Structure and mechanism of the bacterial lipid ABC transporter,MlaFEDB

The cell envelope of Gram-negative bacteria is composed of an inner membrane, outer membane, and an intervening periplasmic space. How the outer membrane lipids are trafficked and assembled there, and how the asymmetry of the outer membrane is maintained is an area of intense research. The Mla system has been implicated in the maintenance of lipid asymmetry in the outer membrane, and is generally thought to drive the removal of mislocalized phospholipids from the outer membrane and their retrograde transport to the inner membrane. At the heart of the Mla pathway is a structurally unique ABC transporter complex in the inner membrane, called MlaFEDB. Recently, an explosion of cryo-EM studies has begun to shed light on the structure and lipid translocation mechanism of MlaFEDB, with many parallels to other ABC transporter families, including human ABCA and ABCG, as well as bacterial lipopolysaccharide and O-antigen transporters. Here we synthesize information from all available structures, and propose a model for lipid trafficking across the cell envelope by MlaFEDB.     

Translocation of phospholipids between the outer and inner membranes of Salmonella typhimurium.

The reversibility and specificity of phospholipid translocation between the inner and outer membrane of Salmonella typhimurium has been investigated by incorporating exogenous lipids from phospholipid vesicles into the outer membrane of intact cells. Translocation of newly incorporated phospholipids to the inner membrane was demonstrated by decarboxylation of vesicle-derived phosphatidylserine and by recovery of vesicle constituents in both inner and outer membrane fractions. All Salmonella phospholipids tested, as well as phosphatidylcholine and cholesteryl oleate were effectively translocated to the inner membrane. However, no translocation of vesicle-derived lipopolysaccharide or an incomplete biosynthetic precursor of lipid A could be detected. Translocation of phospholipids and cholesteryl ester was rapid and extensive, and appeared to lead to equilibration of the lipids between the two membranes. The mechanism of intermembrane translocation has not been established, but the results are suggestive of diffusional flow across zones of adhesion between the inner and outer membranes.     

Lipid analysis of mitochondrial membranes from the yeast Pichia pastoris

Here we describe for the first time isolation and biochemical characterization of highly purified mitochondrial inner and outer membranes from Pichia pastoris and systematic lipid analysis of submitochondrial fractions. Mitochondria of this yeast are best developed during growth on glycerol or sorbitol, but also on methanol or fatty acids. To obtain organelle membranes at high quality, methods of isolation and subfractionation of mitochondria originally developed for Saccharomyces cerevisiae were adapted and employed. A characteristic feature of the outer mitochondrial membrane of P. pastoris is the higher phospholipid to protein ratio and the lower ergosterol to phospholipid ratio compared to the inner membrane. Another marked difference between the two mitochondrial membranes is the phospholipid composition. Phosphatidylcholine and phosphatidylethanolamine are major phospholipids of both membranes, but the inner membrane is enriched in cardiolipin, whereas the outer membrane contains a high amount of phosphatidylinositol. The fatty acid composition of both mitochondrial membranes is similar. Variation of the carbon source, however, leads to marked changes of the fatty acid pattern both in total and mitochondrial membranes. In summary, our data are the first step to understand the P. pastoris lipidome which will be prerequisite to manipulate membrane components of this yeast for biotechnological purposes.     

Lipid topology and physical properties of the outer mitochondrial membrane of the yeast, Saccharomyces cerevisiae

The outer membrane of yeast mitochondria was studied with respect to its lipid composition, phospholipid topology and membrane fluidity. This membrane is characterized by a high phospholipid to protein ratio (1.20). Like other yeast cellular membranes the outer mitochondrial membrane contains predominantly phosphatidylcholine (44% of total phospholipids), phosphatidylethanolamine (34%) and phosphatidylinositol (14%). Cardiolipin, the characteristic phospholipid of the inner mitochondrial membrane (13% of total phospholipids) is present in the outer membrane only to a moderate extent (5%). The ergosterol to phospholipid ratio is higher in the inner (7.0 wt%) as compared to the outer membrane (2.1 wt.%). Attempts to study phospholipid asymmetry by selective degradation of phospholipids of the outer leaflet of the outer mitochondrial membrane failed, because isolated right-side-out vesicles of this membrane became leaky upon treatment with phospholipases. Selective removal of phospholipids of the outer leaflet with the aid of phospholipid transfer proteins and chemical modification with trinitrobenzenesulfonic acid on the other hand, gave satisfactory results. Phosphatidylcholine and phosphatidylinositol are more or less evenly distributed between the two sides of the outer mitochondrial membrane, whereas the majority of phosphatidylethanolamine is oriented towards the intermembrane space. The fluidity of mitochondrial membranes was determined by measuring fluorescence anisotropy using diphenylhexatriene (DPH) as a probe. The lower anisotropy of DPH in the outer as compared to the inner membrane, which is an indication for an increased lipid mobility in the outer membrane, was attributed to the higher phospholipid to protein and the lower ergosterol to phospholipid ratio. The data presented here show, that the outer mitochondrial membrane, in spite of its close contact to the inner membrane, is distinct not only with respect to its protein pattern, but also with respect to its lipid composition and physical membrane properties.     

MlaC belongs to a unique class of non-canonical substrate-binding proteins and follows a novel phospholipid-binding mechanism

The outer membrane (OM) of Gram-negative bacteria acts as a formidable barrier against a plethora of detrimental compounds owing to its asymmetric nature. This is because the OM possesses lipopolysaccharides (LPSs) in the outer leaflet and phospholipids (PLs) in the inner leaflet. The maintenance of lipid asymmetry (Mla) system is involved in preserving the distribution of PLs in OM. The periplasmic component of the system MlaC serves as the substrate-binding protein (SBP) that shuttles PLs between the inner and outer membranes. However, an in-depth report highlighting its mechanism of ligand binding is still lacking. This study reports the crystal structure of MlaC from Escherichia coli (EcMlaC) at a resolution of 2.5 Å in a quasi-open state, complexed with PL. The structural analysis reveals that EcMlaC and orthologs comprise two major domains, viz. nuclear transport factor 2-like (NTF2-like) and phospholipid-binding protein (PBP). Each domain can be further divided into two subdomains arranged in a discontinuous fashion. This study further reveals that EcMlaC is polyspecific in nature and follows a reverse mechanism of the opening of the substrate-binding site during the ligand binding. Furthermore, MlaC can bind two PLs by forming subsites in the binding pocket. These findings, altogether, have led to the proposition of the unique “segmented domain movement” mechanism of PL binding, not reported for any known SBP to date. Further, unlike typical SBPs, MlaC has originated from a cystatin-like fold. Overall, this study establishes MlaC to be a non-canonical SBP with a unique ligand-binding mechanism.     

Stereochemical Analysis of Interaction of Signal Peptide with Phospholipids at the Initiation of Protein Translocation Across the Membrane

Abstract

Stereochemical analysis of signal peptide interaction with E. coli membrane phospholipids revealed the structural complementarity of N-terminus of signal peptide α-helix and acid phospholipids. The formation of their complex leads to neutralization of charges and decrease in hydrophilicity of both components, and promotes insertion of peptide and phospholipid into the membrane, not separately but as a complex. Interaction of acid phospholipids with the E. coli alkaline phosphatase (AP) signal peptide was thoroughly analyzed, and it was shown that in this case a complex of signal peptide α-helix with phosphatidylglycerol is inserted into the membrane with the lowest energy expense. On the basis of the results of stereochemical analysis and the available experimental data, a molecular mechanism of protein translocation initiation across the membrane has been proposed, in which the key events are the formation of the complex “signal peptide α-helix-acid phospholipid”, the coupled insertion of hydrophobic peptide-lipid complex into a nonpolar membrane interior and translocation across the membranes.     

Translocation of phospholipids is facilitated by a subset of membrane-spanning proteins of the bacterial cytoplasmic membrane

The mechanism by which phospholipids are transported across biogenic membranes, such as the bacterial cytoplasmic membrane, is unknown. We hypothesized that this process is mediated by the presence of the membrane-spanning segments of inner membrane proteins, rather than by dedicated flippases. In support of the hypothesis, it was demonstrated that transmembrane alpha-helical peptides, mimicking the membrane-spanning segments, mediate flop of 2-6-(7-nitro-2,1,3-benzoxadiazol-4-yl) aminocaproyl (C6-NBD)-phospholipids (Kol, M. A., de Kroon, A. I., Rijkers, D. T., Killian, J. A., and de Kruijff, B. (2001) Biochemistry 40, 10500-10506). Here the dithionite reduction assay was used to measure transbilayer equilibration of C6-NBD-phospholipids in proteoliposomes, composed of Escherichia coli phospholipids and a subset of bacterial membrane proteins. It is shown that two well characterized integral proteins of the bacterial cytoplasmic membrane, leader peptidase and the potassium channel KcsA, induce phospholipid translocation, most likely by their transmembrane domains. In contrast, the ATP-binding cassette transporter from the E. coli inner membrane MsbA, a putative lipid flippase, did not mediate phospholipid translocation, irrespective of the presence of ATP. OmpT, an outer membrane protein from E. coli, did not facilitate flop either, demonstrating specificity of protein-mediated phospholipid translocation. The results are discussed in the light of phospholipid transport across the E. coli inner membrane.     

Lipid trafficking controls endotoxin acylation in outer membranes of Escherichia coli

The biogenesis of biological membranes hinges on the coordinated trafficking of membrane lipids between distinct cellular compartments. The bacterial outer membrane enzyme PagP confers resistance to host immune defenses by transferring a palmitate chain from a phospholipid to the lipid A (endotoxin) component of lipopolysaccharide. PagP is an eight-stranded antiparallel beta-barrel, preceded by an N-terminal amphipathic alpha-helix. The active site is localized inside the beta-barrel and is aligned with the lipopolysaccharide-containing outer leaflet, but the phospholipid substrates are normally restricted to the inner leaflet of the asymmetric outer membrane. We examined the possibility that PagP activity in vivo depends on the aberrant migration of phospholipids into the outer leaflet. We find that brief addition to Escherichia coli cultures of millimolar EDTA, which is reported to replace a fraction of lipopolysaccharide with phospholipids, rapidly induces palmitoylation of lipid A. Although expression of the E. coli pagP gene is induced during Mg2+ limitation by the phoPQ two-component signal transduction pathway, EDTA-induced lipid A palmitoylation occurs more rapidly than pagP induction and is independent of de novo protein synthesis. EDTA-induced lipid A palmitoylation requires functional MsbA, an essential ATP-binding cassette transporter needed for lipid transport to the outer membrane. A potential role for the PagP alpha-helix in phospholipid translocation to the outer leaflet was excluded by showing that alpha-helix deletions are active in vivo. Neither EDTA nor Mg(2+)-EDTA stimulate PagP activity in vitro. These findings suggest that PagP remains dormant in outer membranes until Mg2+ limitation promotes the migration of phospholipids into the outer leaflet.     

Stereochemical analysis of interaction of signal peptide with phospholipids at the initiation of protein translocation across the membrane.

Stereochemical analysis of signal peptide interaction with E. coli membrane phospholipids revealed the structural complementarity of N-terminus of signal peptide alpha-helix and acid phospholipids. The formation of their complex leads to neutralization of charges and decrease in hydrophilicity of both components, and promotes insertion of peptide and phospholipid into the membrane, not separately but as a complex. Interaction of acid phospholipids with the E. coli alkaline phosphatase (AP) signal peptide was thoroughly analyzed, and it was shown that in this case a complex of signal peptide alpha-helix with phosphatidylglycerol is inserted into the membrane with the lowest energy expense. On the basis of the results of stereochemical analysis and the available experimental data, a molecular mechanism of protein translocation initiation across the membrane has been proposed, in which the key events are the formation of the complex "signal peptide alpha-helix-acid phospholipid", the coupled insertion of hydrophobic peptide-lipid complex into a nonpolar membrane interior and translocation across the membranes.     

大鼠心肌线粒体内、外膜磷脂动态结构的研究

我们以DPH为荧光探针.用毫微秒荧光分光光度计测定了大鼠心肌线粒体及线粒体内、外膜的动态微细结构;用HPLC分析了磷脂组成.实验结果提示.完整线粒体膜流动性主要反映了线粒体外膜的运动状态.线粒体内膜微粘度及磷脂分子摇动角大于外膜,扩散速率小于外膜.除去了蛋白质的线粒体内、外膜磷脂脂质体膜流动性无明显差异.提示线粒体内膜的高微粘度与膜中所含有的多量蛋白有关.     

Transverse Distribution of Phospholipids in Organelle Membranes from Ricinus communis L. var. Hale Endosperm: MITOCHONDRIA AND GLYOXYSOMES

Phospholipase A₂ (Naja naja), the nonpenetrating dye trinitrobenzene sulfonate, and the penetrating dye dinitrofluorobenzene, were used to determine the transmembrane distributions of phospholipids of mitochondria and glyoxysomes isolated from endosperm tissue of castor bean (Ricinus communis L. var. Hale). These studies indicated that the phospholipid distributions were distinctly asymmetric in the accessible (reacted with the probes without total membrane disruption by detergents) pools of the glyoxysomal and inner mitochondrial membranes, but more nearly symmetric in the outer mitochondrial membrane. However, significant quantities of the phospholipids of the mitochondrial membranes were inaccessible to the probes used. An increased accessibility of the phospholipids of all membranes following Triton X-100 dispersion was found, and protein to phospholipid ratios in organelle membranes were found to correlate inversely with the accessibility of the phospholipids to the probes. The inaccessible phospholipids may be involved in lipid-protein interactions.     

Spectrin as a stabilizer of the phospholipid asymmetry in the human erythrocyte membrane

After treatment of intact human erythrocytes with SH-oxidizing agents (e.g. tetrathionate and diamide) phospholipase A₂ cleaves approx. 30% of the phosphatidylserine and 50% of the phosphatidylethanolamine without causing hemolysis (Haest, C.W.M. and Deuticke, B. (1976) Biochim. Biophys. Acta 436, 353–365). These phospholipids are scarcely hydrolysed in fresh erythrocytes and are assumed to be located in the inner lipid layer of the membrane (Verkleij, A.J., Zwaal, R.F.A., Roelofsen, B., Comfurius, P., Kastelijn, D. and van Deenen, L.L.M. (1973) Biochim. Biophys. Acta 323, 178–193). The enhancement of the phospholipid cleavage is now shown to be accompanied by a 50% decrease of the membrane SH-groups and a cross-linking of spectrin, located at the inner surface of the membrane, to oligomers of < 10⁶ dalton.Blocking approx. 10% of the membrane SH groups with N-ethylmaleimide suppresses both the polymerization of spectrin and the enhancement of the phospholipid cleavage. N-Ethylmaleimide, under these conditions, reacts with three SH groups per molecule of spectrin, 0.7 SH groups per major intrinsic 100 000 dalton protein (band 3) and 1.1 SH groups per molecule of an extrinsic protein of 72 000 daltons (band 4.2). Blocking studies with iodoacetamide demonstrate that the SH groups of the 100 000-dalton protein are not involved in the effects of the SH-oxidizing agents.It is suggested that a release of constraints imposed by spectrin enables phosphatidylserine and phosphatidylethanolamine to move from the inner to the outer lipid layer of the erythrocyte membrane and that spectrin, in the native erythrocyte, stabilizes the orientation of these phospholipids to the inner surface of the membrane.     

Outer membrane of Salmonella typhimurium. Electron spin resonance studies

The supramolecular structure of the outer membrane of Salmonella typhimurium that produces an Rc-type lipopolysaccharide was studied by adding spin-labeled fatty acid probes to membranes as well as model bilayers. Lipopolysaccharide of this organism apparently formed a bilayer structure in 0.2 M NaCl/0.01 M MgCl₂, and the electron spin resonance spectra suggested that the motion of the segments of hydrocarbon chains near the carboxyl end was quite restricted even at high temperature; this is presumably due to the anchoring of more than a dozen fatty acid residues to a single backbone structure. In the presence of Mg²⁺, we could produce lipopolysaccharide-phospholipid mixed bilayers containing up to 50% (by weight) lipopolysaccharide. Their spectra showed no sign of major heterogeneity, and the maximum hypertine splitting values were considerably larger than in phospholipid-only liposomes; these results suggest that the two components are finely interspersed and that the mobility of phospholipid hydrocarbons in severely restricted by the hydrocarbon chains of lipopolysaccharide. In spite of the presence of lipopolysaccharide in an amount equal to or exceeding that of phospholipids, the outer membrane produced spectra remarkably similar to those of the inner membrane, which does not contain lipopolysaccharide, and there was little sign of immobilization by lipopolysaccharides. Signals corresponding to the pure lipopolysaccharide phase were not detected, either. These results suggest that the phospholipids and lipopolysaccharides are segregated into separate domains in the outer membrane, and the fatty acid probes enter almost exclusively into the phospholipid domains. This conclusion was fully corroborated by determining, through the exchange broadening of line width, the total area of the domains that accommodated the spin label probes.     

Transbilayer movement of dipalmitoylphosphatidylcholine in proteoliposomes reconstituted from detergent extracts of endoplasmic reticulum. Kinetics of transbilayer transport mediated by a single flippase and identification of protein fractions enriched in flippase activity

Phospholipid translocation (flip-flop) across membrane bilayers is typically assessed via assays utilizing partially water-soluble phospholipid analogs as transport reporters. These assays have been used in previous work to show that phospholipid translocation in biogenic (self-synthesizing) membranes such as the endoplasmic reticulum is facilitated by specific membrane proteins (flippases). To extend these studies to natural phospholipids while providing a framework to guide the purification of a flippase, we now describe an assay to measure the transbilayer translocation of dipalmitoylphosphatidylcholine, a membrane-embedded phospholipid, in proteoliposomes generated from detergent-solubilized rat liver endoplasmic reticulum. Translocation was assayed using phospholipase A(2) under conditions where the vesicles were determined to be intact. Phospholipase A(2) rapidly hydrolyzed phospholipids in the outer leaflet of liposomes and proteoliposomes with a half-time of approximately 0.1 min. However, for flippase-containing proteoliposomes, the initial rapid hydrolysis phase was followed by a slower phase reflecting flippase-mediated translocation of phospholipids from the inner to the outer leaflet. The amplitude of the slow phase was decreased in trypsin-treated proteoliposomes. The kinetic characteristics of the slow phase were used to assess the rate of transbilayer equilibration of phospholipids. For 250-nm diameter vesicles containing a single flippase, the half-time was 3.3 min. Proportionate reductions in equilibration half-time were observed for preparations with a higher average number of flippases/vesicle. Preliminary purification steps indicated that flippase activity could be enriched approximately 15-fold by sequential adsorption of the detergent extract onto anion and cation exchange resins.     

Aminophospholipid translocase in the plasma membrane of Friend erythroleukemic cells can induce an asymmetric topology for phosphatidylserine but not for phosphatidylethanolamine

The ATP-dependent translocation of phospholipids in the plasma membrane of intact Friend erythroleukemic cells (FELCs) was studied in comparison with that in the membrane of mature murine erythrocytes. This was done by following the fate of radiolabeled phospholipid molecules, previously inserted into the outer monolayer of the plasma membranes by using a non-specific lipid transfer protein. The transbilayer equilibration of these probe molecules was monitored by treating the cells--under essentially non-lytic conditions--with phospholipases A2 of different origin. Rapid reorientations of the newly introduced aminophospholipids in favour of the inner membrane leaflet were observed in fresh mouse erythrocytes; the inward translocation of phosphatidylcholine (PC) in this membrane proceeded relatively slow. In FELCs, on the other hand, all three glycerophospholipids equilibrated over both halves of the plasma membrane very rapidly, i.e. within 1 h; nevertheless, an asymmetric distribution in favour of the inner monolayer was only observed for phosphatidylserine (PS). Lowering the ATP-level in the FELCs caused a reduction in the rate of inward translocation of both aminophospholipids, but not of that of PC, indicating that this translocation of PS and phosphatidylethanolamine (PE) is clearly ATP-dependent. Hence, the situation in the plasma membrane of the FELC is rather unique in a sense that, though an ATP-dependent translocase is present and active both for PS and PE, its activity results in an asymmetric distribution of PS, but not of PE. This remarkable situation might be the consequence of the fact that, in contrast to the mature red cell, this precursor cell still lacks a complete membrane skeletal network.     

Mechanisms of protein translocation into mitochondria

Mitochondrial biogenesis utilizes a complex proteinaceous machinery for the import of cytosolically synthesized preproteins. At least three large multisubunit protein complexes, one in the outer membrane and two in the inner membrane, have been identified. These translocase complexes cooperate with soluble proteins from the cytosol, the intermembrane space and the matrix. The translocation of presequence-containing preproteins through the outer membrane channel includes successive electrostatic interactions of the charged mitochondrial targeting sequence with a chain of import components. Translocation across the inner mitochondrial membrane utilizes the energy of the proton motive force of the inner membrane and the hydrolysis of ATP. The matrix chaperone system of the mitochondrial heat shock protein 70 forms an ATP-dependent import motor by interaction with the polypeptide chain in transit and components of the inner membrane translocase. The precursors of integral inner membrane proteins of the metabolite carrier family interact with newly identified import components of the intermembrane space and are inserted into the inner membrane by a second translocase complex. A comparison of the full set of import components between the yeast Sacccharomyces cerevisiae and the nematode Caenorhabditis elegans demonstrates an evolutionary conservation of most components of the mitochondrial import machinery with a possible greater divergence for the import pathway of the inner membrane carrier proteins.     

MsbA is not required for phospholipid transport in Neisseria meningitidis

The outer membrane of Gram-negative bacteria contains phospholipids and lipopolysaccharide (LPS) in the inner and outer leaflet, respectively. Little is known about the transport of the phospholipids from their site of synthesis to the outer membrane. The inner membrane protein MsbA of Escherichia coli, which is involved in the transport of LPS across the inner membrane, has been reported to be involved in phospholipid transport as well. Here, we have reported the construction and the characterization of a Neisseria meningitidis msbA mutant. The mutant was viable, and it showed a retarded growth phenotype and contained very low amounts of LPS. However, it produced an outer membrane, demonstrating that phospholipid transport was not affected by the mutation. Notably, higher amounts of phospholipids were produced in the msbA mutant than in its isogenic parental strain, provided that capsular biosynthesis was also disrupted. Although these results confirmed that MsbA functions in LPS transport, they also demonstrated that it is not required for phospholipid transport, at least not in N. meningitidis.     

Role of membrane-associated cytoskeleton in maintenance of membrane structure

Various structural components of biological membranes are asymmetrically localized in the two surfaces of the membrane bilayer. This asymmetry is absolute for membrane (glyco) proteins, but only a partial asymmetry has been observed for membrane phospholipids. In the red cell membrane, choline-phospholipids are localized mainly in the outer monolayer whereas aminophospholipids are distributed almost exclusively in the inner monolayer. Several evidences are now available to suggest that this distribution of membrane phospholipids in red cells is directly or indirectly maintained by the membrane-associated cytoskeleton (membrane skeleton). This belief is well supported by the previous as well as recent studies carried out in the authors laboratory. Previously, it has been shown that lipid-lipid interactions play no major role in maintaining the transmembrane phospholipid asymmetry in erythrocytes, and that the asymmetry is lost upon covalent crosslinking of the major membrane skeletal protein, spectrin. The recent data presented here further shows that degradation or denaturation of spectrin indices rapid transbilayer movement of membrane phospholipids in the cells which, in turn, leads to more random phospholipid distributions across the membrane. These studies taken together strongly suggest that the skeleton-membrane associations are the major determinants of the transmembrane phospholipid asymmetry in erythrocytes, and that the dissociation of the skeleton from the membrane bilayer probably results in generation of new reorientation sites for phospholipids in the membrane. Communication No 3648 from C.D.R.I., Lucknow.     

Reconstitution and partial characterization of phospholipid flippase activity from detergent extracts of the Bacillus subtilis cell membrane

In bacteria, phospholipids are synthesized on the inner leaflet of the cytoplasmic membrane and must translocate to the outer leaflet to propagate a bilayer. Transbilayer movement of phospholipids has been shown to be fast and independent of metabolic energy, and it is predicted to be facilitated by membrane proteins (flippases) since transport across protein-free membranes is negligible. However, it remains unclear as to whether proteins are required at all and, if so, whether specific proteins are needed. To determine whether bacteria contain specific proteins capable of translocating phospholipids across the cytoplasmic membrane, we reconstituted a detergent extract of Bacillus subtilis into proteoliposomes and measured import of a water-soluble phospholipid analog. We found that the proteoliposomes were capable of transporting the analog and that transport was inhibited by protease treatment. Active proteoliposome populations were also able to translocate a long-chain phospholipid, as judged by a phospholipase A(2)-based assay. Protein-free liposomes were inactive. We show that manipulation of the reconstitution mixture by prior chromatographic fractionation of the detergent extract, or by varying the protein/phospholipid ratio, results in populations of vesicles with different specific activities. Glycerol gradient analysis showed that the majority of the transport activity sedimented at approximately 4S, correlating with the presence of specific proteins. Recovery of activity in other gradient fractions was low despite the presence of a complex mixture of proteins. We conclude that bacteria contain specific proteins capable of facilitating transbilayer translocation of phospholipids. The reconstitution methodology that we describe provides the basis for purifying a facilitator of transbilayer phospholipid translocation in bacteria.     

Diverse effects of phospholipids on lipoprotein sorting and ATP hydrolysis by the ABC transporter LolCDE complex

The LolCDE complex of Escherichia coli releases outer membrane-specific lipoproteins from the inner membrane. Lipoproteins with Asp at + 2 remain in the inner membrane since this residue functions as a LolCDE avoidance signal depending on phosphatidylethanolamine. We examined the effects of other phospholipids on lipoprotein sorting in proteoliposomes reconstituted with LolCDE and various synthetic phospholipids. The lipoprotein release and ATP hydrolysis were both low at 2 mM Mg²⁺ but very high at 10 mM Mg²⁺ in proteoliposomes containing cardiolipin alone. However, the Lol avoidance function was abolished at 10 mM Mg²⁺, and the release of lipoproteins with Asp at + 2 was as efficient as that of outer membrane-specific lipoproteins. The addition of phosphatidylethanolamine to cardiolipin stimulated the ATP hydrolysis and increased the Lol avoidance function of Asp at + 2 at 2 mM Mg²⁺. The addition of phosphatidylglycerol to cardiolipin nearly completely inhibited the release of lipoproteins with Asp at + 2 even at 10 mM Mg²⁺, while that of outer membrane-specific lipoproteins was not. Taken together, these results indicate that three major phospholipids of E. coli differently affect lipoprotein sorting and the activity of LolCDE.