Enantiodiscrimination of bilirubin-IXalpha enantiomers in biomembrane models: has chirality a role in bilirubin toxicity?

Simple biomembrane models, namely micellar aggregates formed by enantiopure sodium N-acylprolinates, are able to convert the racemic mixture of bilirubin-IXα into an enantiomerically enriched mixture, thus suggesting a possible role of chirality in bilirubin toxicity due to the perturbation of neuron membrane dynamics. The length of alkyl chain does not influence the extent of equilibrium displacement, however, it affects the conformation of bilirubin, thus confirming the role of lipid structure in the membrane/bilirubin interaction, and suggesting a non-superficial main site of association.     

Effect of acidosis on bilirubin-induced toxicity to human erythrocytes

Unconjugated bilirubin binds to erythrocytes, eliciting crenation, lipid elution and hemolysis. The present work attempts to establish the role of acidosis on bilirubin-induced toxicity to human erythrocytes. To this end, pH values ranging from 7.0–8.0 were used to induce a different representation of acid and anionic bilirubin species, respectively. Erythrocytes from healthy donors were incubated with bilirubin and albumin (3:1, molar ratio), during 4 h. Erythrocyte-bound bilirubin was evaluated by albumin or chloroform extraction in an attempt to assess either mono- and dianion bilirubin adsorbed on the cell surface or colloidal aggregates, respectively. Cytotoxicity indicators, such as the morphological index, and the extent of phospholipids and hemoglobin release were also determined. The results showed that as pH drops from 8.0–7.0, less bilirubin is removed by albumin and more become recovered by chloroform. The data corroborate the predominance of anionic and non-aggregated bilirubin species at pH 8.0 with dimers and precipitates occurring at 7.0. In accordance, crenation and cell lysis were four times increased at acidic pH. In contrast, elution of phospholipids was 1.5 times less evident at the same pH, thus suggesting that formation of bilirubin complexes with membrane phospholipids may have contributed to prevent their release. In conclusion, both anionic and acid bilirubin species interact with human erythrocytes leading to cytotoxic alterations that may determine definitive lesions. Nevertheless, increased vulnerability to crenation and hemolysis are more likely to occur in acidic conditions pointing to the bilirubin precipitates as the main candidates of bilirubin-induced toxicity to erythrocytes.     

Effects of bilirubin molecular species on membrane dynamic properties of human erythrocyte membranes: a spin label electron paramagnetic resonance spectroscopy study

Unconjugated bilirubin is a neurotoxic pigment that interacts with membrane lipids. In this study we used electron paramagnetic resonance and the spin labels 5-, 7-, 12-, and 16-doxyl-stearic acid (DSA) to evaluate the depth of the hydrocarbon chain at which interaction of bilirubin preferentially occurs. In addition, we used different pH values to determine the molecular species involved. Resealed right-side-out ghosts were incubated (1-60 min) with bilirubin (3.4-42.8 microM) at pH 7.0, 7.4, and 8.0. Alterations of membrane dynamic properties were maximum after 15 min of incubation with 8.6 microM bilirubin at pH 7.4 and were accompanied by a significant release of phospholipids. Interestingly, concentrations of bilirubin up to 42.8 microM and longer incubations resulted in the elution of cholesterol and further increased that of phospholipids while inducing less structural alterations. Variation of the pH values from 8.0 to 7.4 and 7.0, under conditions of maximum perturbation, led to a change from an increased to a diminished polarity sensed by 5-DSA. Conversely, a progressive enhancement in fluidity was reported by 7-DSA, followed by 12- and 16-DSA. These results indicate that bilirubin while enhancing membrane lipid order at C-5 simultaneously has disordering effects at C-7. Furthermore, recovery of membrane dynamics after 15 min of bilirubin exposure along with the release of lipids is compatible with a membrane adaptive response to the insult. In addition, our data provide evidence that uncharged diacid is the species primarily interacting with the membrane as perturbation is favored by acidosis, a condition frequently associated with hyperbilirubinemia in premature and severely ill infants.     

Effect of phospholipase C, trypsin and neuraminidase on binding of bilirubin to mammalian erythrocyte membranes.

Binding of bilirubin to erythrocyte membranes of human, buffalo, sheep and goat was studied after phospholipase C, trypsin and neuraminidase treatment. Phospholipase C and trypsin treatment of membranes greatly enhanced the bilirubin binding in all mammalian species, whereas, neuraminidase treatment resulted into a small increase in the membrane-bound bilirubin. Human erythrocyte membranes bound the highest amount of bilirubin, whereas buffalo, sheep and goat erythrocyte membranes showed different mode of bilirubin binding. The order of bilirubin binding to unmodified as well as neuraminidase-treated erythrocyte membranes was: human>sheep>buffalo>goat; the order was: human>buffalo>sheep>goat; in phospholipase C- and trypsin-treated erythrocyte membranes. These binding results indicate that membrane phospholipids are directly involved in the interaction of bilirubin with the membranes as the differences observed in the membrane-bound bilirubin among mammalian species were directly correlated with the sum of choline phospholipids, especially phosphatidylcholine and sphingomyelin content of the erythrocyte membranes. The negatively charged phosphate moiety of phospholipids of the membranes appears to inhibit a large amount of bilirubin binding to the membrane as its removal by phospholipase C greatly enhanced the binding. Furthermore, membrane proteins and carbohydrate also seem to play a significant regulatory function on the binding as their degradation and/or removal in the form of glycopeptides by trypsin expose a large number of bilirubin binding sites.     

Structural and functional features of membranes with different cholesterol content

The paper deals with the present-day ideas of the structure and functions of membranes with different cholesterol content and relative sterols. The data on the molecular bases of lipids and sterols interaction in model systems, monolayers and liposomes, are obtained using 1H-, 13C-, 31P-NMR, EPR-investigations, methods of differential scanning calorimetry and X-ray diffraction. The methods for obtaining biomembranes with the different content of cholesterol and its effect on the membrane structure and functions are discussed. Reasons are analyzed of principal differences in behaviour of biomembranes with different content of cholesterol and respective model systems. The nature of cholesterol binding with phospholipids, proteins and its asymmetric distribution in biomembranes is considered. The cholesterol effect on the erythrocyte membrane charge density and possible changes in structural and functional properties of the membranes are demonstrated through the author's own experimental data. It is concluded that the cholesterol effect on structure and functions of the membranes is determined to a considerable extent by their phospholipid composition, localization and phase behaviour of phospholipids and sometimes depends on the membrane charge density.     

Mn~(2+)和Cu~(2+)与脂质体和脂酶体相互作用的ESR研究

用ESR实验研究了Mn~(2 )、Cu~(2 )与DOPC,DPPC,SPL,DOPA,DPPA脂质体及其与H~ -ATP酶复合体重组的脂酶体的相互作用.通过Mn~(2 )—ESR谱线强度以及Cu~(2 )—ESR谱g因子的测量得出,磷脂分子头部不同的化学组成及其脂酰链的不同状态决定了Mn~(2 )、Cu~(2 )与膜脂结合的强弱程度,通过脂质体和脂酶体中自旋标记物5NS—ESR谱的测量进一步得出Mn~(2 )的结合增大了膜脂排列的序参数,而酶复合体的嵌入都导致与膜脂结合的Mn~(2 )比例减小.因而,当Mn~(2 )与脂酶体相互作用时,膜脂的排列最终达到一个平衡状态.在中性磷脂脂酶体的膜与Mn~(2 )之间,这种相互作用不明显.     

Activation of membrane cholesterol by displacement from phospholipids

We tested the hypothesis that certain membrane-intercalating agents increase the chemical activity of cholesterol by displacing it from its low activity association with phospholipids. Octanol, 1,2-dioctanoyl-sn-glycerol (a diglyceride), and N-hexanoyl-D-erythrosphingosine (a ceramide) were shown to increase both the rate of transfer and the extent of equilibrium partition of human red blood cell cholesterol to methyl-beta-cyclodextrin. These agents also promoted the interaction of the sterol with two cholesterol-specific probes, cholesterol oxidase and saponin. Expanding the pool of bilayer phospholipids with lysophosphatides countered these effects. The three intercalators also protected the red cells against lysis by cholesterol depletion as if substituting for the extracted sterol. As is the case for excess plasma membrane cholesterol, treating human fibroblasts with octanol, diglyceride, or ceramide stimulated the rapid inactivation of their hydroxymethylglutaryl-CoA reductase, presumably through an increase in the pool of endoplasmic reticulum cholesterol. These data supported the stated hypothesis and point to competition between cholesterol and endogenous and exogenous intercalators for association with membrane phospholipids. We also describe simple screens using red cells in a microtiter well format to identify intercalating agents that increase or decrease the activity of membrane cholesterol.     

Bilirubin induces loss of membrane lipids and exposure of phosphatidylserine in human erythrocytes

Unconjugated bilirubin increasingly binds to erythrocytes as the bilirubin-to-albumin molar ratio exceeds unity, leading to toxic manifestations that can culminate in cell lysis. Our previous studies showed that bilirubin induces the release of lipids from erythrocyte membranes. In the present work, those studies were extended in order to characterize the alterations of membrane lipid composition and evaluate whether bilirubin leads to a loss of phospholipid asymmetry. To this end, human erythrocytes were incubated with several bilirubin-to-albumin molar ratios (0.5 to 5), and cholesterol as well as the total and the individual classes of phospholipids were determined. To detect erythrocytes with phosphatidylserine at the outer surface, the number of annexin V-positive cells was determined following incubation with bilirubin, fixing its molar ratio to albumin at 3. The results demonstrate profound changes in erythrocyte membrane composition, including modified cholesterol and phospholipid content. The release of membrane cholesterol, as well as of total and individual classes of phospholipids at molar ratios ≥1, indicates that damage of erythrocytes may occur in severely ill jaundiced neonates. The loss of the inner-located phospholipids, phosphatidylethanolamine and phosphatidylserine, points to a redistribution of phospholipids in the membrane bilayer. This was confirmed by the exposure of phosphatidylserine at the outer cell surface. In conclusion, this study demonstrates that bilirubin induces loss of membrane lipids and externalization of phosphatidylserine in human erythrocytes. These features may facilitate hemolysis and erythrophagocytosis, thus contributing to enhanced bilirubin production and anemia during severe neonatal hyperbilirubinemia. This revised version was published online in July 2006 with corrections to the Cover Date.     

Interactions of amphotericin B derivative of low toxicity with biological membrane components--the Langmuir monolayer approach

Amphotericin B (AmB)--a polyene macrolide antibiotic--exhibits strong antifungal activity, however, is known to be very toxic to mammalian cells. In order to decrease AmB toxicity, a number of its derivatives have been synthesized. Basing on in vitro and in vivo research, it was evidenced that one of AmB derivatives, namely N-methyl-N-D-fructopyranosylamphotericin B methyl ester (in short MF-AME) retained most of the antifungal activity of the parent antibiotic, however, exhibited dramatically lower animal toxicity. Therefore, MF-AME seems to be a very promising modification product of AmB. However, further development of this derivative as potential new antifungal drug requires the elucidation of its molecular mechanism of reduced toxicity, which was the aim of the present investigations. Our studies were based on examining the binding energies by determining the strength of interaction between MF-AME and membrane sterols (ergosterol-fungi sterol, and cholesterol-mammalian sterol) and DPPC (model membrane phospholipid) using the Langmuir monolayer technique, which serves as a model of cellular membrane. Our results revealed that at low concentration the affinity of MF-AME to ergosterol is considerably stronger as compared to cholesterol, which correlates with the improved selective toxicity of this drug. It is of importance that the presence of phospholipids is essential since--due to very strong interactions between MF-AME and DPPC--the antibiotic used in higher concentration is "immobilized" by DPPC molecules, which reduces the concentration of free antibiotic, thus enabling it to selectively interact with both sterols.     

Interaction of bilirubin with the synaptosomal plasma membrane

The interaction of the neurotoxic pigment bilirubin with synaptosomal plasma membrane vesicles (SPMV) isolated from rat brain was investigated. The interaction seems to involve three steps: (a) a rapid formation of an electrostatic complex between bilirubin and polar lipid head groups; (b) a slow inclusion of the pigment into the hydrophobic core of the membrane; and (c) a SPMV-induced bilirubin aggregation, observed when membrane capacity for bilirubin is exceeded. The association constant of the initial complex increased markedly when pH was lowered below 7.4, particularly in SPMV isolated from newborn rats. A preferential binding of bilirubin to pure gangliosides and sphingomyelin was observed, thus suggesting a role for these lipids as first targets of the pigment in the synaptic membrane. The inclusion of bilirubin into the membranes was gradually enhanced when decreasing the pH or the age of the rats from which SPMV were isolated. In addition, membranes from 2-day-old rats have a higher capacity for bilirubin incorporation compared to those from adult rats. Experiments with reconstituted liposomes of varying protein and cholesterol contents suggest that the effect of age may be related to changes in synaptosomal membrane fluidity during development. Our results support the hypothesis that the interaction of bilirubin with the synaptic membrane plays an important role in the molecular mechanisms of bilirubin neurotoxicity.     

Quinidine is a strong perturber of acidic phospholipid bilayer order and fluidity

The effect of an antiarrhythmic drug, quinidine, on the organization of model phospholipid membranes was studied by the spin-labeling technique. Quinidine strongly perturbs the molecular organization of lipid bilayers prepared from acidic phospholipids (phosphatidylserine, phosphatidic acid) and has only a slight effect on neutral phosphatidylcholine membranes. The interaction of the drug with acidic phospholipids manifests itself in a pronounced increase in the order parameter of the region close to the polar surface of the bilayer and in some decrease in its inner hydrocarbon core fluidity. It is suggested that the perturbation in the organization of membrane lipids may contribute to the mechanisms by which quinidine exerts its pharmacological effects.     

Possible participation of acid phospholipids in the translocation of secreted proteins through the cytoplasmic membrane of bacteria

The work presents a brief review of data on the interrelation between the biosynthesis and secretion of proteins in bacteria, and between metabolism, composition and physicochemical state of membrane lipids. Based on the analysis of these data in view of the modern ideas of the dynamic character of the membrane lipid structure, a hypothesis concerning the active participation of acid phospholipids in the translocation of protein and phospholipids through the bacterial cytoplasmic membrane is advanced. A new model of the coupled translocation of protein and phospholipids through the membrane is proposed which differs from the previous ones because it accounts not only the role of the secreted protein structure in its translocation through the membrane but assumes an active participation of membranes themselves (specifically phospholipids) in this process. The model assumes the interaction between a signal peptide of the de novo synthesized protein and acid phospholipids of membranes. Such an interaction initiates a transmembrane movement of phospholipids and a coupled translocation of phospholipids and protein, in which phospholipids and proteins secreted favor the movement of each other.     

Interactions of biocidal guanidine hydrochloride polymer analogs with model membranes: a comparative biophysical study

Four synthesized biocidal guanidine hydrochloride polymers with different alkyl chain length, including polyhexamethylene guanidine hydrochloride and its three new analogs, were used to investigate their interactions with phospholipids vesicles mimicking bacterial membrane. Characterization was conducted by using fluorescence dye leakage, isothermal titration calorimetry, and differential scanning calorimetry. The results showed that the gradually lengthened alkyl chain of the polymer increased the biocidal activity, accompanied with the increased dye leakage rate and the increased binding constant and energy change value of polymer-membrane interaction. The polymer-membrane interaction induced the change of pretransition and main phase transition (decreased temperature and increased width) of phospholipids vesicles, suggesting the conformational change in the phospholipids headgroups and disordering in the hydrophobic regions of lipid membranes. The above information revealed that the membrane disruption actions of guanidine hydrochloride polymers are the results of the polymer's strong binding to the phospholipids membrane and the subsequent perturbations of the polar headgroups and hydrophobic core region of the phospholipids membrane. The alkyl chain structure significantly affects the binding constant and energy change value of the polymer-membrane interactions and the perturbation extent of the phospholipids membrane, which lead to the different biocidal activity of the polymer analogs. This work provides important information about the membrane disruption action mechanism of biocidal guanidine hydrochloride polymers.     

Molecular determinants of phospholipid synergy in blood clotting

Many regulatory processes in biology involve reversible association of proteins with membranes. Clotting proteins bind to phosphatidylserine (PS) on cell surfaces, but a clear picture of this interaction has yet to emerge. We present a novel explanation for membrane binding by GLA domains of clotting proteins, supported by biochemical studies, solid-state NMR analyses, and molecular dynamics simulations. The model invokes a single "phospho-L-serine-specific" interaction and multiple "phosphate-specific" interactions. In the latter, the phosphates in phospholipids interact with tightly bound Ca(2+) in GLA domains. We show that phospholipids with any headgroup other than choline strongly synergize with PS to enhance factor X activation. We propose that phosphatidylcholine and sphingomyelin (the major external phospholipids of healthy cells) are anticoagulant primarily because their bulky choline headgroups sterically hinder access to their phosphates. Following cell damage or activation, exposed PS and phosphatidylethanolamine collaborate to bind GLA domains by providing phospho-L-serine-specific and phosphate-specific interactions, respectively.     

Molecular modeling and simulation of Mycobacterium tuberculosis cell wall permeability

The low permeability of the mycobacterial cell wall is thought to contribute to the intrinsic drug resistance of mycobacteria. In this study, the permeability of the Mycobacterium tuberculosis cell wall is studied by computer simulation. Thirteen known drugs with diverse chemical structures were modeled as solutes undergoing transport across a model for the M. tuberculosis cell wall. The properties of the solute-membrane complexes were investigated by means of molecular dynamics simulation, especially the diffusion coefficients of the solute molecules inside the cell wall. The molecular shape of the solute was found to be an important factor for permeation through the M. tuberculosis cell wall. Predominant lateral diffusion within, as opposed to transverse diffusion across, the membrane/cell wall system was observed for some solutes. The extent of lateral diffusion relative to transverse diffusion of a solute within a biological cell membrane may be an important finding with respect to absorption distribution, metabolism, elimination, and toxicity properties of drug candidates. Molecular similarity measures among the solutes were computed, and the results suggest that compounds having high molecular similarity will display similar transport behavior in a common membrane/cell wall environment. In addition, the diffusion coefficients of the solute molecules across the M. tuberculosis cell wall model were compared to those across the monolayers of dipalmitoylphosphatidylethanolamine and dimyristoylphosphatidylcholine, are two common phospholipids in bacterial and animal membranes. The differences among these three groups of diffusion coefficients were observed and analyzed.     

Localization of bilirubin in phospholipid bilayers by parallax analysis of fluorescence quenching

It has been proposed that the neurotoxicity observed in severely jaundiced infants results from the binding of unconjugated bilirubin to nerve cell membranes. However, despite potentially important clinical ramifications, there remains significant controversy regarding the physical nature of bilirubin-membrane interactions. We used the technique of parallax analysis of fluorescence quenching (Chattopadhyay, A., and E. London. 1987. Biochemistry. 26: 39;-45) to measure the depth of penetration of bilirubin in model phospholipid bilayers. The localization of unconjugated bilirubin and ditaurobilirubin within small unilamellar vesicles composed of dioleoylphosphatidylcholine was determined through an analysis of the quenching of bilirubin fluorescence by spin-labeled phospholipids, and by bilirubin-mediated quenching of a series of anthroyloxy fatty acid probes at various depths within the membrane bilayer. Findings were further verified with potassium iodide as an aqueous quencher. Our results indicate that, at pH 10, unconjugated bilirubin localizes approximately 20 A from the bilayer center, in the region of the polar head groups. Further analyses suggest a modest influence of pH, membrane cholesterol content, and vesicle diameter on the bilirubin penetration depth. Taken together, these data support that, under physiologic conditions, bilirubin localizes to the polar region of phospholipid bilayers, near the membrane-water interface.     

Membrane binding of twin arginine preproteins as an early step in translocation

The twin arginine transport (Tat) system translocates folded proteins across the bacterial inner membrane. Transport substrates are recognized by means of evolutionarily well-conserved N-terminal signal peptides. The precise role of signal peptides in the actual transport process is not yet fully understood. Potentially, much insight into the molecular details of the transport process could be gained from step-by-step in vitro experiments under controlled conditions. Here, we employ purified preproteins to study their interaction with the phospholipid membrane by using surface plasmon resonance spectroscopy. It turns out that preproteins interact tightly with a model membrane consisting of only phospholipids. This interaction, which is stabilized by both electrostatic and hydrophobic contributions, appears to constitute an early step in protein translocation by the Tat system.     

Hepatic membranolytic stability alteration by metalloporphins in rats.

The mothers of experimental neonates were administered excess bilirubin for a month, and the neonates were suffering from hyperbilirubinemia. The studies were conducted on the effect of excess bilirubin and metalloporphyrins on plasma membrane and mitochondrial membrane. We have isolated, separated, and estimated phospholipids, and also assayed the activity of phospholipase A2 from whole liver and mitochondrial and microsomal fractions. Excess of bilirubin administration decreased the total phospholipid level and inhibited the phospholipase A2 activity. Cr-PP (chromium protoporphyrin) induces the phospholipase A2 activity which is inhibited by simultaneous bilirubin administration. However, Zn-PP (zinc protoporphyrin) and Mn-PP (manganese protoporphyrin) showed a reverse pattern.     

Phosphatidylethanolamine and phosphatidylglycerol are segregated into different domains in bacterial membrane. A study with pyrene-labelled phospholipids

To detect and characterize membrane domains that have been proposed to exist in bacteria, two kinds of pyrene-labelled phospholipids, 2-pyrene-decanoyl-phosphatidylethanolamine (PY-PE) and 2-pyrene-decanoyl-phosphatidylglycerol (PY-PG) were inserted into Escherichia coli or Bacillus subtilis membrane. The excimerization rate coefficient, calculated from the excimer-to-monomer ratio dependencies on the probe concentration, was two times higher for PY-PE than for PY-PG at 37 degrees C. This was ascribed to different local concentrations rather than to differences in mobility. The extent of mixing between the two fluorescent phospholipids, estimated by formation of their heteroexcimer, was found very low both in E. coli and B. subtilis, in contrast to model membranes. In addition, these two pyrene derivatives exhibited different temperature phase transitions and different detergent extractability, indicating that the surroundings of these phospholipids in bacterial membrane differ in organization and order. Inhibition of protein synthesis, leading to condensation of nucleoid and presumably to dissipation of membrane domains, indeed resulted in increased formation of heteroexcimers, broadening of phase transitions and equal detergent extractability of both probes. It is proposed that in bacterial membranes these phospholipids are segregated into distinct domains that differ in composition, proteo-lipid interaction and degree of order; the proteo-lipid domain being enriched by PE.