Study of F-actin interaction with planar and liposomal bilayer phospholipid membranes

Interaction of the cytoskeletal protein F-actin with planar bilayer lipid membrane (BLM) induced formation of single ionic channels in both NaCl and KCl bathing solutions. We also recorded noiselike high-currentjumps with a mean conductivity of approximately 160 pS, which might represent the simultaneous opening and closing of several channels of lower conductivity. The ratio of cation to anion permeabilities (Pc/Pa) of the BLM with many channels in KCl was 26 +/- 2. Freeze-fracture electron microscopy revealed fibrillar-like structures on the hydrophobic surfaces of liposomal membranes. We also observed some structural features giving evidence for the penetration of F-actin fibers through an artificial phospholipid membrane. We suggest that the F-actin/lipids complexes can transmit electric signals in synaptic and other intercellular contacts.     

Structural determinants of lateral gate opening in the protein translocon

The heterotrimeric SecY/Sec61 complex is a protein-conducting channel that provides a passage for proteins across the membrane as well as a means to integrate nascent proteins into the membrane. While the first function is common among membrane protein channels and transporters, the latter is unique. Insertion of nascent membrane proteins, one transmembrane segment at a time, by SecY likely occurs through a lateral gate in the channel. Molecular dynamics simulations have been used to investigate the mechanism of gate opening. Opening and closing the gate under different conditions allowed us to identify structural elements that resist opening as well as those that aid closure. SecE, considered to act as a clamp keeping the lateral gate closed, was found to play no such role. Loosening of the plug by lateral gate opening, a potential step in channel gating, was also observed. The simulations revealed that lipids on time scales of up to 1 micros do not flood channels with an open lateral gate.     

Bidirectional control of sphingomyelinase activity and surface topography in lipid monolayers

Lipid lateral organization is increasingly found to modulate membrane-bound enzymes. We followed in real time the reaction course of sphingomyelin (SM) degradation by Bacillus cereus sphingomyelinase (SMase) of lipid monolayers by epifluorescence microscopy. There is evidence that formation of ceramide (Cer), a lipid second messenger, drives structural reorganization of membrane lipids. Our results provide visual evidence that SMase activity initially alters surface topography by inducing phase separation into condensed (Cer-enriched) and expanded (SM-enriched) domains. The Cer-enriched phase grows steadily as the reaction proceeds at a constant rate. The surface topography derived from the SMase-driven reaction was compared with, and found to differ from, that of premixed SM/Cer monolayers of the same lipid composition, indicating that substantial information content is stored depending on the manner in which the surface was generated. The long-range topographic changes feed back on the kinetics of Smase, and the onset of condensed-phase percolation is temporally correlated with a rapid drop of reaction rate. These observations reveal a bidirectional influence and communication between effects taking place at the local molecular level and the supramolecular organization. The results suggest a novel biocatalytic-topographic mechanism in which a surface enzymatic activity can influence the function of amphitropic proteins important for cell function.     

The influence of lipids on voltage-gated ion channels

Voltage-gated ion channels are responsible for transmitting electrochemical signals in both excitable and non-excitable cells. Structural studies of voltage-gated potassium and sodium channels by X-ray crystallography have revealed atomic details on their voltage-sensor domains (VSDs) and pore domains, and were put in context of disparate mechanistic views on the voltage-driven conformational changes in these proteins. Functional investigation of voltage-gated channels in membranes, however, showcased a mechanism of lipid-dependent gating for voltage-gated channels, suggesting that the lipids play an indispensible and critical role in the proper gating of many of these channels. Structure determination of membrane-embedded voltage-gated ion channels appears to be the next frontier in fully addressing the mechanism by which the VSDs control channel opening. Currently electron crystallography is the only structural biology method in which a membrane protein of interest is crystallized within a complete lipid-bilayer mimicking the native environment of a biological membrane. At a sufficiently high resolution, an electron crystallographic structure could reveal lipids, the channel and their mutual interactions at the atomic level. Electron crystallography is therefore a promising avenue toward understanding how lipids modulate channel activation through close association with the VSDs.     

Extracellular Ca²+ alleviates NaCl-induced stomatal opening through a pathway involving H₂O₂-blocked Na+ influx in Vicia guard cells

To gain further insights into the function of extracellular Ca2+ in alleviating salt stress, Vicia faba guard cell protoplasts (GCPs) were patch-clamped in a whole-cell configuration. The results showed that 100 mM NaCl clearly induced Na+ influx across the plasma membrane in GCPs and promoted stomatal opening. Extracellular Ca2+ at 10 mM efficiently blocked Na+ influx and inhibited stomatal opening, which was partially abolished by La3+ (an inhibitor of plasma membrane Ca2+ channel) or catalase (CAT, a H?O? scavenger), respectively. These results suggest that the plasma membrane Ca2+ channels and H?O? possibly mediate extracellular Ca2+-blocked Na+ influx in GCPs. Furthermore, extracellular Ca2+ activated the plasma membrane Ca2+ channels under NaCl stress, which was partially abolished by CAT. These results, taken together, indicate that hydrogen peroxide (H?O?) likely regulates Na+ uptake by activating plasma membrane Ca2+ channels in GCPs. In accordance with this hypothesis, H?O? could mimic extracellular Ca2+ to activate Ca2+ channels and block Na+ influx in guard cells. A single-cell analysis of cytosolic free Ca2+ ([Ca2+](cyt)) using Fluo 3-AM revealed that extracellular Ca2+ induced the accumulation of cytosolic Ca2+ under NaCl stress, but had few effects on the accumulation of cytosolic Ca2+ under non-NaCl conditions. All of these results, together with our previous studies showing that extracellular Ca2+ induced the generation of H?O? in GCPs during NaCl stress, indicate that extracellular Ca2+ alleviates salt stress, likely by activating the H?O?-dependent plasma membrane Ca2+ channels, and the increase in cytosolic Ca2+ appears to block Na+ influx across the plasma membrane in Vicia guard cells, leading to stomatal closure and reduction of water loss.     

The structural organization of skeletal proteins influences lipid translocation across erythrocyte membrane

In order to define the influence of skeletal protein organization on transmembrane phospholipid movement in erythrocyte membranes, we measured the translocation rate of lysophosphatidylcholine in pathologic red cells. A simple method based on the differential extraction of lysophosphatidylcholine from the red cell membrane by saline and albumin solutions was used to quantitate the translocation rate. Two groups of pathologic red cells were chosen for these studies: red cells with quantitative deficiencies of the skeletal proteins, spectrin and protein 4.1, and sickle erythrocytes in which controlled reorganization of the membrane was induced by hemoglobin polymerization. Marked increase in lipid translocation rate was seen in red cells having quantitative deficiencies of spectrin and protein 4.1. The magnitude of the increase in translocation rate in spectrin-deficient red cells was related to the magnitude of protein deficiency. Translocation rate in sickle erythrocyte membranes increased by 50% upon deoxygenation as a result of sickle hemoglobin polymerization. No increase in translocation rate was seen in normal cells upon deoxygenation. By manipulating the extent of membrane reorganization that occurred following deoxygenation of sickle cells, we have been able to show that skeletal reorganization induced by hemoglobin polymerization and not hemoglobin polymerization per se is responsible for the increase in translocation rate. Together, these findings imply that the structural organization of membrane skeletal proteins plays an important role in regulating the rate of transbilayer movement of lipids across the erythrocyte membrane.     

Expression of a Cs(+)-resistant guard cell K+ channel confers Cs(+)-resistant, light-induced stomatal opening in transgenic arabidopsis.

Inward-rectifying K+ (K+in) channels in the guard cell plasma membrane have been suggested to function as a major pathway for K+ influx into guard cells during stomatal opening. When K+in channels were blocked with external Cs+ in wild-type Arabidopsis guard cells, light-induced stomatal opening was reduced. Transgenic Arabidopsis plants were generated that expressed a mutant of the guard cell K+in channel, KAT1, which shows enhanced resistance to the Cs+ block. Stomata in these transgenic lines opened in the presence of external Cs+. Patch-clamp experiments with transgenic guard cells showed that inward K+(in) currents were blocked less by Cs+ than were K+ currents in controls. These data provide direct evidence that KAT1 functions as a plasma membrane K+ channel in vivo and that K+in channels constitute an important mechanism for light-induced stomatal opening. In addition, biophysical properties of K+in channels in guard cells indicate that components in addition to KAT1 may contribute to the formation of K+in channels in vivo.     

Dielectric characteristics of intact and copper-modified bacteria Escherichia coli]

The dielectric parameters of the intact and Cu(2+)-modified concentrated Escherichia coli populations in the frequency range of alternating current 20 Hz-100 MHz were studied. It was found that Cu(2+)-ions in low concentrations, which are mainly absorbed by active centres of the outer cell surface, change the dielectric characteristics of the inner membrane and simultaneously increase the conductivity of plasma membrane in the frequency-independent region 10(5)-10(6) Hz. It was concluded that the disturbances in the barrier properties of plasma membrane by the action of Cu2+ are closely related to changes in the dielectric parameters of intact bacteria.     

Is acidosis the clue to the loss of structure and functioning of the sarcolemma?

The only way for a tissue or organ to survive ischemia is by reperfusion or restoration of the blood flow. However, if the ischemic period is too long reperfusion leads to a Ca2+ overload of the myocardial cells and thereby to cell death. The question is; what are the key events during ischemia which cause this transition from reversible to irreversible injury. In this article we discuss whether acidosis may play a crucial role by inducing Ca2+ release from the sarcolemma and reorganization of membrane components especially the membrane lipids, i.e. lateral phase separation, resulting in membrane protein clustering and changes in lipid asymmetry.     

The Ca(2+)-activated K(+) channel KCa3.1 compartmentalizes in the immunological synapse of human T lymphocytes

T cell receptor engagement results in the reorganization of intracellular and membrane proteins at the T cell-antigen presenting cell interface forming the immunological synapse (IS), an event required for Ca²⁺ influx. KCa3.1 channels modulate Ca²⁺ signaling in activated T cells by regulating the membrane potential. Nothing is known regarding KCa3.1 membrane distribution during T cell activation. Herein, we determined whether KCa3.1 translocates to the IS in human T cells using YFP-tagged KCa3.1 channels. These channels showed electrophysiological and pharmacological properties identical to wild-type channels. IS formation was induced by either anti-CD3/CD28 antibody-coated beads for fixed microscopy experiments or Epstein-Barr virus-infected B cells for fixed and live cell microscopy. In fixed microscopy experiments, T cells were also immunolabeled for F-actin or CD3, which served as IS formation markers. The distribution of KCa3.1 was determined with confocal and fluorescence microscopy. We found that, upon T cell activation, KCa3.1 channels localize with F-actin and CD3 to the IS but remain evenly distributed on the cell membrane when no stimulus is provided. Detailed imaging experiments indicated that KCa3.1 channels are recruited in the IS shortly after antigen presentation and are maintained there for at least 15–30 min. Interestingly, pretreatment of activated T cells with the specific KCa3.1 blocker TRAM-34 blocked Ca²⁺ influx, but channel redistribution to the IS was not prevented. These results indicate that KCa3.1 channels are a part of the signaling complex that forms at the IS upon antigen presentation. T cell activation; ion channels; membrane distribution     

The role of reactive oxygen species in copper-induced permeability of plasma membranes in Escherichia coli

The role of active oxygen species in the induction of nonselective cationic permeability of the plasma membrane of bacteria Escherichia coli B by the action of Cu2+ ions was studied. It was found that the increase in the amount of active oxygen species in the suspension after treating cells with copper occurred synchronously with the leakage of K+ cations from them. Evidence is presented that active oxygen species formed during the interaction of copper ions with bacteria under aerobic conditions are not involved in the induction of channel conductivity in the membrane. Moreover, the ability of oxygen to protect the membrane from the toxic action of copper was shown, and the activation of membrane damage by external reductants was confirmed. These data suggest that the barrier properties of the membrane are disturbed during the interaction of Cu+ ions with critical targets on the surface, the concentration of Cu+ being determined by all redox processes in the near-membrane space.     

Action of calcium ions on channels of inward and outward currents in the molluscan neuron membrane

Changes in the characteristics of activity of sodium, calcium, and potassium channels in the surface membrane during variation of the calcium ion concentration in the extracellular and intracellular medium were investigated by the voltage clamp method during intracellular dialysis of isolated neurons of the mollusksLimnea stagnalis andHelix pomatia. Besides their direct role in passage of the current through the membrane, calcium ions were shown to have two actions, differing in their mechanism, on the functional properties of this membrane. The first was caused by the electrostatic action of calcium ions on the outer surface of the membrane and was manifested as a shift of the potential-dependent characteristics of the ion transport channels along the potential axis; the second is determined by closer interaction of calcium ions with the specific structures of the channels. During the action of calcium-chelating agents EGTA and EDTA on the inner side of the membrane the conductivity of the potassium channels is substantially reduced. With an increase in the intracellular free calcium concentration the conductivity is partially restored. The action of EGTA and EDTA on the outer side of the membrane causes a substantial decrease in the ion selectivity of the calcium channels and changes the kinetics of the portal mechanism. These changes are easily abolished by rinsing off the chelating agents or by returning calcium ions to the external medium. A specific blocking action of an increase in the intracellular free calcium concentration on conductivity of the calcium channels was found.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 9, No. 1, pp. 69–77, January–February, 1977.     

Modulation of TRPV2 by endogenous and exogenous ligands: A computational study

Transient receptor potential vanilloid (TRPV) channels play various important roles in human physiology. As membrane proteins, these channels are modulated by their endogenous lipid environment as the recent wealth of structural studies has revealed functional and structural lipid binding sites. Additionally, it has been shown that exogenous ligands can exchange with some of these lipids to alter channel gating. Here, we used molecular dynamics simulations to examine how one member of the TRPV family, TRPV2, interacts with endogenous lipids and the pharmacological modulator cannabidiol (CBD). By computationally reconstituting TRPV2 into a typical plasma membrane environment, which includes phospholipids, cholesterol, and phosphatidylinositol (PIP) in the inner leaflet, we showed that most of the interacting surface lipids are phospholipids without strong specificity for headgroup types. Intriguingly, we observed that the C-terminal membrane proximal region of the channel binds preferentially to PIP lipids. We also modelled two structural lipids in the simulation: one in the vanilloid pocket and the other in the voltage sensor-like domain (VSLD) pocket. The simulation shows that the VSLD lipid dampens the fluctuation of the VSLD residues, while the vanilloid lipid exhibits heterogeneity both in its binding pose and in its influence on protein dynamics. Addition of CBD to our simulation system led to an open selectivity filter and a structural rearrangement that includes a clockwise rotation of the ankyrin repeat domains, TRP helix, and VSLD. Together, these results reveal the interplay between endogenous lipids and an exogenous ligand and their effect on TRPV2 stability and channel gating.     

Dielectric properties of yeast cells as determined by electrorotation.

Electrorotational spectra of yeast cells, Saccharomyces cerevisiae strain R XII, were measured over a frequency range of nearly 7 decades. The physical properties of distinct cell parts were simultaneously determined for individual cells by comparison with an electrical two-shell model: The conductivity of the cytoplasm, cell wall and cytoplasmic membrane of living cells were found to be 5.5 mS/cm, 0.1 to more than 0.5 mS/cm and less than 0.25 nS/cm to 4.5 microS/cm, respectively. The conductivity of the cytoplasmic membrane was dependent on the conductivity of the medium. Membrane behaviour is interpreted as an opening of membrane channels when the environment becomes more physiological. The specific membrane capacitance was determined to be 1.1 microF/cm2 and the thickness of the cell wall was calculated as 0.11 micron. Heat treated cells showed an increased membrane conductivity of more than 0.1 microS/cm (at 25 microS/cm medium conductivity) and a drop in cytoplasmic conductivity to between 0.1 and 0.8 mS/cm, depending on the length of time the cells were suspended in low conductivity water (25 microS/cm), indicating a perforation of the membrane. A slightly decreased spinning speed scaling factor for dead cells suggests a modification to the cellular surface, while the principal structure of the cell wall appears to be uneffected. It can be demonstrated by these observations, that cellular electrorotation permits the simultaneous investigation of the different cellular compartments of individual cells in vivo under various environmental conditions.     

Src regulates distinct pathways for cell volume control through Vav and phospholipase Cgamma

Cell volume recovery in response to swelling requires reorganization of the cytoskeleton and fluid efflux. We have previously shown that electrolyte and fluid efflux via K+ and Cl- channels is controlled by swelling-induced activation of phospholipase Cgamma (PLCgamma). Recently, integrin engagement has been suggested to trigger responses to swelling through activation of Rho family GTPases and Src kinases. Because both PLCgamma and Rho GTPases can be regulated by Src during integrin-mediated cytoskeletal reorganization, we sought to identify swelling-induced Src effectors. Upon hypotonic challenge, Src was rapidly activated in transient plasma membrane protrusions, where it colocalized with Vav, an activator of Rho GTPases. Inhibition of Src with PP2 attenuated phosphorylation of Vav. PP2 also attenuated phosphorylation of PLCgamma, and inhibited swelling-mediated activation of K+ and Cl- channels and cell volume recovery. These findings suggest that swelling-induced Src regulates cytoskeletal dynamics, through Vav, and fluid efflux, through PLCgamma, and thus can coordinate structural reorganization with fluid balance to maintain cellular integrity.     

Structural polarity and functional bile canaliculi in rat hepatocyte spheroids

Primary hepatocytes self-assemble into spheroids that possess tight junctions and microvilli-lined channels. We hypothesized that polarity develops gradually and that the channels structurally and functionally resemble bile canaliculi. Immunofluorescence labeling of apical and basolateral proteins demonstrated reorganization of the membrane proteins into a polarized distribution during spheroid culture. By means of fluorescent dextran diffusion and confocal microscopy, an extensive network of channels was revealed in the interior of the spheroids. These channels connected over several planes and opened to pores on the surface. To examine the content of apical proteins in the channel membranes, the bile canalicular enzyme dipeptidyl peptidase IV (DPPIV) was localized using a fluorogenic substrate, Ala-Pro-cresyl violet. The results show that DPPIV activity is heterogeneously distributed in spheroids and localized in part to channels. Bile acid excretion was then investigated to demonstrate functional polarity. A fluorescent bile acid analogue, fluorescein isothiocyanate-labeled glycocholate, was taken up into the spheroids and excreted into bile canalicular channels. Due to the structural polarity of spheroids and their ability to excrete bile into channels, they are a unique three-dimensional model of in vitro liver tissue self-assembly. (Videoanimations of some results are available at http://hugroup.cems.umn.edu/research_movies).     

Modulation of potassium channel gating by external divalent cations

We have examined the actions of Zn2+ ions on Shaker K channels. We found that low (100 microM) concentrations of Zn2+ produced a substantial (approximately three-fold) slowing of the kinetics of macroscopic activation and inactivation. Channel deactivation was much less affected. These results were obtained in the presence of 5 mM Mg2+ and 4 mM Ca2+ in the external solution and so are unlikely to be due to modification of membrane surface charges. Furthermore, the action of 100 microM Zn2+ on activation was equivalent to a 70-mV reduction of a negative surface potential whereas the effects on deactivation would require a 15-mV increase in surface potential. External H+ ions reduced the Zn-induced slowing of macroscopic activation with an apparent pK of 7.3. Treatment of Shaker K channels with the amino group reagent, trinitrobenzene sulfonic acid (TNBS), substantially reduced the effects of Zn2+. All these results are qualitatively similar to the actions of Zn2+ on squid K channels, indicating that the binding site may be a common motif in potassium channels. Studies of single Shaker channel properties showed that Zn2+ ions had little or no effect on the open channel current level or on the open channel lifetime. Rather, Zn2+ substantially delayed the time to first channel opening. Thus, K channels appear to contain a site to which divalent cations bind and in so doing act to slow one or more of the rate constants controlling transitions among closed conformational states of the channel.     

Flu channel drug resistance: a tale of two sites

The M2 proteins of influenza A and B virus, AM2 and BM2, respectively, are transmembrane proteins that oligomerize in the viral membrane to form proton-selective channels. Proton conductance of the M2 proteins is required for viral replication; it is believed to equilibrate pH across the viral membrane during cell entry and across the trans-Golgi membrane of infected cells during viral maturation. In addition to the role of M2 in proton conductance, recent mutagenesis and structural studies suggest that the cytoplasmic domains of the M2 proteins also play a role in recruiting the matrix proteins to the cell surface during virus budding. As viral ion channels of minimalist architecture, the membrane-embedded channel domain of M2 has been a model system for investigating the mechanism of proton conduction. Moreover, as a proven drug target for the treatment of influenza A infection, M2 has been the subject of intense research for developing new anti-flu therapeutics. AM2 is the target of two anti-influenza A drugs, amantadine and rimantadine, both belonging to the adamantane class of compounds. However, resistance of influenza A to adamantane is now widespread due to mutations in the channel domain of AM2. This review summarizes the structure and function of both AM2 and BM2 channels, the mechanism of drug inhibition and drug resistance of AM2, as well as the development of new M2 inhibitors as potential anti-flu drugs.     

How does plasmid DNA penetrate cell membranes in artificial transformation process of Escherichia coli?

Artificial transformation of Escherichia coli with plasmid DNA in presence of CaCl2 is a widely used technique in recombinant DNA technology. However, exact mechanism of DNA transfer across cell membranes is largely obscure. In this study, measurements of both steady state and time-resolved anisotropies of fluorescent dye trimethyl ammonium diphenyl hexatriene (TMA-DPH), bound to cellular outer membrane, indicated heat-pulse (0 degrees C42 degrees C) step of the standard transformation procedure had lowered considerably outer membrane fluidity of cells. The decrease in fluidity was caused by release of lipids from cell surface to extra-cellular medium. A subsequent cold-shock (42 degrees C0 degrees C) to the cells raised the fluidity further to its original value and this was caused by release of membrane proteins to extra-cellular medium. When the cycle of heat-pulse and cold-shock steps was repeated, more release of lipids and proteins respectively had taken place, which ultimately enhanced transformation efficiency gradually up to third cycle. Study of competent cell surface by atomic force microscope showed release of lipids had formed pores on cell surface. Moreover, the heat-pulse step almost depolarized cellular inner membrane. In this communication, we propose heat-pulse step had two important roles on DNA entry: (a) Release of lipids and consequent formation of pores on cell surface, which helped DNA to cross outer membrane barrier, and (b) lowering of membrane potential, which facilitated DNA to cross inner membrane of E. coli.     

K+ transport properties of K+ channels in the plasma membrane of Vicia faba guard cells

Electrical properties of the plasma membrane of guard cell protoplasts isolated from stomates of Vicia faba leaves were studied by application of the whole-cell configuration of the patch-clamp technique. The two types of K+ currents that have recently been identified in guard cells may allow efflux of K+ during stomatal closing, and uptake of K+ during stomatal opening (Schroeder et al., 1987). A detailed characterization of ion transport properties of the inward-rectifying (IK+,in) and the outward-rectifying (IK+,out) K+ conductance is presented here. The permeability ratios of IK+,in and IK+,out currents for K+ over monovalent alkali metal ions were determined. The resulting permeability sequences (PK+ greater than PRb+ greater than PNa+ greater than PLi+ much greater than PCs+) corresponded closely to the ion specificity of guard cell movements in V. faba. Neither K+ currents exhibited significant inactivation when K+ channels were activated for prolonged periods (greater than 10 min). The absence of inactivation may permit long durations of K+ fluxes, which occur during guard cell movements. Activation potentials of inward K+ currents were not shifted when external K+ concentrations were changed. This differs strongly from the behavior of inward-rectifying K+ channels in animal tissue. Blue light and fusicoccin induce hyperpolarization by stimulation of an electrogenic pump. From slow-whole-cell recordings it was concluded that electrogenic pumps require cytoplasmic substrates for full activation and that the magnitude of the pump current is sufficient to drive K+ uptake through IK+,in channels. First, direct evidence was gained for the hypothesis that IK+,in channels are a molecular pathway for K+ accumulation by the finding that IK+,in was blocked by Al3+ ions, which are known to inhibit stomatal opening but not closing. The results presented in this study strongly support a prominent role for IK+,in and IK+,out channels in K+ transport across the plasma membrane of guard cells.