The interfacial lipid binding site on the potassium channel KcsA is specific for anionic phospholipids

Lipid binding to the potassium channel KcsA from Streptomyces lividans has been studied using quenching of the fluorescence of Trp residues by brominated phospholipids. It is shown that binding of phospholipids to nonannular lipid binding sites on KcsA, located one each at the four protein-protein interfaces in the tetrameric structure, is specific for anionic phospholipids, zwitterionic phosphatidylcholine being unable to bind at the sites. The binding constant for phosphatidylglycerol of 3.0 ± 0.7 mol fraction⁻¹ means that in a membrane containing ~20 mol% phosphatidylglycerol, as in the Escherichia coli inner membrane, the nonannular sites will be ~37% occupied by phosphatidylglycerol. The binding constant for phosphatidic acid is similar to that for phosphatidylglycerol but binding constants for phosphatidylserine and cardiolipin are about double those for phosphatidylglycerol. Binding to annular sites around the circumference of the KcsA tetramer are different on the extracellular and intracellular faces of the membrane. On the extracellular face of the membrane the binding constants for anionic lipids are similar to those for phosphatidylcholine, the lack of specificity being consistent with the lack of any marked clusters of charged residues on KcsA close to the membrane on the extracellular side. In contrast, binding to annular sites on the intracellular side of the membrane shows a distinct structural specificity, with binding of phosphatidic acid and phosphatidylglycerol being stronger than binding of phosphatidylcholine, whereas binding constants for phosphatidylserine and cardiolipin are similar to that for phosphatidylcholine. It is suggested that this pattern of binding follows from the pattern of charge distribution on KcsA on the intracellular side of the membrane.     

Non-covalent binding of membrane lipids to membrane proteins

Polar lipids and membrane proteins are major components of biological membranes, both cell membranes and membranes of enveloped viruses. How these two classes of membrane components interact with each other to influence the function of biological membranes is a fundamental question that has attracted intense interest since the origins of the field of membrane studies. One of the most powerful ideas that driven the field is the likelihood that lipids bind to membrane proteins at specific sites, modulating protein structure and function. However only relatively recently has high resolution structure determination of membrane proteins progressed to the point of providing atomic level structure of lipid binding sites on membrane proteins. Analysis of X-ray diffraction, electron crystallography and NMR data over 100 specific lipid binding sites on membrane proteins. These data demonstrate tight lipid binding of both phospholipids and cholesterol to membrane proteins. Membrane lipids bind to membrane proteins by their headgroups, or by their acyl chains, or binding is mediated by the entire lipid molecule. When headgroups bind, binding is stabilized by polar interactions between lipid headgroups and the protein. When acyl chains bind, van der Waals effects dominate as the acyl chains adopt conformations that complement particular sites on the rough protein surface. No generally applicable motifs for binding have yet emerged. Previously published biochemical and biophysical data link this binding with function. This Article is Part of a Special Issue Entitled: Membrane Structure and Function: Relevance in the Cell's Physiology, Pathology and Therapy.     

Interactions of anionic phospholipids and phosphatidylethanolamine with the potassium channel KcsA

Fluorescence quenching methods have been used to study interactions of anionic phospholipids with the potassium channel KcsA from Streptomyces lividans. Quenching of the Trp fluorescence of KcsA reconstituted into mixtures of dioleoylphosphatidylcholine (DOPC) and an anionic phospholipid with dibromostearoyl chains is more marked at low mole fractions of the brominated anionic phospholipid than is quenching in mixtures of dibromostearoylphosphatidylcholine and nonbrominated anionic lipid. The quenching data are consistent with two classes of binding site for lipid on KcsA, one set corresponding to annular binding sites around KcsA to which DOPC and two-chain anionic phospholipids bind with similar affinities, the other set (non-annular sites) corresponding to sites at which anionic phospholipids can bind but from which DOPC is either excluded or binds with very low affinity. The binding constant for tetraoleoylcardiolipin at the annular sites is significantly less than that for DOPC, being comparable to that for dioleoylphosphatidylethanolamine. Tetraoleoylcardiolipin binds with highest affinity to the non-annular sites, the affinity for dioleoylphosphatidylglycerol being the lowest. The affinity for dioleoylphosphatidylserine decreases at high ionic strength, suggesting that electrostatic interactions between the anionic phospholipid headgroup and positively charged residues on KcsA are important for binding at the non-annular site. The effect of ionic strength on the binding of phosphatidic acid is less marked than on phosphatidylserine. The value of the binding constant for the non-annular site depends on the extent of Trp fluorescence quenching following from binding at the non-annular site. It is suggested that the non-annular site to which binding is detected in the fluorescence quenching experiments corresponds to the binding site for phosphatidylglycerol detected at monomer-monomer interfaces in x-ray diffraction studies.     

Heterogeneity in the binding of lipid molecules to the surface of a membrane protein: hot spots for anionic lipids on the mechanosensitive channel of large conductance MscL and effects on conformation

We have introduced single Trp residues into the mechanosensitive channel of large conductance (MscL) from Mycobacterium tuberculosis and used fluorescence quenching by brominated phospholipids to detect the presence of a binding site of high affinity for anionic phospholipids. A cluster of three positively charged residues, Arg-98, Lys-99, and Lys-100, is located on the cytoplasmic side of MscL, in a position where they could interact with the headgroup of an anionic phospholipid. Single mutations of these charged residues in the Trp-containing mutant F80W results in a decreased affinity for phosphatidic acid. Single mutations of the charged residues also result in a significant shift in the fluorescence emission spectrum in dioleoylphosphatidylcholine [di(C18:1)PC] but smaller shifts in dioleoylphosphatidic acid [di(C18:1)PA], suggesting that single mutations result in a conformational change for the protein that is reversed by interaction with anionic phospholipids. This is consistent with the observation that single mutations of the charged residues do not result in a gain of function phenotype. In contrast, simultaneous mutation of all three charged residues results in a gain of function phenotype, and a shift in fluorescence emission spectrum in di(C18:1)PC not reversed in di(C18:1)PA. The gain of function mutant F80W:V21K also shows a shifted fluorescence emission spectrum in both di(C18:1)PC and di(C18:1)PA and binds di(C18:1)PC and di(C18:1)PA with equal affinity, suggesting that the conformational change caused by the V21K mutation results in a breakup of the cluster of three positive charges. Experiments with the Trp mutants L69W and Y87W allow us to measure lipid binding constants on the periplasmic and cytoplasmic sides of the membrane, respectively. On both sides of the membrane the affinity for di(C18:1)PC is equal to that for dioleoylphosphatidylethanolamine. On the periplasmic side of the membrane, there is no selectivity for anionic phospholipids. In contrast, quenching data for Y87W provides evidence for the existence of two lipid binding sites on the cytoplasmic side of the membrane close to the Trp residue at position 87, with binding to one of these sites showing a marked preference for anionic lipid over zwitterionic lipid, presumably involving the charged cluster Arg-98, Lys-99, and Lys-100.     

Lipid-protein interactions studied by introduction of a tryptophan residue: the mechanosensitive channel MscL

Trp fluorescence spectroscopy is a powerful tool to study the structures of membrane proteins and their interactions with the surrounding lipid bilayer. Many membrane proteins contain more than one Trp residue, making analysis of the fluorescence data more complex. The mechanosensitive channels MscL's of Mycobacterium tuberculosis (TbMscL) and Escherichia coli (EcMscL) contain no Trp residues. We have therefore introduced single Trp residues into the transmembrane regions of TbMscL and EcMscL to give the Trp-containing mutants F80W-TbMscL and F93W-EcMscL, respectively, which we show are highly suitable for measurements of lipid binding constants. In vivo cell viability assays in E. coli show that introduction of the Trp residues does not block function of the channels. The Trp-containing mutants have been reconstituted into lipid bilayers by mixing in cholate followed by dilution to re-form membranes. Cross-linking experiments suggest that the proteins retain their pentameric structures in phosphatidylcholines with chain lengths between C14 and C24, phosphatidylserines, and phosphatidic acid. Quenching of Trp fluorescence by brominated phospholipids suggests that the Trp residue in F80W-TbMscL is more exposed to the lipid bilayer than the Trp residue in F93W-EcMscL. Binding constants for phosphatidylcholines change with changing fatty acyl chain length, the strongest interaction for both TbMscL and EcMscL being observed with a chain of length C16, corresponding to a bilayer of hydrophobic thickness ca. 24 A, compared to a hydrophobic thickness for TbMscL of about 26 A estimated from the crystal structure. Lipid binding constants change by only a factor of 1.5 in the chain length range from C12 to C24, much less than expected from theories of hydrophobic mismatch in which the protein is treated as a rigid body. It is concluded that MscL distorts to match changes in bilayer thickness. The binding constants for dioleoylphosphatidylethanolamine for both TbMscL and EcMscL relative to those for dioleoylphosphatidylcholine are close to 1. Quenching experiments suggest a single class of binding sites for phosphatidylserine, phosphatidylglycerol, and cardiolipin on TbMscL; binding constants are greater than those for phosphatidylcholine and decrease with increasing ionic strength, suggesting that charge interactions are important in binding these anionic phospholipids. Quenching experiments suggest two classes of lipid binding sites on TbMscL for phosphatidic acid, binding of phosphatidic acid being much less dependent on ionic strength than binding of phosphatidylserine.     

Interactions of phospholipids with the potassium channel KcsA

The potassium channel KcsA from Streptomyces lividans has been reconstituted into bilayers of phosphatidylcholines and fluorescence spectroscopy has been used to characterize the response of KcsA to changes in bilayer thickness. The Trp residues in KcsA form two bands, one on each side of the membrane. Trp fluorescence emission spectra and the proportion of the Trp fluorescence intensity quenchable by I(-) hardly vary in the lipid chain length range C10 to C24, suggesting efficient hydrophobic matching between KcsA and the lipid bilayer over this range. Measurements of fluorescence quenching for KcsA reconstituted into mixtures of brominated and nonbrominated phospholipids have been analyzed to give binding constants of lipids for KcsA, relative to that for dioleoylphosphatidylcholine (di(C18:1)PC). Relative lipid binding constants increase by only a factor of three with increasing chain length from C10 to C22 with a decrease from C22 to C24. Strongest binding to di(C22:1)PC corresponds to a state in which the side chains of the lipid-exposed Trp residues are likely to be located within the hydrocarbon core of the lipid bilayer. It is suggested that matching of KcsA to thinner bilayers than di(C24:1)PC is achieved by tilting of the transmembrane alpha-helices in KcsA. Measurements of fluorescence quenching of KcsA in bilayers of brominated phospholipids as a function of phospholipid chain length suggest that in the chain length range C14 to C18 the Trp residues move further away from the center of the lipid bilayer with increasing chain length, which can be partly explained by a decrease in helix tilt angle with increasing bilayer thickness. In the chain length range C18 to C24 it is suggested that the Trp residues become more buried within the hydrocarbon core of the bilayer.     

Multiple equilibria binding treatment of lipid and detergent interactions with membrane proteins. Application to cytochrome c oxidase solubilized in cholate

A modified multiple binding equilibria treatment is presented that allows determination of thermodynamic parameters of the interaction of phospholipids with integral membrane proteins solubilized in excess detergent. Lipid binding is modeled as a series of exchange reactions between lipid molecules and detergent molecules at the hydrophobic protein surface. A general equation is derived which expresses a relative association constant (K) and the total number of contact sites at the lipid-protein interface (N) in terms of experimentally measurable variables. A useful simplification of the general equation occurs when the amount of detergent is high relative to the total number of lipid binding sites in the sample. Computer simulations show that in cases we have examined there appears to be an experimentally accessible range of detergent to protein molar ratios where the approximation at high detergent is useful for analyzing experimental data. This model is used to examine the competition between cholate and spin-labeled phospholipids for the hydrophobic surfaces of bovine heart cytochrome c oxidase. We find, for example, that K = 12 +/- 2 for phosphatidylcholine relative to cholate (i.e., the cholate molecules are relatively easily displaced by membrane lipids). This helps to explain the experimental observation that cholate is an effective detergent both for solubilizing cytochrome c oxidase and for reconstituting this protein into a defined lipid bilayer environment. An excess of cholate readily displaces almost all of the native phospholipids, and the protein is dispersed in cholate micelles. However, when phospholipids are added back, the cholate molecules at the protein surface are replaced because of the higher relative binding of the phospholipids. Observed differences between the behavior of phosphatidylcholine and phosphatidylglycerol suggest that reconstitution in cholate is a selective process in which detergent molecules in localized areas on the protein surface are more readily displaced by certain phospholipids.     

Interaction of the 140/130/110 kDa rhoptry protein complex of Plasmodium falciparum with the erythrocyte membrane and liposomes

During Plasmodium falciparum merozoite invasion into human and mouse erythrocytes, a 110-kDa rhoptry protein is secreted from the organelle into the erythrocyte membrane. In the present study our interest was to examine the interaction of rhoptry proteins of P. falciparum with the erythrocyte membrane. It was observed that the complex of rhoptry proteins of 140/130/110 kDa bind directly to a trypsin sensitive site on intact mouse erythrocytes, and not human, saimiri, or other erythrocytes. However, when erythrocytes were disrupted by hypotonic lysis, rhoptry proteins of 140/130/110 kDa were found to bind to membranes and inside-out vesicles prepared from human, mouse, saimiri, rhesus, rat, and rabbit erythrocytes. A binding site on the cytoplasmic face of the erythrocyte membrane suggests that the rhoptry proteins may be translocated across the lipid bilayer during merozoite invasion. Furthermore, pretreatment of human erythrocytes with a specific peptide derived from MSA-1, the major P. falciparum merozoite surface antigen of MW 190,000-200,000, induced binding of the 140/130/110-kDa complex. The rhoptry proteins bound equally to normal human erythrocytes and erythrocytes treated with neuraminidase, trypsin, and chymotrypsin indicating the binding site was independent of glycophorin and other major surface proteins. The rhoptry protein complex also bound specifically to liposomes prepared from different types of phospholipids. Liposomes containing PE effectively block binding of the rhoptry proteins to mouse cells, suggesting that there are two binding sites on the mouse membrane for the 140/130/110-kDa complex, one protein and a second, possibly lipid in nature. The results of this study suggest that the 140/130/110 kDa protein complex may interact directly with sites in the lipid bilayer of the erythrocyte membrane.     

Phospholipid-cytochrome c interaction: evidence for the extended lipid anchorage.

Binding of cytochrome c (cyt c) to fatty acids and acidic phospholipid membranes produces pronounced and essentially identical changes in the spectral properties of cyt c, revealing conformational changes in the protein. The exact mechanism of the interaction of fatty acids and acidic phospholipids with cyt c is unknown. Binding of cyt c to liposomes with high contents (mole fraction X > 0.7) of acidic phospholipids caused spectral changes identical to those due to binding of oleic acid. Fluorescence spectroscopy of a cyt c analog containing a Zn(2+) substituted heme moiety and brominated lipid derivatives (9,10)-dibromostearate and 1-palmitoyl-2-(9,10)-dibromo-sn-glycero-3-phospho-rac-glycerol demonstrated a direct contact between the fluorescent [Zn(2+)-heme] group and the brominated acyl chain. These data constitute direct evidence for interaction between an acyl chain of a membrane phospholipid and the inside of the protein containing the heme moiety and provide direct evidence for the so-called extended-lipid anchorage of cyt c to phospholipid membranes. In this mechanism, one of the phospholipid acyl chains protrudes out of the membrane and intercalates into a hydrophobic channel in cyt c while the other chain remains in the bilayer.     

Annular and nonannular binding sites for cholesterol associated with the nicotinic acetylcholine receptor

Interactions between lipids and the nicotinic acetylcholine receptor from Torpedo californica have been measured in reconstituted membranes containing purified receptor and defined lipids. The ability of brominated lipids to partially quench the intrinsic fluorescence of the acetylcholine receptor has been exploited to monitor contacts between the protein and the surrounding lipid. Relative binding constants for lipid binding to the protein have been quantitatively determined by measuring quenching observed in mixtures of brominated and nonbrominated lipids by use of equilibrium exchange equations developed by London and Feigenson [London, E., & Feigenson, G. W. (1981) Biochemistry 20, 1939-1948] and by Simmonds et al. [Simmonds, A. C., Rooney, E. K., & Lee, A. G. (1984) Biochemistry 23, 1432-1441]. Dioleoylphosphatidylcholine and its dibromo derivative are the two principal lipids used in the reconstituted membranes to establish the quenching parameters. Competition studies between cholesterol and phosphatidylcholine indicate that cholesterol does not compete effectively for the phospholipid sites presumed to surround the membrane-embedded portions of the receptor (annular lipids). However, dibromocholesterol partially quenches the receptor and leads to additional quenching of receptor in pure dibromophosphatidylcholine membranes. The results are consistent with the presence of additional binding sites for cholesterol that are not accessible to phospholipids (nonannular sites). Similar results are obtained by using cholesterol hemisuccinate and its dibromo analogue, both of which can be introduced into membranes more easily than cholesterol because of their greater solubility in water. Fatty acids appear to compete for both annular and nonannular sites, and analysis of the quenching data suggests that there are 5-10 nonannular sites associated with the receptor. Cholesterol has been shown to play a critical role in both acetylcholine receptor structural stabilization and ion channel activity, and the results presented here provide additional information about cholesterol-receptor interactions.     

The Bilayer Collective Properties Govern the Interaction of an HIV-1 Antibody with the Viral Membrane

Efficient engagement with the envelope glycoprotein membrane-proximal external region (MPER) results in robust blocking of viral infection by a class of broadly neutralizing antibodies (bnAbs) against human immunodeficiency virus (HIV). Developing an accommodation surface that engages with the viral lipid envelope appears to correlate with the neutralizing potency displayed by these bnAbs. The nature of the interactions established between the antibody and the lipid is nonetheless a matter of debate, with some authors arguing that anti-MPER specificity arises only under pathological conditions in autoantibodies endowed with stereospecific binding sites for phospholipids. However, bnAb-lipid interactions are often studied in systems that do not fully preserve the biophysical properties of lipid bilayers, and therefore, questions on binding specificity and the effect of collective membrane properties on the interaction are still open. Here, to evaluate the specificity of lipid interactions of an anti-MPER bnAb (4E10) in an intact membrane context, we determine quantitatively its association with lipid bilayers by means of scanning fluorescence correlation spectroscopy and all-atom molecular dynamic simulations. Our data support that 4E10 establishes electrostatic and hydrophobic interactions with the viral membrane surface and that the collective physical properties of the lipid bilayer influence 4E10 dynamics therein. We conclude that establishment of peripheral, nonspecific electrostatic interactions with the viral membrane through accommodation surfaces may assist high-affinity binding of HIV-1 MPER epitope at membrane interfaces. These findings highlight the importance of considering antibody-lipid interactions in the design of antibody-based anti-HIV strategies.     

Lipid--protein multiple binding equilibria in membranes

Phospholipids at the lipid--protein interface of membrane proteins are in dynamic equilibrium with fluid bilayer. In order to express the number of binding sites (N) and the relative binding constants (K) in terms of measurable quantities, the equilibrium is formulated as an exchange reaction between lipid molecules competing for hydrophobic sites on the protein surface. Experimental data are reported on two integral membrane proteins, cytochrome oxidase and (Na,-K)-ATPase, reconstituted into defined phospholipids. Electron spin resonance measurements on reconstituted preparations of beef heart cytochrome oxidase in 1,2-dioleoyl-sn-3-phosphatidylcholine containing small quantities of the spin-labeled phospholipid 1-palmitoyl-2-(14-proxylstearoyl)-sn-3-phosphatidylcholine (PC*) gave a linear plot of bilayer/bound PC* vs. the lipid/protein ratio as predicted by the theory, with K congruent to 1 and N = 40 (normalized to heme aa3). This demonstrates that the spin-label moiety attached to the hydrocarbon chain does not significantly perturb the binding equilibria. In the second experimental system, (Na,K)-ATPase purified from rectal glands of Squalus acanthias was reconstituted with defined phosphatidylcholines as the lipid solvent and spin-labeled phospholipids with choline or serine head groups (PC*, PS*) as the solute. The (Na,K)-ATPase has a larger number of lipid binding or contact sites (N = 60-65 per alpha 2 beta 2 dimer) and exhibits a detectably larger average binding constant for the negatively charged phosphatidylserine than for the corresponding phosphatidylcholine. These results show that a multiple equilibria, noninteracting site binding treatment can account for the behavior of lipids exchanging between the protein surface and the lipid bilayer. Selective sites among a background of nonselective sites are experimentally detectable as a change in the measured relative binding constant.     

Cholesterol and anionic phospholipids increase the binding of amyloidogenic transthyretin to lipid membranes

Deposition of transthyretin (TTR) amyloid is a pathological hallmark of familial amyloidotic polyneuropathy (FAP). Recently we showed that TTR binds to membrane lipids via electrostatic interactions and that membrane binding is correlated with the cytotoxicity induced by amyloidogenic TTR. In the present study, we examined the role of lipid composition in membrane binding of TTR by a surface plasmon resonance (SPR) approach. TTR bound to lipid bilayers through both high- and low-affinity interactions. Increasing the mole fraction of cholesterol in the bilayer led to an increase in the amount of high-affinity binding of an amyloidogenic mutant (L55P) TTR. In addition, a greater amount of L55P TTR bound with high affinity to membranes made from anionic phospholipids, phosphatidylglycerol (PG) and phosphatidylserine (PS), than to membranes made from zwitterionic phospholipid phosphatidylcholine (PC). The anionic phospholipids (PS and PG) promoted the aggregation of L55P TTR by accelerating the nucleation phase of aggregation, whereas the zwitterionic phospholipid PC had little effect. These results suggest that cholesterol and anionic phospholipids may be important for TTR aggregation and TTR-induced cytotoxicity.     

Cholesterol and anionic phospholipids increase the binding of amyloidogenic transthyretin to lipid membranes

Deposition of transthyretin (TTR) amyloid is a pathological hallmark of familial amyloidotic polyneuropathy (FAP). Recently we showed that TTR binds to membrane lipids via electrostatic interactions and that membrane binding is correlated with the cytotoxicity induced by amyloidogenic TTR. In the present study, we examined the role of lipid composition in membrane binding of TTR by a surface plasmon resonance (SPR) approach. TTR bound to lipid bilayers through both high- and low-affinity interactions. Increasing the mole fraction of cholesterol in the bilayer led to an increase in the amount of high-affinity binding of an amyloidogenic mutant (L55P) TTR. In addition, a greater amount of L55P TTR bound with high affinity to membranes made from anionic phospholipids, phosphatidylglycerol (PG) and phosphatidylserine (PS), than to membranes made from zwitterionic phospholipid phosphatidylcholine (PC). The anionic phospholipids (PS and PG) promoted the aggregation of L55P TTR by accelerating the nucleation phase of aggregation, whereas the zwitterionic phospholipid PC had little effect. These results suggest that cholesterol and anionic phospholipids may be important for TTR aggregation and TTR-induced cytotoxicity.     

Interactions of lipids and proteins: Some general principles

Methods to describe the binding of phospholipids to membrane proteins are described. It is shown that it is difficult to obtain estimates of the number of phospholipids bound to the surface of a membrane protein from ESR experiments in which plots of free to bound spin label (y) vs. molar ratio of lipid to protein are extrapolated toy=0. The relative advantages and disadvantages of ESR and fluorescence methods for measuring relative binding constants of phospholipids to membrane proteins are discussed. The particular problems associated with comparing binding constants of molecules of very different sizes (e.g., fatty acids and cardiolipin) are described and equations are presented to account for these problems. The possible effects of membrane viscosity and thickness on activity of membrane proteins are discussed, but it is concluded that effects of phospholipid structure on activity can only be understood in terms of a reasonably complete kinetic model for the protein.     

Electrostatic and hydrophobic interactions governing the interaction and binding of beta-lactoglobulin to membranes

The role of electrostatic and hydrophobic interactions in the binding and penetration of beta-lactoglobulin (betaLG) to preformed lipid membranes was studied using various phospholipid micelles and vesicles. Zwitterionic lysophospholipid micelles are able to induce the beta-sheet to alpha-helix transition, as judged by circular dichroism (CD), but the degree of transition is dramatically below and the amount of lipid required above that for anionic phospholipids with equivalent hydrocarbon chains. Anionic phospholipids with short hydrocarbon chains induce only low alpha-helical content in betaLG as compared to phospholipids with the same head group but longer hydrocarbon chains. These results suggest that both electrostatic and hydrophobic interactions are indispensable in betaLG-lipid interaction. Furthermore, air-water interface monolayer surface pressure and fluorescence anisotropy studies reveal that the membrane insertion of betaLG strongly depends on the nature of phospholipids, given the identical headgroup, particularly lipid packing. These results are supported by urea denaturation and acrylamide fluorescence quenching tests and by the FTIR-ATR polarization results for betaLG in multilayers on a surface. Under the same experimental conditions, the membrane binding and insertion of betaLG as well as the stability of the betaLG-lipid complexes can be enhanced by lowering the pH. Collectively, electrostatic interactions play a crucial role in all the processes involved in the betaLG-lipid interaction, while the presence of hydrophobic interaction remains necessary. Finally, betaLG biological function in the transport of fatty acids was tested by demonstrating the release of 2-AS from a 2-AS-betaLG complex on binding to lipids.     

Interaction of phospholipids with the detergent-solubilized ADP/ATP carrier protein as studied by spin-label electron spin resonance

The interaction of spin-labeled phospholipids with the detergent-solubilized ADP/ATP carrier protein from the inner mitochondrial membrane has been investigated by electron spin resonance spectroscopy. The equilibrium binding of cardiolipin and phosphatidic acid was studied by titration of the protein with spin-labeled phospholipid analogues using a spectral subtraction protocol for the evaluation of the mobile and immobilized lipid portions. This analysis revealed the immobilization of two molecules of spin-labeled cardiolipin per protein dimer. Phosphatidic acid has a similar affinity for the protein surface as cardiolipin. The lipid-protein interaction was less pronounced with the neutral phospholipids and with phosphatidylglycerol. The importance of the electrostatic contribution to the phospholipid-protein interaction shows up with a strong dependence of the lipid binding on salt concentration. Cleavage by phospholipase A2 and spin reduction by ascorbate of the spin-labeled acidic phospholipids in contact with the protein surface suggest that these lipids are located on the outer perimeter of the protein. At reduced detergent concentration, the protein aggregated upon addition of small amounts of cardiolipin but remained solubilized when more cardiolipin was added. This result is discussed with respect to the aggregation state of the protein in the mitochondrial membrane. It is also tentatively concluded that binding of spin-labeled cardiolipin does not displace the tightly bound cardiolipin of mitochondrial origin, which was detected previously by 31P nuclear magnetic resonance spectroscopy.     

Evidence that helix 8 of rhodopsin acts as a membrane-dependent conformational switch

The crystal structure of rhodopsin revealed a cytoplasmic helical segment (H8) extending from transmembrane (TM) helix seven to a pair of vicinal palmitoylated cysteine residues. We studied the structure of model peptides corresponding to H8 under a variety of conditions using steady-state fluorescence, fluorescence anisotropy, and circular dichroism spectroscopy. We find that H8 acts as a membrane-surface recognition domain, which adopts a helical structure only in the presence of membranes or membrane mimetics. The secondary structural properties of H8 further depend on membrane lipid composition with phosphatidylserine inducing helical structure. Fluorescence quenching experiments using brominated acyl chain phospholipids and vesicle leakage assays suggest that H8 lies within the membrane interfacial region where amino acid side chains can interact with phospholipid headgroups. We conclude that H8 in rhodopsin, in addition to its role in binding the G protein transducin, acts as a membrane-dependent conformational switch domain.     

Mapping lipid and detergent molecules at the surface of membrane proteins

Electron-density maps for the crystal structures of membrane proteins often show features suggesting binding of lipids and/or detergent molecules on the hydrophobic surface, but usually it is difficult to identify the bound molecules. In our studies, heavy-atom-labelled phospholipids and detergents have been used to unequivocally identify these binding sites at the surfaces of test membrane proteins, the reaction centres from Rhodobacter sphaeroides and Blastochloris viridis. The generality of this method is discussed in the present article.