembrane pH gradients (acidic inside) and electrical gradients (negative inside) were estimated in cortical synaptosomes from the distribution of the weak base methylamine and the lipophilic cation tetraphenylphosphonium, respectively. 2. Acidic interior pH gradients were produced by outwardly directed K+ gradients in Na+-free media. External K+ accelerated the dissipation of preformed H+ gradients. The appearance of H+ in the medium was directly demonstrated by pH-stat titration of a weakly buffered medium. Amiloride failed to inhibit K+-induced H+ release. 3. Elevating K+ in the absence of Na+ did not affect the endogenous contents of noradrenaline, dopamine, and serotonin, as determined by high-performance liquid chromatography with electrochemical detection. 4. H+ diffusion potentials were generated when outwardly directed H+ gradients were imposed onto the plasma membrane indicating an electrogenic H+ efflux which is not coupled to other ions. 5. At low K+ in the Na+-free sucrose medium, the plasma membrane potential Em (derived from distribution of tetraphenylphosphorium cation) did not approach a value for EK, the K+ equilibrium potential (calculated from K+ gradients). The deviation of Em from EK could be quantitatively described by a modified constant-field equation, taking a relative H+/K+ permeability coefficient of 12,400 into consideration. 6. It is concluded that synaptosomes have a H+ conductance pathway in their plasma membrane in addition to the Na+/H+ antiporter. H+ influx is driven by and leads to a reduction of Em. K+/H+ exchange resulted from the electrical coupling of K+ and H+ fluxes via parallel K+ and H+ channels. Since the Na+/H+ antiporter counteracts passive equilibration of H+ under physiological conditions, a continuous cycling of H+ across the plasma membrane will take place. A possible physiological role of the H+ leak in pHi regulation is discussed.     

Water permeability of the OMCD and IMCD cells' basolateral membrane under the conditions of dehydration and dDAVP action

Water permeability of the basolateral membrane was estimated in isolated fragments of OMCD or IMCD in the Wistar rats. Apical surface of the fragments was blocked with oil injected into the lumen. Apparent water permeability coefficient (Pf) was measured by the rate of epithelium swelling following transition from hypertonic to isotonic medium (600 mOsm to 300 mOsm). Water deprivation caused significant increase in the Pf value in OMCD and IMCD fragments. Desmopressin (10(-8) M) increased water permeability in hydrated rats both in OMCD and IMCD. Mercury chloride decreased the Pf and abolished the effect of desmopressin in reversible manner. Estimation of aquaporins 2, 3, 4 mRNA content in the renal medulla was performed by semi-quantitative RT-PCR. Content of AQP4 and AQP2 mRNA in dehydrated animals was significantly higher than in hydrated ones both in outer medulla and inner medulla. Expression of AQP3 increased during dehydration only in the inner medulla. The findings reveal that water permeability of OMCD and IMCD can be increased by physiological stimuli, e.g. water deprivation. The activation of gene expression of the key elements of vasopressin signal system seems to contribute to this reaction.     

Energy metabolism in wheat root cells under modification of plasma membrane permeability by antibiotic nystatin

This paper reports changes in ion transport and energy metabolism of plant cells during short- and long-term expositions, resp., to antibiotic nystatin, which is known to specifically bind with plasma membrane sterols to form channels. The excised roots of 5 days old wheat seedlings were used as a model system in this research. It has been shown that treatment of excised roots with nystatin leads to activation of energy metabolism expressed as an increase of respiration and heat production by root cells. Furthermore, in the presence of nystatin increased pH of incubation medium, plasma membrane depolarization and a significant loss of potassium ions were observed. Nystatin-induced stimulation of respiration was prevented by malonate, an inhibitor of succinate dehydrogenase, electron acceptor dichlorophenolindophenol, and AgNO3, an inhibitor of H(+)-ATPase. Based on the data obtained it can be suggested that nystatin-induced stimulation of respiration is related to electron transport activation via mitochondrial respiratory chain, and is connected with activation of plasmalemma proton pump. Moreover, nystatin-induced increase of oxygen consumption was prevented by cerulenin, an inhibitor of fatty acid and sterol synthesis. This indicates that additional sterols and phospholipids may be synthesized in root cells to "heal" nystatin-caused damage of plasma membrane. A supposed chain of events of cell response to nystatin action may by as following: formation of nystatin channels-influx of protons--depolarization of plasmalemma-efflux of potassium ions-disturbance of ion homeostasis--activation of H(+)-ATPase work-increase in energy "requests" for H(+)-ATPase function--increase in the rate of oxygen consumption and heat production. The increased energy production under the action of nystatin, may provide the work of proton pump and synthesis of sterols and phospholipids, which are necessary for membrane regeneration.     

Cholesterol impairs the adenine nucleotide translocator-mediated mitochondrial permeability transition through altered membrane fluidity

Mitochondrial permeability transition (MPT) has been proposed to play a key role in cell death. Downstream MPT events include the release of apoptogenic factors that sets in motion the mitochondrial apoptosome leading to caspase activation. The current work examined the regulation of MPT by membrane fluidity modulated upon cholesterol enrichment. Mitochondria enriched in cholesterol displayed increased microviscosity resulting in impaired MPT induced by atractyloside, a c-conformation stabilizing ligand of the adenine nucleotide translocator (ANT). This effect was dependent on the dose of cholesterol loaded and reversed upon the fluidization of mitochondria by the fatty acid derivative A2C. Mitoplasts derived from cholesterol-enriched mitochondria responded to atractyloside in a similar fashion as intact mitochondria, indicating that a significant amount of cholesterol is still found in the inner membrane. The effects of cholesterol on MPT induced by atractyloside were mirrored by the release of intermembrane proteins, cytochrome c, Smac/Diablo, and apoptosis inducing factor. However, cholesterol loading did not affect the uptake rate of adenine nucleotide hence dissociating the function of ANT as a MPT-mediated protein from its adenine nucleotide exchange function. Thus, these findings indicate that the ability of atractyloside to induce MPT via ANT requires an appropriate membrane fluidity range.     

Analysis of the H+/sugar symport in yeast under conditions of depolarized plasma membrane

H⁺/sugar symport in the obligatory aerobic yeastRhodotorula glutinis was analyzed under conditions where the plasma membrane was selectively depolarized by the lipophilic cation tetraphenylphosphonium (TPP⁺). Control experiments showed that this treatment did not impair the transmembrane pH, the cell energy charge, and the function of plasma membrane H⁺-ATPase. The kinetic data were fitted to elementary functions derived from a model constructed on the basis of some simplifying premises for ordered (either C + H⁺ + S or C + S + H⁺) and random reaction mechanisms. In addition, the comparison of the kinetic parameters in fully energized and depolarized cells provided information about the free carrier charge. It was concluded that the binding sequence of formation of the ternary carrier/H⁺/substrate complex follows a random mechanism and that the carrier bears a negative charge.     

The role of intracellular Ca2+ in the regulation of the plasma membrane Ca2+ permeability of unstimulated rat lymphocytes

The mechanism responsible for the increase in cytosolic free Ca2+ concentration ([Ca2+]i) during mitogenic stimulation of lymphocytes has been widely investigated. By contrast, little is known about the processes underlying Ca2+i homeostasis in resting (unstimulated) cells. It has been suggested that [Ca2+]i is an important determinant of the rate of Ca2+ influx following mitogenic activation. Using rat thymic lymphocytes, we investigated whether the resting influx pathway is similarly controlled by [Ca2+]i. Otherwise untreated cells were Ca(2+)-depleted by loading with Ca2+ chelators while suspended in Ca(2+)-free solution. Ca2+ depletion induced an 8-fold increase in the rate of unidirectional Ca2+ uptake. The depletion-activated flux was voltage-sensitive and was blocked by La3+ and by compound SK&F 96365, a receptor-operated Ca2+ channel blocker. Upon reintroduction to Ca(2+)-containing solution, the increased influx brought about a rapid recovery of [Ca2+]i. Detailed analysis of the magnitude of the 45Ca2+ flux during this recovery indicated that [Ca2+]i is not the primary determinant of the plasmalemmal Ca2+ permeability. Instead, depletion of an internal thapsigargin-sensitive store correlates with and appears to be responsible for the increased permeability of the plasma membrane. Accordingly, the Ca2+ fluxes induced by intracellular Ca2+ depletion and by thapsigargin were pharmacologically indistinguishable. Mitogenic lectins also released Ca2+ from a thapsigargin-sensitive store and activated a plasmalemmal Ca2+ permeability displaying identical pharmacology. The data support the existence of a coupling process whereby the degree of filling of an internal Ca2+ store dictates the Ca2+ permeability of the plasma membrane. This coupling mechanism is important not only in mediating the effects of mitogens and other agonists, as suggested before, but seemingly also in the control of resting Ca2+i homeostasis in unstimulated cells.     

Cholesterol-rich intracellular membranes: a precursor to the plasma membrane

The disposition of newly synthesized sterols in cultured human fibroblasts has been examined in this study. We began by demonstrating that cholesterol mass and exogenously added [3H]cholesterol both are markers for the plasma membrane, perhaps better than 5'-nucleotidase. Cells were incubated with radioactive acetate to label their endogenous sterols biosynthetically, treated with cholesterol oxidase to convert plasma membrane cholesterol to cholestenone, and then homogenized and spun to equilibrium on sucrose gradients. The density gradient profiles of the various organelles were monitored using these markers: plasma membrane, radioactive cholestenone; smooth endoplasmic reticulum, 3-hydroxy-3-methylglutaryl-CoA reductase (HMG-CoA reductase); and Golgi apparatus, galactosyltransferase. The buoyant density profiles of radioactive intracellular cholesterol and lanosterol both had a peak at 1.12 g/cm3, similar to 5'-nucleotidase and galactosyltransferase but not to HMG-CoA reductase. This result suggests that cholesterol biosynthesis is not taken to completion in the endoplasmic reticulum. Digitonin treatment shifted the profiles of both plasma membrane and intracellular cholesterol to higher densities. Pretreatment of intact cells with cholesterol oxidase abolished the digitonin shift of plasma membranes but not the intracellular cholesterol, indicating that these two membrane pools are not entirely physically associated. Because intracellular cholesterol was shifted more than any of the organelle markers, it must reside in a separate membrane. Since digitonin selectively shifts the density of membranes rich in cholesterol, we infer that newly synthesized cholesterol accumulates in such membranes prior to its delivery to the plasma membrane. Taken together, these results suggest that cholesterol may be concentrated for delivery to the plasma membrane by being synthesized from a sterol precursor such as lanosterol in a discrete but undefined intracellular membrane.     

Dynamic changes in the osmotic water permeability of protoplast plasma membrane

The osmotic water permeability coefficient (P(f)) of plasma membrane of maize (Zea mays) Black Mexican Sweet protoplasts changed dynamically during a hypoosmotic challenge, as revealed using a model-based computational approach. The best-fitting model had three free parameters: initial P(f), P(f) rate-of-change (slope(P(f))), and a delay, which were hypothesized to reflect changes in the number and/or activity of aquaporins in the plasma membrane. Remarkably, the swelling response was delayed 2 to 11 s after start of the noninstantaneous (but accounted for) bath flush. The P(f) during the delay was < or =1 microm s(-1). During the swelling period following the delay, P(f) changed dynamically: within the first 15 s P(f) either (1) increased gradually to approximately 8 microm s(-1) (in the majority population of low-initial-P(f) cells) or (2) increased abruptly to 10 to 20 microm s(-1) and then decreased gradually to 3 to 6 microm s(-1) (in the minority population of high-initial-P(f) cells). We affirmed the validity of our computational approach by the ability to reproduce previously reported initial P(f) values (including the absence of delay) in control experiments on Xenopus oocytes expressing the maize aquaporin ZmPIP2;5. Although mercury did not affect the P(f) in swelling Black Mexican Sweet cells, phloretin, another aquaporin inhibitor, inhibited swelling in a predicted manner, prolonging the delay and slowing P(f) increase, thereby confirming the hypothesis that P(f) dynamics, delay included, reflected the varying activity of aquaporins.