Lipid modifications of proteins – slipping in and out of membranes

Protein lipid modification, once thought to act as a stable membrane anchor for soluble proteins, is now attracting more widespread attention for its emerging role in diverse signaling pathways and regulatory mechanisms. Most multicellular organisms have recruited specific types of lipids and a suite of unique enzymes to catalyze the modification of a select number of proteins, many of which are evolutionarily conserved in plants, animals and fungi. Each of the three known types of lipid modification – palmitoylation, myristylation and prenylation – allows cells to target proteins to the plasma membrane, as well as to other subcellular compartments. Among the lipid modifications, protein prenylation might also function as a relay between cytoplasmic isoprene biosynthesis and regulatory pathways that control cell cycle and growth. Molecular and genetic studies of an Arabidopsis mutant that lacks farnesyl transferase suggest that the enzyme has a role in abscisic acid signaling during seed germination and in the stomata. It is becoming clear that lipid modifications are not just fat for the protein, but part of a highly conserved intricate network that plays a role in coordinating complex cellular functions.     

α-Synuclein interacts differently with membranes mimicking the inner and outer leaflets of neuronal membranes

The toxicity of α-synuclein (α-syn), the amyloidogenic protein responsible for Parkinson's disease, is likely related to its interaction with the asymmetric neuronal membrane. α-Syn exists as cytoplasmatic and as extracellular protein as well. To shed light on the different interactions occurring at the different α-syn localizations, we have here modelled the external and internal membrane leaflets of the neuronal membrane with two complex lipid mixtures, characterized by phase coexistence and with negative charge confined to either the ordered or the disordered phase, respectively. To this purpose, we selected a five-component (DOPC/SM/DOPE/DOPS/chol) and a four-component (DOPC/SM/GM1/chol) lipid mixtures, which contained the main membrane lipid constituents and exhibited a phase separation with formation of ordered domains. We have compared the action of α-syn in monomeric form and at different concentrations (1 nM, 40 nM, and 200 nM) with respect to lipid systems with different composition and shape by AFM, QCM-D, and vesicle leakage experiments. The experiments coherently showed a higher stability of the membranes composed by the internal leaflet mixture to the interaction with α-syn. Damage to membranes made of the external leaflet mixture was detected in a concentration-dependent manner. Interestingly, the membrane damage was related to the fluidity of the lipid domains and not to the presence of negatively charged lipids.     

Bioactivity and viscoelastic characterization of chitosan/bioglass® composite membranes

Membranes of chitosan (CTS) and composite membranes of CTS with bioglass are prepared by solvent casting. The composite membranes are shown to induce the precipitation of apatite upon immersion in SBF. The biomineralization process is followed by measuring the variation of the viscoelastic properties of the membranes immersed in SBF, both online and offline. Non-conventional DMA is used to measure the change in the storage modulus, E', and the loss factor, tan δ, as a function of the immersion in SBF. A simple model is used to estimate the E' of the apatite layer formed in vitro that is about 130?MPa. This work shows that innovate mechanical tests can be useful to characterize the mechanical performance of composites under physiological conditions.     

Polypeptide profiles of chlorophyll · protein complexes and thylakoid membranes of spinach chloroplasts

In addition to the major chlorophyll · protein complexes I and II, two minor chlorophyll proteins have been observed in sodium dodecyl sulfate (SDS)-polyacrylamide gels of spinach chloroplast membranes. These minor pigmented zones appeared to be derived from the light-harvesting chlorophyll $\text{a}\text{b}$ · protein and from the reaction centre complex of Photosystem II.Data are presented on the polypeptide profiles of purified digitonin-subchloroplast particles, with special regard to the effect of solubilization temperature and extraction of lipids. The results are compared with the SDS-polypeptide pattern of spinach thylakoids obtained under exactly the same conditions with respect to electrophoresis technique, solubilization method and presence of lipid. In addition, the effects of temperature and lipid extraction on the distinct chlorophyll · protein complexes appearing in SDS gel electrophoretograms of chloroplast membranes were studied by slicing the chlorophyll-containing regions and subjecting them to a second run with or without heating or extraction with acetone. By supplementing these data with an examination of the polypeptide composition of cytochrome f and coupling factor, it has been possible to identify most of the major chloroplast membrane polypeptides.     

Qualitative difference between “bulb” membranes and other vacuolar membranes

“Bulb” is a mobile and complex structure appearing in vacuolar membrane of plant cell. We recently reported new fluorescent marker lines for bulbs and bulb-less mutants. We tried multicolor visualization of vacuolar membrane to show distinct segregation of bulb-positive protein (γTIP or AtVAM3) and bulb-negative protein (AtRab75). Unexpectedly, GFP-AtRab75 resulted to localize in bulb under the condition of co-expression with TagRFP-AtVAM3. The signal intensities of GFP-AtRab75 and TagRFP-AtVAM3 were quantified and compared. The result indicates that TagRFP-AtVAM3 is concentrated in bulb than GFP-AtRab75.     

The isolation and characterisation of gas-cylinder membranes and α-granules fromAnabaena flos-aquae D 124

Summary Gas-cylinder membranes and -granules were isolated from cells of the blue-green alga,Anabaena flos-aquae D 124. Gas-cylinder membranes, which are 1,100 Å wide after isolation, show striations having a periodicity of 50 Å. The membranes appear globular in section with a spacing of about 40 Å between globules. There are strong indications that the globules are proteinaceous with molecular weights of 22,000±2,000. Possible homologies of these membranes with viral coat protein are discussed. -granules were shown by a variety of techniques to be polysaccharide.     

Structure of pulmonary surfactant membranes and films: The role of proteins and lipid–protein interactions

The pulmonary surfactant system constitutes an excellent example of how dynamic membrane polymorphism governs some biological functions through specific lipid–lipid, lipid–protein and protein–protein interactions assembled in highly differentiated cells. Lipid–protein surfactant complexes are assembled in alveolar pneumocytes in the form of tightly packed membranes, which are stored in specialized organelles called lamellar bodies (LB). Upon secretion of LBs, surfactant develops a membrane-based network that covers rapidly and efficiently the whole respiratory surface. This membrane-based surface layer is organized in a way that permits efficient gas exchange while optimizing the encounter of many different molecules and cells at the epithelial surface, in a cross-talk essential to keep the whole organism safe from potential pathogenic invaders.The present review summarizes what is known about the structure of the different forms of surfactant, with special emphasis on current models of the molecular organization of surfactant membrane components. The architecture and the behaviour shown by surfactant structures in vivo are interpreted, to some extent, from the interactions and the properties exhibited by different surfactant models as they have been studied in vitro, particularly addressing the possible role played by surfactant proteins. However, the limitations in structural complexity and biophysical performance of surfactant preparations reconstituted in vitro will be highlighted in particular, to allow for a proper evaluation of the significance of the experimental model systems used so far to study structure–function relationships in surfactant, and to define future challenges in the design and production of more efficient clinical surfactants.     

Binding and release kinetics of inhibitors of Q−A oxidation in thylakoid membranes

Oxygen flash yield patterns of dark adapted thylakoid membranes as measured with a Joliot-type O₂-electrode indicate that inhibitors that block the oxidation of the reduced primary quinone Q^?_A of Photosystem II vary greatly in the rate of binding to and release from the inhibitor / Q_B binding environment. The ‘classical’ Photosystem-II herbicides like diuron and atrazine exhibit slow binding and release kinetics, whereas, for example, phenolic inhibitors, o-phenanthroline and synthetic quinones are exchanging quite rapidly with Q_B (about once per second or faster at inhibitor concentrations causing about 50% inhibition of O₂ evolution). No general relationship between the efficiency of the inhibitor and the exchange rate is observed; it depends mainly on the type of inhibitor. Based on the classical Kok model, equations are derived in order to calculate oxygen yields evolved by thylakoids in single-turnover flashes as a function of the rate constants of inhibitor binding to and release from the inhibitor / Q_B binding environment in the presence of an oxidized or semireduced Q_A · Q_B or Q_A · inhibitor complex. Fitting of theoretical and experimental values yields that o-phenanthroline binds much faster to an oxidized than to a semireduced Q_A · Q_B complex. This fits very well with the hypothesis that the Q^?_B affinity to the site is much higher than that of Q_B. In the case of i-dinoseb, however, inhibitor / quinone exchange seems to occur mainly in the semiquinone state. Possibilities to explain this result are discussed.     

Is a fluid-mosaic model of biological membranes fully relevant? Studies on lipid organization in model and biological membranes

The basic concept of the fluid-mosaic model of Singer and Nicolson, an essential point of which is that the membrane proteins are floating in a sea of excess lipid molecules organized in the lipid bilayer, may be misleading in understanding the movement of membrane components in biological membranes that show distinct domain structure. It seems that the lipid bilayer is an active factor in forming the membrane structure, and the lipid composition is responsible for the presence of domains in the membrane. The main role in the process of domain formation is played by cholesterol and sphingolipids. The results presented here show that in a binary mixture of cholesterol and unsaturated phospholipids, cholesterol is segregated out from the bulk unsaturated liquid-crystalline phase. This forms cholesterol-enriched domains or clustered cholesterol domains due to the lateral nonconformability between the rigid planar ring structure of cholesterol and the rigid bend of the unsaturated alkyl chain at double bond position. These cholesterol-enriched domains may be stabilized by the presence of saturated alkyl chains of sphingomyelin or glycosphingolipids, and also by specific proteins which selectively locate in these domains and stabilize them as a result of protein-protein interaction. Such lipid domains are called "rafts" and have been shown to be responsible both for signal transduction to and from the cell and for protein sorting. We also looked at whether polar carotenoids, compounds showing some similarities to cholesterol and affecting membrane properties in a similar way, would also promote domain formation and locate preferentially in one of the lipid phases. Our preliminary data show that in the presence of cholesterol, lutein (a polar carotenoid) may segregate out from saturated lipid regions (liquid-ordered phase) and accumulate in the regions rich in unsaturated phospholipids forming carotenoid-rich domains there. Conventional and pulse EPR (electron paramagnetic resonance) spin labeling techniques were employed to assess the molecular organization and dynamics of the raft-constituent molecules and of the raft itself in the membrane.     

Interactions between canthaxanthin and lipid membranes — possible mechanisms of canthaxanthin toxicity

Canthaxanthin (β, β-carotene 4, 4′ dione) is used widely as a drug or as a food and cosmetic colorant, but it may have some undesirable effects on human health, mainly caused by the formation of crystals in the macula lutea membranes of the retina. This condition is called canthaxanthin retinopathy. It has been shown that this type of dysfunction of the eye is strongly connected with damage to the blood vessels around the place of crystal deposition. This paper is a review of the experimental data supporting the hypothesis that the interactions of canthaxanthin with the lipid membranes and the aggregation of this pigment may be the factors enhancing canthaxanthin toxicity towards the macula vascular system. All the results of the experiments that have been done on model systems such as monolayers of pure canthaxanthin and mixtures of canthaxanthin and lipids, oriented bilayers or liposomes indicate a very strong effect of canthaxanthin on the physical properties of lipid membranes, which may explain its toxic action, which leads to the further development of canthaxanthin retinopathy.     

Modes of Cl− transport across the mucosal and serosal membranes of urodele intestinal cells

Summary The characteristics of Cl^– movement across luminal and basolateral membranes ofAmphiuma intestinal absorptive cells were studied using Cl^–-sensitive microelectrodes and tracer³⁶Cl techniques. Intracellular Cl^– activity (a _Cl ⁱ ) was unchanged when serosal Cl^– was replaced; when luminal Cl^– was replaced cell Cl^– was rapidly lost. Accordingly, the steady statea _Cl ⁱ could be varied by changing the luminal [Cl]. As luminal [Cl] was raised from 1 to 86mM,a _Cl ⁱ rose in a linear manner, the mucosal membrane hyperpolarized, and the transepithelial voltage became serosa negative. In contrast, the rate of Cl^– transport from the cell into the serosal medium, measured as the SITS-inhibitable portion of the Cl^– absorptive flux, attained a maximum whena _Cl ⁱ reached an apparent value of 17mm, indicating the presence of a saturable, serosal transport step. The stilbeneinsensitive absorptive flux was linear with luminal [Cl], suggestive of a paracellular route of movement. Intracellulara _Cl was near electrochemical equilibrium at all but the lowest values of luminal [Cl] after interference produced by other anions was taken into account.a _Cl ⁱ was unaffected by Na replacement, removal of medium K, or elevation of medium HCO ₃ ^– . Mucosae labeled with³⁶Cl lost isotope into both luminal and serosal media at the same rate and from compartments of equal capacity. Lowering luminal [Cl] or addition of theophylline enhanced luminal Cl^– efflux. It is concluded that a conductive Cl leak pathway is present in the luminal membrane. Serosal transfer is by a saturable, stilbene-inhibitable pathway. Luminal Cl^– entry appears to be passive, but an electrogenic uptake cannot be discounted.     

High-resolution proton and carbon-13 NMR of membranes: why sonicate?

We have obtained high-field (11.7-T) proton and carbon-13 Fourier transform (FT) nuclear magnetic resonance (NMR) spectra of egg lecithin and egg lecithin-cholesterol (1:1) multibilayers, using "magic-angle" sample spinning (MASS) techniques, and sonicated egg lecithin and egg lecithin-cholesterol (1:1) vesicles, using conventional FT NMR methods. Resolution of the proton and carbon-13 MASS NMR spectra of the pure egg lecithin samples is essentially identical with that of sonicated samples, but spectra of the unsonicated lipid, using MASS, can be obtained very much faster than with the more dilute, sonicated systems. With the 1:1 lecithin-cholesterol systems, proton MASS NMR spectra are virtually identical with conventional FT spectra of sonicated samples, while with 13C NMR, we demonstrate that most 13C nuclei in the cholesterol moiety can be monitored, even though these same nuclei are essentially invisible, i.e., are severely broadened, in the corresponding sonicated systems. In addition, 13C MASS NMR, spectra can again be recorded much faster than with sonicated samples, due to concentration effects. Taken together, these results strongly suggest there will seldom be need in the future to resort to ultrasonic disruption of lipid bilayer membranes in order to obtain high-resolution proton or carbon-13 NMR spectra.     

Effects of α-tocopherol analogs on lysosome membranes and fatty acid monolayers

The surface pressures of α-tocopherol analogs, fatty acids, and their mixtures were measured in their spread monolayers at an air—water interface. The surface pressure—area isotherms for the mixed monolayers of α-tocopherol and either stearic acid, oleic acid or linoleic acid deviated positively from those calculated on the basis of the additivity rule, and the magnitude depended on the length of the phytyl side chain in α-tocopherol and on the degree of unsaturation of the fatty acid chains. Lysosome membranes of mouse liver were stabilized by addition of α-tocopherol. A decrease in the length of the phytyl side chain in α-tocopherol reduced its ability to stabilize lysosome membranes. A good correlation was obtained between the extent of stabilizing activity of α-tocopherol analogs on lysosome membranes and the degree of positive deviation of the surface pressure for their mixtures with fatty acids.     

Effect of Ser-129 phosphorylation on interaction of α-synuclein with synaptic and cellular membranes

In the healthy brain, less than 5% of α-synuclein (α-syn) is phosphorylated at serine 129 (Ser(P)-129). However, within Parkinson disease (PD) Lewy bodies, 89% of α-syn is Ser(P)-129. The effects of Ser(P)-129 modification on α-syn distribution and solubility are poorly understood. As α-syn normally exists in both membrane-bound and cytosolic compartments, we examined the binding and dissociation of Ser(P)-129 α-syn and analyzed the effects of manipulating Ser(P)-129 levels on α-syn membrane interactions using synaptosomal membranes and neural precursor cells from α-syn-deficient mice or transgenic mice expressing human α-syn. We first evaluated the recovery of the Ser(P)-129 epitope following either α-syn membrane binding or dissociation. We demonstrate a rapid turnover of Ser(P)-129 during both binding to and dissociation from synaptic membranes. Although the membrane binding of WT α-syn was insensitive to modulation of Ser(P)-129 levels by multiple strategies (the use of phosphomimic S129D and nonphosphorylated S129A α-syn mutants; by enzymatic dephosphorylation of Ser(P)-129 or proteasome inhibitor-induced elevation in Ser(P)-129; or by inhibition or stable overexpression of PLK2), PD mutant Ser(P)-129 α-syn showed a preferential membrane association compared with WT Ser(P)-129 α-syn. Collectively, these data suggest that phosphorylation at Ser-129 is dynamic and that the subcellular distribution of α-syn bearing PD-linked mutations, A30P or A53T, is influenced by the phosphorylation state of Ser-129.     

Affinity of different α1-agonists and antagonists for the α1-adrenoceptors of rabbit and rat liver membranes

In membranes prepared from rabbit liver, competition with [³H] prazosin by different α₁-agonists and antagonists revealed different affinities in comparison to the results obtained on rat liver membranes, and showed a good correlation with the affinity of the same compounds for the cloned α_1c-adrenoceptor subtype. The potencies observed on rat liver membranes were well correlated with the affinity observed for the cloned α_1b-adrenoceptors. These results confirm that rabbit and rat liver membranes preparations can be utilized to evaluate the affinity of compounds for these α₁-adrenergic subtypes.     

Direct insertion and fluorescence studies of rhodamine-labeled β-adrenergic receptors in cell membranes

Summary Previous studies utilizing the fluorescence of propanolol as a probe for the beta-adrenergic receptor showed that this receptor is motionally constrained. To further study the betaadrenergic receptorin situ we have reinserted rhodamine-labeled beta-receptors into cell membranes. This report presents documentation of their insertion and physiologic viability. Beta-receptors were purified by affinity chromatography (10,000-fold), then fluorescently labeled with tetramethyl rhodamine isothiocyanate, repurified (55,000-fold) and incubated with rat pancreatic islet cells. The binding of³H-dihydroalprenolol by these cells was increased from aB _max of 168±2 to 309±20 fmol/mg protein with no change inK _d . Various treatments which remove peripheral membrane proteins, e.g. NaOH, lithium diiodosalicylate, and trypsinization, did not alter binding by the cells with inserted receptors indicating that the receptors inserted into cell membranes. In islet cells treated with Koshland's reagent I, beta-adrenergic binding was completely abolished, but following incubation with isolated beta-receptors, the cells bound beta-adrenergic radioligand with aB _max of 100 fmol/mg protein, indicating functionality on the part of the inserted receptors. Furthermore, insertion of isolated receptors into frog erythrocytes resulted in increased production of cAMP in response to added isoproterenol. In pancreatic islet cells, incubation with labeled receptors caused the fluorescence to shift in wavelength with increased intensity indicating a shift from an aqueous to a lipid environment, probably into the membrane. Using fluorescence (P), it was found that the inserted receptors became motionally constrained to aP of 0.38 (limitingP _o=0.42) during the first 15 min, remaining so for at least 2 hr. Colchicine (5 g/ml) caused a decrease inP to 0.18 indicating release of constraint. Isoproterenol (10^–5M) caused a rapid decrease toP=0.15. This effect was blocked by propranolol. Propranolol itself (10^–5M) had no effect. These results indicate that the labeled receptors rapidly insert into cell membranes and also support the view that agonist activation of the receptor causes an increase in receptor mobility, presumably due to release of constraint from cytoskeleton elements.     

Chymotrypsinogen · inositol phosphatide complexes and the transport of digestive enzyme across membranes

Chymotrypsinogen A was almost quantitatively extracted from aqueous solution in the presence of inositol phosphatides at relatively low concentrations of both ligands. Calcium ion facilitated the interaction at concentrations of 10^?4–10^?5 M. A water-insoluble chymotrypsinogen · Ca²⁺ · inositol phosphatide complex was formed with an apparent stochiometry of 3 mol phospholipid : 3 mol Ca²⁺ : 1 mol protein. Small changes in the structure of the protein prevented complex formation; in particular, the almost identical α-chymotrypsin, did not form complexes under the conditions studied. On the other hand, an homologous, but structurally substantially different, secretory protein, trypsinogen, did form complexes. Water-insoluble complexes were not formed with albumin, carbonic anhydrase or lactic dehydrogenase under the same circumstances. Neither phosphatidylethanolamine nor phosphatidylcholine formed complexes with chymotrypsinogen. Phosphatidylserine formed complexes, but was less effective than inositol phosphatides. Complex formation and stability was dependent upon “critical” concentrations of both Ca²⁺ and H⁺. Extraction of the protein from solution increased from neglible to complete when the calcium concentration of the medium was raised slightly from 1.0 · 10^?4 M to 1.5·10^?4 M. Conversely, dissociation was complete when H⁺ concentration was decreased slightly from pH 6.5 to 7.0. The complex is apparently formed as the result of specific electrostatic interactions between the polar head group of the inositol phosphatide and the protein, with the nonpolar alipathic fatty acid chains of the phospholipid providing a hydrophobic microenvironment for the protein. It is proposed that such complexes could account for the movement of digestive enzyme through membranes.     

Fusion of vacuoles--where are the membranes, and where are the holes?

In the February 8th issue of Cell, Wang et al. report the surprising finding that vacuolar fusion occurs at the periphery of the contact area of the vacuoles and not by the expansion of a central fusion pore. During fusion, a disk of boundary membrane is excised and left behind within the fused vacuoles.     

Insulin-dependent release of 5′-nucleotidase and alkaline phosphatase from liver plasma membranes

Insulin treatment of isolated liver plasma membranes induced the release of 5′-nucleotidase and alkaline phosphatase. This effect was maximal at physiological hormone concentrations, being 36% and 17% for 5′-nucleotidase and alkaline phosphatase respectively, and was fully mimicked by the phosphatidylinositol specific phospholipase C (PI-PLC), thus confirming the presence of a glycosyl-phosphatidylinositol anchoring-system for these exofacial enzymatic proteins. The complete inhibition of insulin dependent enzyme release by neomycin is strongly supportive of an involvement of membrane-located PI-PLC activity. In addition, the insulin-like effect on enzyme release induced by the GTP non-hydrolysable analog, GTP-γ-S, and its sensitivity to the pertussis toxin are in favour of a mediatory role exerted by the G proteins system, in the transduction of some actions of insulin.