Steroid hormone-induced effects on membrane fluidity and their potential roles in non-genomic mechanisms

Steroid hormones are lipophilic suggesting they intercalate into the bilayer of target cell plasma membranes, potentially altering the fluidity and function of the membrane. The present study measured the effects of steroidal exposure on both phospholipid fluidity and integral protein mobility. Studies were performed on the effects of a variety of steroids on phosphatidylcholine liposomes, synaptosomal plasma membranes and sarcoplasmic reticulum membranes. Progesterone decreased the lipid fluidity, whereas testosterone had no effect on lipid movement. The estrogen, 17 beta-estradiol, an aromatised metabolite of testosterone, increased lipid mobility. In each case, the steroid action was concentration-dependent. The steroids all increased the activity of the Ca2+ ATPase of SR membrane, in keeping with their effects on this enzyme's aggregation state. The results suggest that, although lipid fluidity is a factor influencing protein activity, their mobility within the bilayer is the primary determinant of enzyme activity in the membrane for most proteins.     

Innate immune and non-immune mediators of erythrocyte clearance.

Erythrocyte clearance is reviewed in the context of what is known in 2003 on clearance of apoptotic cells in vitro and in vivo. Thus, emphasis is put on the role of the innate immune system comprised of naturally occurring autoantibodies (NAbs) and complement. Oxidative damage, cellular senescence and diffusion-controlled exoplasmic cross-linking appear to generate oligomers of band 3 (anion transport protein) that are a prerequisite for anti-band 3 NAb binding to human red blood cells (RBC). Similar processes seem to be responsible for premature RBC clearance in hemoglobinopathies and membrane protein deficiencies. The review discusses why NAb binding alone is insufficient and how bound NAbs may enhance complement deposition. Clearance of RBC is not only the result of cell-bound opsonins, but is enhanced by the loss of RBC membrane constituents, such as CD47 and sialic acids. As long as these constituents are present on RBC in normal numbers and topologic arrangement, they bind to their respective receptors on macrophages, elicit a negative signal that appears to prevent the macrophage from engulfing bound RBC. Exposure of phosphatidylserine is not a primary signal for RBC removal and where exposed it initiates binding of CRP or of beta-2-glycoprotein I and NAbs.     

Transbilayer distribution and mobility of phosphatidylinositol in human red blood cells

The present studies describe the distribution of phosphatidylinositol (PI) within the membrane bilayer of the human red blood cell (RBC) as well as its transbilayer mobility. The membrane bilayer distribution was determined by measuring the hydrolysis of PI in the exterior leaflet of the RBC membrane using a PI-specific phospholipase C and by extraction of PI from the exterior leaflet using bovine serum albumin. The transbilayer mobility of PI was measured by following the fate of radiolabeled PI which was first incorporated into the outer leaflet of the RBC membrane. Our results indicate that PI is asymmetrically distributed in the membrane, with approximately 80% located in the inner and 20% in the outer leaflet of the bilayer. The rate of transbilayer mobility of PI is similar to that for certain molecular species of phosphatidylcholine and much slower than that reported for the aminophospholipids in the RBC membrane.     

Novel Nongenomic Signaling by Glucocorticoid May Involve Changes to Liver Membrane Order in Rainbow Trout

Stress-induced glucocorticoid elevation is a highly conserved response among vertebrates. This facilitates stress adaptation and the mode of action involves activation of the intracellular glucocorticoid receptor leading to the modulation of target gene expression. However, this genomic effect is slow acting and, therefore, a role for glucocorticoid in the rapid response to stress is unclear. Here we show that stress levels of cortisol, the primary glucocorticoid in teleosts, rapidly fluidizes rainbow trout (Oncorhynchus mykiss) liver plasma membranes in vitro. This involved incorporation of the steroid into the lipid domains, as cortisol coupled to a membrane impermeable peptide moiety, did not affect membrane order. Studies confirmed that cortisol, but not sex steroids, increases liver plasma membrane fluidity. Atomic force microscopy revealed cortisol-mediated changes to membrane surface topography and viscoelasticity confirming changes to membrane order. Treating trout hepatocytes with stress levels of cortisol led to the modulation of cell signaling pathways, including the phosphorylation status of putative PKA, PKC and AKT substrate proteins within 10 minutes. The phosphorylation by protein kinases in the presence of cortisol was consistent with that seen with benzyl alcohol, a known membrane fluidizer. Our results suggest that biophysical changes to plasma membrane properties, triggered by stressor-induced glucocorticoid elevation, act as a nonspecific stress response and may rapidly modulate acute stress-signaling pathways.     

Alterations in human red blood cell membrane properties induced by the lipopolysaccharide from Proteus mirabilis S1959

The effect of lipopolysaccharide (LPS, endotoxin), isolated from Proteus mirabilis S1959 strain, on red blood cell (RBC) membranes in whole cells as well as on isolated membranes was studied. Lipid membrane fluidity, conformational state of membrane proteins and the osmotic fragility of RBCs were examined using electron paramagnetic resonance spectroscopy and spectrophotometric method. Lipid membrane fluidity was determined using three spin-labeled fatty acids: 5-, 12- and 16-doxylstearic acid (5-, 12- and 16-DS). The addition of LPS S1959 to RBC suspension resulted in an increase in membrane fluidity, as indicated by 12-DS. At the concentrations of 0.5 and 1 mg/ml, LPS treatment led to a significant (P<0.05) increase in lipid membrane fluidity in the deeper region of lipid bilayer (determined by 12-DS). The conformational changes in membrane proteins were determined using two covalently bound spin labels, 4-maleimido-2,2,6,6-tetramethylpiperidine-1-oxyl and 4-iodoacetamido-2,2,6,6-tetramethylpiperidine-1-oxyl (ISL). The highest concentration of endotoxin significantly (P<0.05) decreased the relative rotational correlation time of ISL and significantly (P<0.05) increased the osmotic fragility of RBCs. The effect of endotoxin was much more profound in isolated membranes than in intact cells treated with LPS. At the concentrations 0.5 and 1 mg/ml, LPS led to a significant increase in h(w)/h(s) ratio. These results indicated increased membrane protein mobility, mainly in the spectrin-actin complex in membrane cytoskeleton. These data suggest that LPS-induced alterations in membrane lipids and cytoskeleton proteins of RBCs lead to loss of membrane integrity.     

Staphylococcal Phenotypes Induced by Naturally Occurring and Synthetic Membrane-Interactive Polyphenolic β-Lactam Resistance Modifiers

Galloyl catechins, in particular (-)-epicatechin gallate (ECg), have the capacity to abrogate β-lactam resistance in methicillin-resistant strains of Staphylococcus aureus (MRSA); they also prevent biofilm formation, reduce the secretion of a large proportion of the exoproteome and induce profound changes to cell morphology. Current evidence suggests that these reversible phenotypic traits result from their intercalation into the bacterial cytoplasmic membrane. We have endeavoured to potentiate the capacity of ECg to modify the MRSA phenotype by stepwise removal of hydroxyl groups from the B-ring pharmacophore and the A:C fused ring system of the naturally occurring molecule. ECg binds rapidly to the membrane, inducing up-regulation of genes responsible for protection against cell wall stress and maintenance of membrane integrity and function. Studies with artificial membranes modelled on the lipid composition of the staphylococcal bilayer indicated that ECg adopts a position deep within the lipid palisade, eliciting major alterations in the thermotropic behaviour of the bilayer. The non-galloylated homolog (-)-epicatechin enhanced ECg-mediated effects by facilitating entry of ECg molecules into the membrane. ECg analogs with unnatural B-ring hydroxylation patterns induced higher levels of gene expression and more profound changes to MRSA membrane fluidity than ECg but adopted a more superficial location within the bilayer. ECg possessed a high affinity for the positively charged staphylococcal membrane and induced changes to the biophysical properties of the bilayer that are likely to account for its capacity to disperse the cell wall biosynthetic machinery responsible for β-lactam resistance. The ability to enhance these properties by chemical modification of ECg raises the possibility that more potent analogs could be developed for clinical evaluation.     

Characterization of cortisol binding sites in chicken liver plasma membrane

1. The presence of sites specifically binding [3H]cortisol in plasma membrane isolated from chicken liver has been determined. The kinetic parameters of this binding are: Kd = 4.5 nM and Bmax = 2225 fmol/mg protein in presence of 10(-6) M progesterone. 2. The affinities of several natural and synthetic steroids for the membrane binding site respect to the binding of 4 nM [3H]cortisol without competitor increased in the following order: Testosterone less than pregnenone less than dexamethasone less than progesterone less than prednisolone less than corticosterone less than deoxycorticosterone. 3. Other steroids such as estradiol, ouabain and triamcinolone acetonide does not bind to the plasma membrane. 4. Metal ions such as Ca2+ and Mg2+ did not modify the binding of [3H]cortisol. 5. Neither propranolol nor phentolamine, beta- and alpha-adrenergic antagonists affected [3H]cortisol binding to the plasma membranes. 6. The result suggest that the binding site detected is more specific for glucocorticoids and it is different of nuclear glucocorticoid receptor and progesterone receptor.     

Characterization of immunoglobulin binding to isolated human erythrocyte membranes: evidence for selective, temperature-induced binding of naturally occurring autoantibodies to the cytoskeleton

Human plasma contains naturally occurring autoantibodies to the predominant components of the erythrocyte membrane: band 3 and spectrin bands 1 and 2 of the cytoskeleton. The titer of cytoskeletal plasma autoantibodies increases in various hemolytic conditions, suggesting that opsonization of the cytoskeleton may play an important role in the clearance of hemolyzed (not senescent) erythrocytes from the circulation. In this study, we use Alexa Fluor 488 goat anti-human IgG conjugate (Molecular Probes, Eugene, OR, USA), to characterize plasma immunoglobulin binding to erythrocyte membranes from osmotically hemolyzed cells ('ghosts'). The results show that exposure of ghosts to plasma results in 4-fold more immunoglobulin binding to the cytoskeleton than is bound to the proteins contained within the lipid bilayer. Preincubation of the ghosts at 37 degrees C causes 8-fold more immunoglobulin binding to the cytoskeleton compared to bilayer proteins. This temperature-induced change resulted from selective immunoglobulin binding to the cytoskeleton, with no change in immunoglobulin binding to bilayer proteins. However, the rate of increase in cytoskeletal antigenicity at 37 degrees C did correlate with the rate of a conformational change in band 3, a transmembrane protein which serves as a major membrane attachment site for the cytoskeleton. The results of this study suggest that the cytoskeleton is the primary target in the opsonization of hemolyzed erythrocyte membranes by naturally occurring plasma autoantibodies. The conformational changes which occur in ghosts at 37 degrees C are associated with selective exposure of new immunoglobulin binding sites on the cytoskeleton, and with a change in the structure of band 3. We propose a model suggesting that opsonization of the cytoskeleton occurs prior to the decomposition of hemolyzed erythrocytes at 37 degrees C.     

Orientation and motion of spin-labels in rabbit small intestinal brush border vesicle membranes

The temperature dependence of the packing (order) and fluidity (microviscosity) of rabbit small, intestinal brush border vesicle membranes and of liposomes made from their extracted lipids has been investigated by using a variety of lipid spin probes. The lipids in the brush border membrane are present essentially as a bilayer. Compared to other mammalian membranes, the brush border membrane appears to be characterized by a relatively high packing order as well as microviscosity. At body temperature, the lipid molecules undergo rapid, anisotropic motion, which is essentially a fast rotation about an axis approximately perpendicular to the bilayer normal. Both the order (motional anisotropy) and the microviscosity increase with decreasing temperature and with increasing distance from the center of the bilayer. Qualitatively similar motional or fluidity gradients have been reported for other mammalian and bacterial membranes. The liposomes made from the extracted lipids have a somewhat lower packing order and a slightly higher fluidity than brush border vesicle membranes. The differences are, however, small indicating that the packing and the fluidity (microviscosity) of the membrane are primarily determined by the lipid composition. Membrane-associated proteins and cytoskeleton cannot play a dominant role in determining the order and fluidity of the lipid bilayer. Discontinuities are observed in the temperature dependence of various spectral parameters, the order parameter S, the rotational correlation time tau, and 2,2,6,6-tetramethylpiperidinyloxy partitioning. They are assigned to phase transitions and/or phase separations of the membrane lipids. These discontinuities occur at about 30, 20, and 13 degrees C for 5-doxyl-, 12-doxyl-, and 16-doxylstearic acid, respectively. The apparent transition temperature depends on the location of the spin probe along the bilayer normal, being higher the closer the probe is to the membrane surface. This indicates the possibility that chain melting is progressive and spreads with increasing temperature from the center of the membrane outward.     

Effects of physical states of phospholipids on the incorporation and cytochalasin B binding activity of human erythrocyte membrane proteins in reconstituted vesicles

Proteoliposomes were reconstituted from a Triton extract of human erythrocyte membrane proteins and a mixture of phosphatidylcholine (PC) and phosphatidylethanolamine (PE) of varying ratios. With mixtures of egg PC and soybean PE, the protein/lipid ratio of the reconstituted vesicles was maximal at 25% PC and 75% PE, the composition which is known to have a maximum bilayer disruption (highest occurrence of lipidic particles seen by freeze-fracture electron microscopy). With mixtures of 1-palmitoyl-2-oleoyl-PC and dilinoleoyl-PE, which gave vesicles with few isolated lipidic particles at room temperature, the effect was less pronounced. The specific activity of the cytochalasin B (CB) binding protein in the reconstituted vesicles, on the other hand, was increased monotonically up to severalfold as the PC content was increased in the egg PC/soybean PE mixture. A similar increase was observed when soybean PE was partially substituted by dimyristoyl-PC, cholesterol, or transphosphatidylated PE from egg PC. These findings indicate that preexisting defects in the lipid bilayer promote protein incorporation into the bilayer during reconstitution whereas reduction of the bilayer fluidity facilitates the CB binding activity in the reconstituted vesicles.     

Plasmon resonance studies of agonist/antagonist binding to the human delta-opioid receptor: new structural insights into receptor-ligand interactions

Structural changes accompanying the binding of ligands to the cloned human delta-opioid receptor immobilized in a solid-supported lipid bilayer have been investigated using coupled plasmon-waveguide resonance spectroscopy. This highly sensitive technique directly monitors mass density, conformation, and molecular orientation changes occurring in anisotropic thin films and allows direct determination of binding constants. Although both agonist binding and antagonist binding to the receptor cause increases in molecular ordering within the proteolipid membrane, only agonist binding induces an increase in thickness and molecular packing density of the membrane. This is a consequence of mass movements perpendicular to the plane of the bilayer occurring within the lipid and receptor components. These results are consistent with models of receptor function that involve changes in the orientation of transmembrane helices.     

Interaction of flavonoids with red blood cell membrane lipids and proteins: antioxidant and antihemolytic effects

Plant flavonoids are emerging as potent therapeutic drugs effective against a wide range of free radical mediated diseases. Hence their interactions with cell membranes, which generally serve as targets for lipid peroxidation, are of enormous interest. Here we report in vitro studies, via absorption and fluorescence spectroscopy, on the effects of several flavonoids (namely fisetin, quercetin, chrysin, morin, and 3-hydroxyflavone, 3-HF) in goat RBC membranes. Owing to the presence of functionally relevant membrane protein components embedded in the lipid bilayer RBC ghosts provide a more realistic system for exploring drug actions in biomembranes than simpler membrane models like phosphatidylcholine liposomes used in our previous studies [e.g. B. Sengupta, A. Banerjee, P.K. Sengupta, FEBS Lett. 570 (2004) 77-81]. Here, we demonstrate that binding of the flavonoids to the RBC membranes significantly inhibits lipid peroxidation, and at the same time enhances their integrity against hypotonic lysis. Interestingly, the antioxidant and antihemolytic activities are found to be crucially dependent on the locations of the flavonoids in the membrane matrix as revealed by fluorescence studies. Furthermore, we observe that FRET (from membrane protein tryptophans to flavonoids) occurs with significant efficiency indicating that the flavonoid binding sites lie in close proximity to the tryptophan residues in the ghost membrane proteins.     

Effects of r—HuEPO on the biophysical characteristics of erythrocyte membrane in patients with anemia of chronic renal failure

Using electron spin resonance (ESR) spin labeling technique,we have studied the conformation of sulfhydryl groups(-SH) binding sites in membrane proteins and mem brane fluidity of red blood cells(RBCs) from two groups of patients with anemia of chronic renal failure(ACRF).One of the groups is composed of patients who were untreated with recombinant human erythropoietin(r-HuEPO),and the other is composed of patients who were treated with r-HuEPO.The results indicated:1)the conformation of SH group binding site in RBC membrane proteins from former group was different from those of healty people.2)the fluidity in the region near the surface of RBC membrane from former group was lower than those of healthy people.3)However,the above biophysical properties of RBC membrane from later group were normal.We concluded that RBC membrane in patients with ACRF was abnormal,and the treatment of r-HuEPO may promote the production of normal RBCs,thus ameliorate the biophysical properties of RBCs from the patients with ACRF.     

Bilayer Thickness and Curvature Influence Binding and Insertion of a pHLIP Peptide

The physical properties of lipid bilayers, such as curvature and fluidity, can affect the interactions of polypeptides with membranes, influencing biological events. Additionally, given the growing interest in peptide-based therapeutics, understanding the influence of membrane properties on membrane-associated peptides has potential utility. pH low insertion peptides (pHLIPs) are a family of water-soluble peptides that can insert across cell membranes in a pH-dependent manner, enabling the use of pH to follow peptide-lipid interactions. Here we study pHLIP interactions with liposomes varying in size and composition, to determine the influence of several key membrane physical properties. We find that pHLIP binding to bilayer surfaces at neutral pH is governed by the ease of access to the membrane’s hydrophobic core, which can be facilitated by membrane curvature, thickness, and the cholesterol content of the membrane. After surface binding, if the pH is lowered, the kinetics of pHLIP folding to form a helix and subsequent insertion across the membrane depends on the fluidity and energetic dynamics of the membrane. We showed that pHLIP is capable of forming a helix across lipid bilayers of different thicknesses at low pH. However, the kinetics of the slow phase of insertion corresponding to the translocation of C-terminal end of the peptide across lipid bilayer, vary approximately twofold, and correlate with bilayer thickness and fluidity. Although these influences are not large, local curvature variations in membranes of different fluidity could selectively influence surface binding in mixed cell populations.     

Lipid organization regulates annexin A2 Ca(2+)-sensitivity for membrane bridging and its modulator effects on membrane fluidity

Annexin A2 (AnxA2) is a phospholipid binding protein that has been implicated in many membrane-related cellular functions. AnxA2 is able to bind different acidic phospholipids such as phosphatidylserine (PS) and phosphatidylinositol-4,5-bisphosphate (PI2P). This binding is mediated by Ca(2+)-dependent and Ca(2+)-independent mechanisms. The specific functions of annexin A2 related to these two phospholipids and the molecular mechanisms involved in their interaction remain obscure. Herein we studied the influence of lipid composition on the Ca(2+)-dependency of AnxA2-mediated membrane bridging and on membrane fluidity. Membrane models of ten different lipid compositions and detergent-resistant membranes from two cellular sources were investigated. The results show that the AnxA2-mediated membrane bridging requires 3 to 50 times less calcium for PS-membranes than for PI2P-membranes. Membrane fluidity was measured by the ratiometric fluorescence parameter generalized polarization method with two fluorescent probes. Compared to controls containing low phospholipid ligand, AnxA2 was found to reduce the membrane fluidity of PI2P-membranes twice as much as the PS-membranes in the presence of calcium. On the contrary, at mild acidic pH in the absence of calcium AnxA2 reduces the fluidity of the PS-membranes more than the PI2P-membranes. The presence of cholesterol on the bilayer reduced the AnxA2 capacity to reduce membrane fluidity. The presented data shed light on the specific roles of PI2P, PS and cholesterol present on membranes related to the action of annexin A2 as a membrane bridging molecule during exocytosis and endocytosis events and as a plasma membrane domain phospholipid packing regulator.     

肺叶切除术对红细胞及淋巴细胞膜流动性的影响

目的：研究肺叶切除术对红细胞及淋巴细胞膜流坳性的影响。方法：选择２０例择期开胸手术病人,均作肺叶切除术。分别用微量滴定法、高效液权色谱法和ＤＰＨ荧光探剂法测定血浆和红细胞膜ＰＬＡ２活性,红细胞膜磷脂ＰＳ、ＰＥ、ＰＣ和红细胞、淋巴膜脂流动性。结果：手术１０ｍｉｎ、手术６０ｍｉｎ和手术结束后３０ｍｉｎ血浆和红细胞膜ＰＬＡ２活性均显著高于麻醉诱导前;手术６０ｍｉｎ和手术结束后３０ｍｉｎ 红细胞膜ＰＳ、Ｐ     

Change in membrane fluidity induced by polyphenols is highly dependent on the position and number of galloyl groups

The cell membrane fluidity was very important in adipogenesis and galloyl groups on polyphenolic structures could enhance their antiadipogenic activity. However, the effect of polyphenols on membrane fluidity and the role of galloyl groups in fluidity changes remain unclear. Therefore, the present study chose structurally different polyphenols to compare their effects on the membrane morphology and fluidity of 3T3-L1 preadipocytes, and then the reasons behind the changes of membrane fluidity induced by galloylated polyphenols were explored from structural and molecular insights using liposome model and molecular dynamic simulation technology. Our results indicated that galloylated polyphenols could significantly change 3T3-L1 cell membrane morphology and decrease membrane fluidity, while non-galloylated ones could not. The membrane interference effect of polyphenols was enhanced as the number of galloyl groups increased. Morever, the decrease in membrane fluidity induced by galloylated polyphenols was due to the disturbance of polyphenols on lipid alkyl chains in the cell membrane. Galloylated polyphenols could not only locate in the polar head, but also insert into hydrophobic center of lipid bilayer to interfere with the lipid alkyl chains arrangement, thus decreasing the membrane fluidity and showing strong affinity for the membrane. In addition, differences in position of galloyl groups in polyphenols induced distinct effect on cell membranes interactions, thus affecting the binding manner and bioactivity. The results expanded the understanding on the strong antiadipogenic activity of galloylated polyphenols through the aspect of their effects on cell membrane by both experimental and theoretically simulated ways.     

Evidence for a relationship between protein glycation and red blood cell membrane fluidity

This study examines the relationship between protein glycation and membrane fluidity in RBC membranes. Incubation of RBC membranes of healthy subjects with 25mM glucose or galactose at 37 degrees C induced a 38% (p less than 0.02) increase in protein glycation (using furosine determination by HPLC) and higher fluidity (p less than 0.05) in DPH polarization ratio). However, incubation of RBC membranes from diabetic subjects under the same conditions did not modify either membrane fluidity or protein glycation; protein glycation was above normal before incubation because of the high diabetic plasma glucose. There was no difference in the membrane fluidities of 21 healthy subjects and 32 diabetic subjects, despite a significantly elevated protein glycation in diabetics. Furthermore, there was no change with respect to age in either population. We conclude that other in vivo factors, such as membrane lipid changes (increase in CL/PL ratio) or formation of advanced Maillard products and peroxidation in the diabetic subjects, could be responsible for the difference between these in vitro results and the in vivo situation.     

Membrane embedded location of Na+ or H+ binding sites on the rotor ring of F1F0 ATP synthases.

Recent crosslinking studies indicated the localization of the coupling ion binding site in the Na+-translocating F1F0 ATP synthase of Ilyobacter tartaricus within the hydrophobic part of the bilayer. Similarly, a membrane embedded H+-binding site is accepted for the H+-translocating F1F0 ATP synthase of Escherichia coli. For a more definite analysis, we performed parallax analysis of fluorescence quenching with ATP synthases from both I. tartaricus and E. coli. Both ATP synthases were specifically labelled at their c subunit sites with N-cyclohexyl-N'-(1-pyrenyl)carbodiimide, a fluorescent analogue of dicyclohexylcarbodiimide and the enzymes were reconstituted into proteoliposomes. Using either soluble quenchers or spinlabelled phospholipids, we observed a deeply membrane embedded binding site, which was quantitatively determined for I. tartaricus and E. coli to be 1.3 +/- 2.4 A and 1.8 +/- 2.8 A from the bilayer center apart, respectively. These data show a conserved topology among enzymes of different species. We further demonstrated the direct accessibility for Na+ ions to the binding sites in the reconstituted I. tartaricus c11 oligomer in the absence of any other subunits, pointing to intrinsic rotor channels. The common membrane embedded location of the binding site of ATP synthases suggest a common mechanism for ion transfer across the membrane.