Isolation and properties of Ca2+-transporting glycoprotein and peptide from beef heart mitochondria

The 40,000-dalton glycoprotein and 2000-dalton peptide inducing selective Ca²⁺-transport through bilayer lipid membranes were isolated from beef heart homogenate and mitochondria. Micromolar concentrations of these substances were found to increase the conductivity of membranes by 3–4 orders. Transmembrane Ca²⁺ gradient induces an electric potential difference whose magnitude is close to the theoretical for ideal Ca²⁺ selectivity. The inhibitor of mitochondrial Ca²⁺ transport, ruthenium red, abolishes both the glycoprotein-and peptide-induced Ca²⁺ transport in bilayer lipid membranes. Thiol groups essential for Ca²⁺ transport activity were revealed in the glycoprotein and peptide. Addition of these substances to rat liver mitochondria induces Ca²⁺-dependent inhibition of the state 3 respiration that can be released by uncouplers (oligomycin-like effect).     

Loss of membrane phospholipid asymmetry during activation of blood platelets and sickled red cells; mechanisms and physiological significance

Membrane phospholipid asymmetry is considered to be a general property of biological membranes. Detailed information is presently available on the non-random orientation of phospholipids in red cell- and platelet membranes. The outer leaflet of the lipid bilayer membrane is rich in choline-phospholipids, whereas amino-phospholipids are abundant in the inner leaflet. Studies with blood platelets have shown that these asymmetries are not maintained when the cells are activated in various ways. Undoing the normal asymmetry of membrane phospholipids in activated blood cells is presumably mediated by increased transbilayer movement of phospholipids. This process, which leads to increased exposure of negatively charged phosphatidylserine at the outer surface, plays an important physiological role in local blood clotting reactions. A similar phenomenon occurs in sickled red cells. Phospholipid vesicles breaking off from reversibly sickled cells contribute similarly to intravascular clotting in the crisis phase of sickle cell disease.The loss of membrane phospholipid asymmetry in activated platelets seems to be strictly correlated with degradation of cytoskeletal proteins by endogenous calpain. It is remarkable that membrane phospholipid asymmetry can be (partly) restored when activated platelets are treated with reducing agents. This leads to disappearance of phosphatidylserine from the outer leaflet where it was previously exposed during cell activation. These observations will be discussed in relation to two mechanisms which have been recognized to play a role in the regulation of membrane phospholipid asymmetry; i.e. the interaction of aminophospholipids to cytoskeletal proteins, and the involvement of a phospholipid-translocase catalyzing outward-inward transbilayer movement of amino-phospholipids.     

Isolation of calcium-transporting lipid from the mitochondrial glycolipoprotein

Summary From the mitochondrial Ca²⁺-transporting glycolipoprotein (GLP) the lipid was isolated which induced Ca²⁺-translocation through bilayer lipid membranes. Electroconductivity of modified phospholipid membranes in the presence of CaCl₂ is increased 150-200 times. At 10-fold CaCl₂ gradient a generation of membrane potential is observed close to its theoretical value. It is shown that the lipid forms separate conductivity channels of 10 and 20 pS in the bilayer. The mode of action of GLP in the membrane is proposed It is assumed that the carbohydrate part of GLP is a selective receptor-accumulator for Ca²⁻, whereas the function of the lipid component consists in forming channels in the bilayer.     

Regulation of transbilayer plasma membrane phospholipid asymmetry

Lipids in biological membranes are asymmetrically distributed across the bilayer; the amine-containing phospholipids are enriched on the cytoplasmic surface of the plasma membrane, while the choline-containing and sphingolipids are enriched on the outer surface. The maintenance of transbilayer lipid asymmetry is essential for normal membrane function, and disruption of this asymmetry is associated with cell activation or pathologic conditions. Lipid asymmetry is generated primarily by selective synthesis of lipids on one side of the membrane. Because passive lipid transbilayer diffusion is slow, a number of proteins have evolved to either dissipate or maintain this lipid gradient. These proteins fall into three classes: 1) cytofacially-directed, ATP-dependent transporters ("flippases"); 2) exofacially-directed, ATP-dependent transporters ("floppases"); and 3) bidirectional, ATP-independent transporters ("scramblases"). The flippase is highly selective for phosphatidylserine and functions to keep this lipid sequestered from the cell surface. Floppase activity has been associated with the ABC class of transmembrane transporters. Although they are primarily nonspecific, at least two members of this class display selectivity for their substrate lipid. Scramblases are inherently nonspecific and function to randomize the distribution of newly synthesized lipids in the endoplasmic reticulum or plasma membrane lipids in activated cells. It is the combined action of these proteins and the physical properties of the membrane bilayer that generate and maintain transbilayer lipid asymmetry.     

Palmitic Acid Induces the Opening of a Ca2+-Dependent Pore in the Plasma Membrane of Red Blood Cells: The Possible Role of the Pore in Erythrocyte Lysis

Earlier we found that in the presence of Ca²⁺ palmitic acid (Pal) increases the nonspecific permeability of artificial (planar and liposomal) membranes and causes permeabilization of the inner mitochondrial membrane. An assumption was made that the mechanism of Pal/Ca²⁺-induced membrane permeabilization relates to the Ca²⁺-induced phase separation of Pal and can be considered as formation of fast-tightening lipid pores due to chemotropic phase transition in the lipid bilayer. In this article, we continue studying this pore. We have found that Pal plus Ca²⁺ permeabilize the plasma membrane of red blood cells in a dose-dependent manner. The same picture has been revealed for stearic acid (20 μM) but not for myristic and linoleic acids. The Pal-induced permeabilization of erythrocytic membranes can also occur in the presence of Ba²⁺ and Mn²⁺ (200 μM), but other bivalent cations (200 μM Mg²⁺, Sr²⁺, Ni²⁺, Co²⁺) are relatively ineffective. The formation of Pal/Ca²⁺-induced pores in the erythrocytic membranes has been found to result in the destruction of cells.     

Passive transport of Ca2+ ions through lipid bilayers imaged by widefield second harmonic microscopy

In biology, release of Ca²⁺ ions in the cytosol is essential to trigger or control many cell functions. Calcium signaling acutely depends on lipid membrane permeability to Ca²⁺. For proper understanding of membrane permeability to Ca²⁺, both membrane hydration and the structure of the hydrophobic core must be taken into account. Here, we vary the hydrophobic core of bilayer membranes and observe different types of behavior in high-throughput wide-field second harmonic imaging. Ca²⁺ translocation is observed through mono-unsaturated (DOPC:DOPA) membranes, reduced upon the addition of cholesterol, and completely inhibited for branched (DPhPC:DPhPA) and poly-unsaturated (SLPC:SLPA) lipid membranes. We propose, using molecular dynamics simulations, that ion transport occurs through ion-induced transient pores, which requires nonequilibrium membrane restructuring. This results in different rates at different locations and suggests that the hydrophobic structure of lipids plays a much more sophisticated regulating role than previously thought.     

Ca2+-induced isotropic motion and phosphatidylcholine flip-flop in phosphatidylcholine-cardiolipin bilayers

Ca²⁺ induces a structural change in phosphatidylcholine-cardiolipin bilayers, which is visualised by freeze-fracturing as lipidic particles associated with the bilayer and is detected by ³¹P-NMR as isotropic motion of the phospholipids. In this structure a rapid transbilayer movement of phosphatidylcholine and a highly increased permeability towards Mn²⁺ are observed.     

The role of ion-lipid interactions and lipid packing in transient defects caused by phenolic compounds

The transient disruption of membranes for the passive permeation of ions or small molecules is a complex process relevant to understanding physiological processes and biotechnology applications. Phenolic compounds are widely studied for their antioxidant and antimicrobial properties, and some of these activities are based on the interactions of the phenolic compound with membranes. Ions are ubiquitous in cells and are known to alter the structure of phospholipid bilayers. Yet, ion-lipid interactions are usually ignored when studying the membrane-altering properties of phenolic compounds. This study aims to assess the role of Ca²⁺ ions on the membrane-disrupting activity of two phenolic acids and to highlight the role of local changes in lipid packing in forming transient defects or pores. Results from tethered bilayer lipid membrane electrical impedance spectroscopy experiments showed that Ca²⁺ significantly reduces membrane disruption by caffeic acid methyl ester and caffeic acid. As phenolic acids are known metal chelators, we used UV-vis and fluorescence spectroscopy to exclude the possibility that Ca²⁺ interferes with membrane disruption by binding to the phenolic compound and subsequently preventing membrane binding. Molecular dynamics simulations showed that Ca²⁺ but not caffeic acid methyl ester or caffeic acid increases lipid packing in POPC bilayers. The combined data confirm that Ca²⁺ reduces the membrane-disrupting activity of the phenolic compounds, and that Ca²⁺-induced changes to lipid packing govern this effect. We discuss our data in the context of ion-induced pores and transient defects and how lipid packing affects membrane disruption by small molecules.     

Chemically induced lipid phase separation in model membranes containing charged lipids: A spin label study

The lipid distribution in binary mixed membranes containing charged and uncharged lipids and the effect of Ca²⁺ and polylysine on the lipid organization was studied by the spin label technique. Dipalmitoyl phosphatidic acid was the charged, and spin labelled dipalmitoyl lecithin was the uncharged (zwitterionic) component. The ESR spectra were analyzed in terms of the spin exchange frequency, W_ex. By measuring W_ex as a function of the molar percentage of labelled lecithin a distinction between a random and a heterogeneous lipid distribution could be made. It is established that mixed lecithinphosphatidic acid membranes exhibit lipid segregation (or a miscibility gap) in the fluid state. Comparative experiments with bilayer and monolayer membranes strongly suggest a lateral lipid segregation. At low lecithin concentration, aggregates containing between 25% and 40% lecithin are formed in the fluid phosphatidic acid membrane. This phase separation in membranes containing charged lipids is understandable on the basis of the Gouy-Chapman theory of electric double layers.In dipalmitoyl lecithin and in dimyristoyl phosphatidylethanolamine membranes the labelled lecithin is randomly distributed above the phase transition and has a coefficient of lateral diffusion of D = 2.8·10^?8 cm²/s at 59°C.Addition of Ca²⁺ dramatically increases the extent of phase separation in lecithin-phosphatidic acid membranes. This chemically (and isothermally) induced phase separation is caused by the formation of crystalline patches of the Ca²⁺-bound phosphatidic acid. Lecithin is squeezed out from these patches of rigid lipid. The observed dependence of W_ex on the Ca²⁺ concentration could be interpreted quantitatively on the basis of a two-cluster model. At low lecithin and Ca²⁺ concentration clusters containing about 30 mol% lecithin are formed. At high lecithin or Ca²⁺ concentrations a second type of precipitation containing 100% lecithin starts to form in addition. A one-to-one binding of divalent ions and phosphatidic acid at pH 9 was assumed. Such a one-to-one binding at pH 9 was established for the case of Mn²⁺ using ESR spectroscopy.Polylysine leads to the same strong increase in the lecithin segregation as Ca²⁺. The transition of the phosphatidic acid bound by the polypeptide is shifted from T_t = 47.5° to T_t = 62°C. This finding suggests the possibility of cooperative conformational changes in the lipid matrix and in the surface proteins in biological membranes.     

Decoding P4-ATPase substrate interactions

Cellular membranes display a diversity of functions that are conferred by the unique composition and organization of their proteins and lipids. One important aspect of lipid organization is the asymmetric distribution of phospholipids (PLs) across the plasma membrane. The unequal distribution of key PLs between the cytofacial and exofacial leaflets of the bilayer creates physical surface tension that can be used to bend the membrane; and like Ca²⁺, a chemical gradient that can be used to transduce biochemical signals. PL flippases in the type IV P-type ATPase (P4-ATPase) family are the principle transporters used to set and repair this PL gradient and the asymmetric organization of these membranes are encoded by the substrate specificity of these enzymes. Thus, understanding the mechanisms of P4-ATPase substrate specificity will help reveal their role in membrane organization and cell biology. Further, decoding the structural determinants of substrate specificity provides investigators the opportunity to mutationally tune this specificity to explore the role of particular PL substrates in P4-ATPase cellular functions. This work reviews the role of P4-ATPases in membrane biology, presents our current understanding of P4-ATPase substrate specificity, and discusses how these fundamental aspects of P4-ATPase enzymology may be used to enhance our knowledge of cellular membrane biology.     

Interactions of phenytoin with rat brain synaptosomes examined by fluorescent fatty acid probes

Phenytoin (PHT) modified the fluorescent characteristics of anthroyloxy-fatty acids in synaptosomal membranes. Association of PHT with synaptosomal membranes caused the greatest change when the fluorescent probe was located at the 6-carbon position of N-(anthroyloxy)stearic acid and was incorporated into the membranes. Phenytoin and 6-(anthroyloxy)stearic acid compete for high affinity binding regions which are probably lipid domains within the membrane. Phenytoin has a weaker association with the sites than the fluorescent fatty acids. Divalent cations, e.g. Mg²⁺ or Ca²⁺, are required to observe maximal change in polarization of fluorescence of fatty acid probes in the presence of PHT. It is proposed that the membrane lipid bilayer reorganizes to accommodate exogenous compounds, such as phenytoin or the fatty acid probe in order to permit the most efficient packing of lipids. This reorganization of the lipid bilayer may influence membrane enzyme activities and ion channels.     

The Calcium-Dependent and Calcium-Independent Membrane Binding of Synaptotagmin 1: Two Modes of C2B Binding

The Ca²⁺-independent membrane interactions of the soluble C2 domains from synaptotagmin 1 (syt1) were characterized using a combination of site-directed spin labeling and vesicle sedimentation. The second C2 domain of syt1, C2B, binds to membranes containing phosphatidylserine and phosphatidylcholine in a Ca²⁺-independent manner with a lipid partition coefficient of approximately 3.0 × 10² M^− 1. A soluble fragment containing the first and second C2 domains of syt1, C2A and C2B, has a similar affinity, but C2A alone has no detectable affinity to phosphatidylcholine/phosphatidylserine bilayers in the absence of Ca²⁺. Although the Ca²⁺-independent membrane affinity of C2B is modest, it indicates that this domain will never be free in solution within the cell. Site-directed spin labeling was used to obtain bilayer depth restraints, and a simulated annealing routine was used to generate a model for the membrane docking of C2B in the absence of Ca²⁺. In this model, the polybasic strand of C2B forms the membrane binding surface for the domain; however, this face of C2B does not penetrate the bilayer but is localized within the aqueous double layer when C2B is bound. This double-layer location indicates that C2B interacts in a purely electrostatic manner with the bilayer interface. In the presence of Ca²⁺, the membrane affinity of C2B is increased approximately 20-fold, and the domain rotates so that the Ca²⁺-binding loops of C2B insert into the bilayer. This Ca²⁺-triggered conformational change may act as a switch to modulate the accessibility of the polybasic face of C2B and control interactions of syt1 with other components of the fusion machinery.     

Relation between lipid polymorphism and transbilayer movement of lipid in rat liver microsomes

We have studied the effects of trinitrophenylation on the transbilayer movement of phosphatidylcholine and the macroscopic lipid structure in rat liver microsomal membranes. The transbilayer movement of phosphatidylcholine was investigated using the PC-specific transfer protein. ³¹P-NMR was employed to monitor the phospholipid organization in intact microsomal vesicles. The results indicate that modification of microsomes with trinitrobenzenesulfonic acid enhances the transbilayer movement of phosphatidylcholine at 4°C. Furthermore, phosphatidylethanolamine headgroup trinitrophenylation in microsomes increases the isotropic component in the ³¹P-NMR spectra even at 4°C, possibly representing the appearance of intermediate non-bilayer lipid structures. The observed parallel between these data suggests that phosphatidylethanolamine molecules in the microsomal membrane, probably in combination with a protein component, are able to destabilize the bilayer organization, thereby facilitating the transmembrane movement of phospholipids.     

Synthetic peptide K+ carrier with Ca2+ inhibition

Based on a proposed solution conformation of the Ca²⁺ ion complex of the repeat hexapeptide of elastin, l-Val-l-Ala-l-Pro-Gly-l-Val-Gly, it is possible to modify the molecule making it more lipophilic for lipid bilayer permeation while retaining its complexation features. Therefore the two peptides, For-MeVal-Ala-Pro-Sar-Pro-Sar-OMe and For-MeVal-Ala-Pro-Sar-Pro-Sar-OH, were synthesized and evaluated for lipid bilayer activity and cation binding (For, N-formyl; Me, N-methyl; Sar, N-methyl glycine). Both peptides bound Ca²⁺ preferentially but did not exhibit the properties of a Ca²⁺ carrier. They were however active as K⁺ carriers although K⁺ ion titration curves showed a much lower affinity for K⁺ than for Ca²⁺. The addition of Ca²⁺ or Mg²⁺ to the bilayer system inhibited the peptide K⁺ carrier activity. Three possible explanations of this interesting Ca²⁺ inhibition of carrier activity are irreversible complexation of Ca²⁺, mixed ligand complex formation involving Ca²⁺, lipid and peptide, and impermeability of the lipid layer when peptide is complexed with a divalent cation.     

Minocycline chelates Ca<Superscript>2+</Superscript>, binds to membranes,and depolarizes mitochondria by formation of Ca<Superscript>2+</Superscript>-dependent ion channels

Minocycline (an anti-inflammatory drug approved by the FDA) has been reported to be effective in mouse models of amyotrophic lateral sclerosis and Huntington disease. It has been suggested that the beneficial effects of minocycline are related to its ability to influence mitochondrial functioning. We tested the hypothesis that minocycline directly inhibits the Ca²⁺-induced permeability transition in rat liver mitochondria. Our data show that minocycline does not directly inhibit the mitochondrial permeability transition. However, minocycline has multiple effects on mitochondrial functioning. First, this drug chelates Ca²⁺ ions. Secondly, minocycline, in a Ca²⁺-dependent manner, binds to mitochondrial membranes. Thirdly, minocycline decreases the proton-motive force by forming ion channels in the inner mitochondrial membrane. Channel formation was confirmed with two bilayer lipid membrane models. We show that minocycline, in the presence of Ca²⁺, induces selective permeability for small ions. We suggest that the beneficial action of minocycline is related to the Ca²⁺-dependent partial uncoupling of mitochondria, which indirectly prevents induction of the mitochondrial permeability transition.     

Transmembrane Lipid Migration in Planar Asymmetric Bilayer Membranes

Planar asymmetric bilayer membranes, formed by apposing a monolayer of the neutral lipid glyceroldioleate (GDO) with one of the negatively charged lipid oleyl acid phosphate (OAP), were used to measure the rate of transmembrane OAP migration. The assay for this lipid flip-flop was the interaction of Ca²⁺ ions with negatively charged lipids which causes membranes to break: when Ca²⁺ is added to the compartment limited initially by the neutral lipid, flip-flop of the charged lipid eventually results in membrane breakdown. At 22 ± 2°C, in the absence of an externally applied electric field, an upper limit to the half time of OAP flip-flop was measured as 18.7 h, with a tentative lower limit of 14.4 h.     

Ca2+-dependent mechanism of membrane insertion and destabilization by the SARS-CoV-2 fusion peptide

Cell penetration after recognition of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) virus by the ACE2 receptor and the fusion of its viral envelope membrane with cellular membranes are the early steps of infectivity. A region of the Spike protein of the virus, identified as the “fusion peptide” (FP), is liberated at its N-terminal site by a specific cleavage occurring in concert with the interaction of the receptor-binding domain of the Spike. Studies have shown that penetration is enhanced by the required binding of Ca²⁺ ions to the FPs of coronaviruses, but the mechanisms of membrane insertion and destabilization remain unclear. We have predicted the preferred positions of Ca²⁺ binding to the SARS-CoV-2-FP, the role of Ca²⁺ ions in mediating peptide-membrane interactions, the preferred mode of insertion of the Ca²⁺-bound SARS-CoV-2-FP, and consequent effects on the lipid bilayer from extensive atomistic molecular dynamics simulations and trajectory analyses. In a systematic sampling of the interactions of the Ca²⁺-bound peptide models with lipid membranes, SARS-CoV-2-FP penetrated the bilayer and disrupted its organization only in two modes involving different structural domains. In one, the hydrophobic residues F833/I834 from the middle region of the peptide are inserted. In the other, more prevalent mode, the penetration involves residues L822/F823 from the LLF motif, which is conserved in CoV-2-like viruses, and is achieved by the binding of Ca²⁺ ions to the D830/D839 and E819/D820 residue pairs. FP penetration is shown to modify the molecular organization in specific areas of the bilayer, and the extent of membrane binding of the SARS-CoV-2 FP is significantly reduced in the absence of Ca²⁺ ions. These findings provide novel mechanistic insights regarding the role of Ca²⁺ in mediating SARS-CoV-2 fusion and provide a detailed structural platform to aid the ongoing efforts in rational design of compounds to inhibit SARS-CoV-2 cell entry.     

Lipid distribution in Acholeplasma laidlawii membrane. A study using the lactoperoxidase-mediated iodination

The lactoperoxidase-mediated radioiodination has been applied to study the transbilayer distribution of phospho- and glycolipids in Acholeplasma laidlawii membranes. After radioiodination, about 5% of the ¹²⁵I-iodine was found in membrane lipids. A comparison of the labeling intensities of the various lipid species between iodinated intact cells and isolated membranes revealed that the glycolipids monoglucosyldiglyceride and diglucosyldiglyceride are located almost exclusively in the outer half of the bilayer, whereas the phospholipids phosphatidylglycerol and diphosphatidylglycerol as well as the phosphoglycolipids glycerophosphoryl-diglucosyldiglyceride and glycerophosphoryl-monoglucosyldiglyceride are almost equally distributed in the outer and inner halves of A. laidlawii membranes.     

Barrier properties of glycophorin-phospholipid systems prepared by different methods

Glycophorin was incorporated into large unilamellar dioleoylphosphatidylcholine vesicles by either a detergent dialysis method using octylglucoside or a method avoiding the use of detergents. The vesicles were characterized and the permeability properties and transbilayer movement of lipids in both vesicles were investigated as a function of the protein concentration and were compared to protein-free vesicles. An insight in the permeability properties of the vesicles was obtained by monitoring the ratio potassium (permeant): dextran (impermeant) trap immediately after separation of the vesicles from the external medium. Glycophorin incorporated without the use of detergents in 1:300 protein:lipid molar ratio induces a high potassium permeability for the majority of the vesicles as judged from the low potassium trap (K⁺:dextran trap = 0.21). In contrast, the vesicles in which glycophorin is incorporated via the octylglucoside method (1:500 protein:lipid molar ratio) are much less permeable to potassium (K⁺:dextran trap = 0.67 and $\text{t}\text{1}\text{2}$ of potassium efflux at 22°C is 7.5 h.). The relationship between protein-induced bilayer permeability and lipid transbilayer movement in both vesicle preparations is discussed. Addition of wheat-germ agglutinin to glycophorin-containing vesicles comprised of dioleoylphosphatidylcholine and total erythrocyte lipids caused no or just a small effect (less than 20% release of potassium) on the potassium permeability of these vesicles. Also, addition of lectin to dioleoylphosphatidylethanolamine-glycophorin bilayer vesicles in a 25:1 lipid:glycophorin molar ratio had no effect on the permeability characteristics of the vesicles. In contrast, addition of wheat-germ agglutinin to bilayer vesicles made of dioleoylphosphatidylethanolamine and glycophorin in a 200:1 molar ratio resulted in a release of 74% of the enclosed potassium by triggering a bilayer to hexagonal (H_II) phase transition. The role of protein aggregation and the formation of defects in the lipid bilayer on membrane permeability and lipid transbilayer movement is discussed.     

pH modulation of large conductance potassium channel from adrenal chromaffin granules

We report here that large conductance K⁺ selective channel in adrenal chromaffin granules is controlled by pH. We measured electrogenic influx of ⁸⁶Rb⁺ into chromaffin granules prepared from bovine adrenal gland medulla. The ⁸⁶Rb⁺ influx was inhibited by acidic pH. Purified chromaffin granule membranes were also fused with planar lipid bilayer. A potassium channel with conductance of 432±9 pS in symmetric 450 mM KCl was observed after reconstitution into lipid bilayer. The channel activity was unaffected by charybdotoxin, a blocker of the Ca²⁺-activated K⁺ channel of large conductance. It was observed that acidification to pH 6.4 cis side of the membrane lowered the channel open probability and single channel conductance. Whereas only weak influence on the single channel current amplitude and open probability were observed upon lowering of the pH at the trans side. We conclude that a pH-sensitive large conductance potassium channel operates in the chromaffin granule membrane.