Non-covalent cross-linking of lipid bilayers by myelin basic protein. A possible role in myelin formation

Myelin basic protein associates with bilayer vesicles of pure egg phosphatidylcholine, l-α-dimyristoyl phosphatidylcholine and dl-α-dipalmitoyl phosphatidylcholine. Under optimum conditions the vesicles contain 15–18% of protein by weight. The binding to dipalmitoyl phosphatidylcholine is facilitated above its gel-to-liquid crystalline transition temperature. At low ionic strength the protein provokes a large increase in vesicle size and aggregation of these enlarged vesicles. Above a sodium chloride concentration of 0.07 M vesicle fusion is far less marked but aggregation persists. The pH- and ionic strength-dependence of this aggregation follows that of the protein alone; in both cases it occurs despite appreciable electrostatic repulsion between the associating species.A similar interaction was observed with diacyl phosphatidylserine vesicles.These observations, which contrast with earlier reports in the literature of a lack of binding of basic protein to phosphatidylcholine-containing lipids, demonstrate the ability of this protein to interact non-ionically with lipid bilayers. The strong cross-linking of lipid bilayers suggests a role for basic protein in myeling, raising the possibility that the protein is instrumental in collapsing the oligodendrocyte cell membrane and thus initiating myelin formation.     

Non-covalent cross-linking of lipid bilayers by myelin basic protein: a possible role in myelin formation.

Myelin basic protein associates with bilayer vesicles of pure egg phosphatidylcholine, L-alpha-dimyristoyl phosphatidylcholine and DL-alpha-dipalmitoyl phosphatidylcholine. Under optimum conditions the vesicles contain 15-18% of protein by weight. The binding to dipalmitoyl phosphatidylcholine is facilitated above its gel-to-liquid crystalline transition temperature. At low ionic strength the protein provokes a large increase in vesicle size and aggregation of these enlarged vesicles. Above a sodium chloride concentration of 0.07 M vesicle fusion is far less marked but aggregation persists. The pH- and ionic strength-dependence of this aggregation follows that of the protein alone; in both cases it occurs despite appreciable electrostatic repulsion between the associated species. A similar interaction was observed with diacyl phosphatidylserine vesicles. These observations, which contrast with earlier reports in the literature of a lack of binding of basic protein to phosphatidylcholine-containing lipids, demonstrate the ability of this protein to interact non-ionically with lipid bilayers. The strong cross-linking of lipid bilayers suggests a role for basic protein in myelin, raising the possibility that the protein is instrumental in collapsing the oligodendrocyte cell membrane and thus initiating myelin formation.     

Nonelectrostatic contributions to the binding of MARCKS-related protein to lipid bilayers.

The association of various protein constructs of MARCKS-related protein (MRP) lacking the myristoyl moiety or the basic effector domain (ED) or both to neutral and acidic supported planar phospholipid bilayer membranes has been monitored using two-mode optical waveguide spectroscopy. The importance of the myristoyl moiety for interaction with both neutral and acidic membranes is demonstrated but unmyristoylated MRP still binds appreciably to neutral membranes, albeit less than to acidic membranes. Only when both the myristoyl moiety and the ED are excised does the interaction fall to zero in the case of the acidic membranes, with very small residual binding still detectable in the presence of neutral membranes. These results point to the importance of hydrophobic interactions apart from those associated with the myristoyl moiety in the association of MRP with membranes. The ED is well endowed with hydrophobic as well as with basic residues, and the former are chiefly responsible for binding unmyristoylated MRP to neutral membranes: The very small residual attraction between MRP lacking both the myristoyl moiety and the ED is completely outweighed by electrostatic repulsion between the net acidic MRP and the acidic lipid head groups.     

Interaction of glycosylated human myelin basic protein with lipid bilayers

Myelin basic protein (MBP), isolated from normal human myelin, was glycosylated with UDP-N-acetyl-D-galactosamine and a glycosyltransferase isolated from porcine submaxillary glands. MBP containing 0.85 mol of N-acetyl-D-galactosamine per mole of protein was oxidized at carbon 6 by galactose oxidase and complexed with a spin-label, Tempoamine, in order to study its interactions with lipids. When the spin-labeled MBP was reacted with lipid vesicles consisting of DSPG, DPPG, and DMPG, most of the spin-label was motionally restricted in the gel phase, with a correlation time greater than 10(-8)s. The motion increased with increasing temperature and was sensitive to the lipid phase transition. Interaction with the gel phase of DPPA caused much less motional restriction of the probe. However, melting of the lipid allowed increased interaction and motional restriction of the probe, which was only partially reversed on cooling back to the gel phase. The motional restriction of the probe in these lipids is attributed to its penetration partway into the lipid bilayer in both the gel and liquid-crystalline phases. The fact that the probe bound to the protein can penetrate partway into the bilayer suggests that other hydrophobic side chains and residues of the protein can similarly penetrate into the bilayer. Additional evidence for penetration was provided by digestion of the lipid-bound protein with endoproteinase Lys-C. When nonglycosylated and glycosylated MBP in solution was treated with Lys-C, extensive digestion occurred. A single radioactive peptide which eluted at 25 min was identified as residues 92-105.(ABSTRACT TRUNCATED AT 250 WORDS)     

Monotopic enzymes and lipid bilayers: a comparative study

Monotopic proteins make up a class of membrane proteins that bind tightly to, but do not span, cell membranes. We examine and compare how two monotopic proteins, monoamine oxidase B (MAO-B) and cyclooxygenase-2 (COX-2), interact with a phospholipid bilayer using molecular dynamics simulations. Both enzymes form between three and seven hydrogen bonds with the bilayer in our simulations with basic side chains accounting for the majority of these interactions. By analyzing lipid order parameters, we show that, to a first approximation, COX-2 disrupts only the upper leaflet of the bilayer. In contrast, the top and bottom halves of the lipid tails surrounding MAO-B are more and less ordered, respectively, than in the absence of the protein. Finally, we identify which residues are important in binding individual phospholipids by counting the number and type of lipid atoms that come close to each amino acid residue. The existing models that explain how these proteins bind to bilayers were proposed following inspection of the X-ray crystallographic structures. Our results support these models and suggest that basic residues contribute significantly to the binding of these monotopic proteins to bilayers through the formation of hydrogen bonds with phospholipids.     

Structure,topology, and dynamics of myristoylated recoverin bound to phospholipid bilayers

Recoverin, a member of the EF-hand protein superfamily, serves as a calcium sensor in retinal rod cells. A myristoyl group covalently attached to the N-terminus of recoverin facilitates its binding to retinal disk membranes by a mechanism known as the Ca(2+)-myristoyl switch. Samples of (15)N-labeled Ca(2+)-bound myristoylated recoverin bind anisotropically to phospholipid membranes as judged by analysis of (15)N and (31)P chemical shifts observed in solid-state NMR spectra. On the basis of a (2)H NMR order parameter analysis performed on recoverin containing a fully deuterated myristoyl group, the N-terminal myristoyl group appears to be located within the lipid bilayer. Two-dimensional solid-state NMR ((1)H-(15)N PISEMA) spectra of uniformly and selectively (15)N-labeled recoverin show that the Ca(2+)-bound protein is positioned on the membrane surface such that its long molecular axis is oriented approximately 45 degrees with respect to the membrane normal. The N-terminal region of recoverin points toward the membrane surface, with close contacts formed by basic residues K5, K11, K22, K37, R43, and K84. This orientation of the membrane-bound protein allows an exposed hydrophobic crevice, near the membrane surface, to serve as a potential binding site for the target protein, rhodopsin kinase. Close agreement between experimental and calculated solid-state NMR spectra of recoverin suggests that membrane-bound recoverin retains the same overall three-dimensional structure that it has in solution. These results demonstrate that membrane binding by recoverin is achieved primarily by insertion of the myristoyl group inside the bilayer with apparently little rearrangement of the protein structure.     

UV immobilized phospholipid bilayers

Dinitrophenyl phosphotidylethanolamine-containing bilayers have been immobilized on carbon-shadowed support films by UV irradiation of the first monolayer transferred to the support film. The immobilized bilayer is capable of allowing bound protein (anti-DNP antibody) to organize into 2-D arrays in the presence of organic solvents such as acetonitrile and dilute concentrations of detergents such as beta-octyl glucoside. The ability of the bilayers to remain attached to supports under various conditions that include organic solvents and detergents as well as divalent ions is of potential interest in the study of protein crystallization and particularly in the study of membrane proteins.     

Investigation of the interaction of myelin basic protein with phospholipid bilayers using solid-state NMR spectroscopy

Interaction of bovine myelin basic protein and its constituent charge isomers (C1-C3) with phospholipid bilayers was studied using solid-state NMR experiments on model membranes. 31P NMR experiments on multilamellar vesicles and mechanically aligned bilayers were used to measure the degree of protein-induced disorder in the lipid headgroup region while 2H NMR data provided the disorder caused by the protein in the hydrophobic core of the bilayers. Our results suggest that MBP and its charge isomers neither fragment nor significantly disrupt DMPC, POPC, POPC:POPG, and POPE bilayers. These results demonstrate that the MBP-induced fragmentation of POPC bilayers is due to the freeze-thaw cycles used in the preparation of multilamellar vesicles and not due to intrinsic protein-lipid interactions.     

Binding of equine infectious anemia virus matrix protein to membrane bilayers involves multiple interactions

Human immunodeficiency virus (HIV) and equine infectious anemia virus (EIAV) are closely related lentiviruses that infect immune cells, but their pathogenesis differ. Localization to the cytosolic leaflet of the plasma membrane is critical for replication of both viruses. This localization is accomplished through the matrix (MA) domain of the Gag precursor protein. In HIV-1, association of MA to anionic membranes appears to be primarily driven by a linear cluster of basic residues in the MA domain and an N-myristoylation signal. Interestingly, the MA protein of EIAV does not contain either of these signals. To understand which factors could promote EIAV assembly we characterized the membrane binding properties of its MA protein using fluorescence and biochemical methods. We find that EIAV MA exists as a multimer in solution whose protein-protein interactions are destabilized by membrane binding. EIAV MA binds strongly to electrically neutral membranes as well as to negatively charged membranes. Fluorescence quenching and chemical modification techniques, as well as trypsin proteolysis, indicate a different exposure of the EIAV MA Trp residues when bound to the two types of membranes, and EIAV MA proteolysis by trypsin differs when bound to the two types of membranes. Based on these data and the known structures of closely related matrix proteins, we constructed a structural model. This model predicts that EIAV MA binds to negatively charged membranes, but EIAV MA has an additional membrane binding region rich in residues that partition favorably into the membrane headgroup region. This secondary site may play a role in early events of viral infection.     

The interaction of protein kinase C and other specific cytoplasmic proteins with phospholipid bilayers

The role of lipid composition in the interaction of purified protein kinase C with large unilamellar vesicles was determined by the extent of photolabelling of the enzyme with 5-[125I]iodonaphthalene-I-azide. The protein kinase C was only slightly labelled when exposed to phosphatidylcholine (PC) liposomes. The addition of phorbol 12-myristate 13-acetate (PMA) or of diacylglycerol to the PC liposomes enhanced significantly the labelling of the protein kinase C at low calcium concentrations. A further enhancement in the photolabelling of the protein kinase C was observed in liposomes containing 2% phosphatidylserine (PS). At low calcium concentrations, the binding of the enzyme to these liposomes increased in the presence of added PMA or diacylglycerol. Raising the levels of PS beyond 2% in the liposomes did not enhance the binding of the protein kinase C. However, when the enzymatic activity of the protein kinase C was measured using basic histones as substrates, maximum phosphorylation was obtained in liposomes with a PC to PS ratio of 1. The fact that the translocation of the protein kinase C from solution to the surface of the liposomes could be monitored by its labelling with 5-iodonaphthalene 1-azide prompted us to determine whether other cytoplasmic proteins might share this property. The interaction of cytoplasmic proteins from HeLa cells with PC liposomes gave trace labelling irrespective of whether calcium was added. When the HeLa cell cytoplasmic proteins were allowed to interact with liposomes containing PS, selective 5-iodonaphthalene-1-azide photolabelling was observed in distinct proteins. Addition of calcium and of PMA or diacylglycerol modified the labelling of some but not all of these proteins. These results suggest that the methodology developed might serve to identify proteins that move to the membrane during stimulation of cells by phorbol esters or by growth factors which induce the generation of diacylglycerol. These results also suggest a role for the phospholipid composition of the plasma membrane (or any intracellular membrane) in the modulation of the activation processes of specific phospholipid-dependent proteins, in particular protein kinase C.     

Colicin E1 in planar lipid bilayers

The channel formed by the C-terminal domain of colicin E1 in planar lipid bilayers has proven to be more complex than one might have guessed for such a simple system. The protein undergoes a pH-dependent rearrangement which transforms it from a water soluble form to a much different membrane bound form. There are at least two bound states which don't form a channel. The process by which the channel opens and closes is regulated by the pH and the transmembrane voltage. The voltage is probably sensed by at least 3 (and more likely 4 or more) lysine residues which must be driven through the field to open the channel. The process appears to be hindered by particular carboxyl groups when they are in the unprotonated state. The open channel has several substates and several superstates. Very large positive voltage catalyzes a transition of the open channel to an inactivated state, and may be able to drive the channel-forming region of the protein across the membrane. Little is known about the structure of any of these states, but the open channel is large enough to allow NAD to traverse the membrane and appears to be formed by one colicin molecule. This single polypeptide mimics many of the properties found in channels of mammalian cell membranes, but it may prove more relevant as a model for the transport of proteins across membranes. The comparative ease with which the protein can be manipulated chemically and genetically, along with the complexity of its behavior, promises to keep several laboratories busy for some time.     

Interaction of eosinophil granule major basic protein with synthetic lipid bilayers: A mechanism for toxicity

Summary Eosinophil granule major basic protein (MBP) is a potent toxin for mammalian cells and helminths, but the mechaism of its toxicity is not known. Here we tested whether MBP toxicity is exerted through its effect on the lipid bilayer of its targets. Liposomes prepared from synthetic phospholipids were used as targets for MBP and their properties examined by fluorescence and circular dichroism (CD) spectroscopy. MBP caused a change in the temperature transition profiles of acidic liposomes (1-palmitoyl-2-oleoyl-sn-glycero-3-phosphatidyl serine or an equimolar mixture of 1,2-dimyristoyl-sn-glycero-3-phosphocholine and 1,2-dimyristoyl-sn-glycero-3-phosphatidic acid) and induced their aggregation as shown by fluorescence resonance energy transfer experiments. The CD spectra and fluorescence characteristics of MBP itself were altered by its interaction with acidic lipids. Blue shifts in the emission maxima of the Trp, and of the dimethylaminonaphthyl moiety in acrylodan-labeled MBP, and a reduction in the effectiveness of quenching of Trp fluorescence by acrylamide were observed in the presence of acidic lipids. None of these effects were noted with zwitterionic lipids. This MBP : lipid bilayer interaction resulted in fusion and lysis of liposomes as indicated by the fluorescent indicator calcein. The results demonstrate that MBP associates with acidic lipids and that it disrupts, aggregates, fuses, and lyses liposomes prepared from such lipids. Such interaction might account for its wide range of toxicity.Abbreviations used Acrylodan 6-acryloyl-2-dimethylam-inonaphthalene - CD circular dichroism - DMPA 1,2-dimyrist-oyl-sn-glycero-3-phosphatidic acid - DMPC 1,2-dimyristoyl-sn-glycero-3-phosphocholine - DPH 1,6-diphenyl-1,3,5-hexatriene - DTT dithiothreitol - FRET fluorescence resonance energy transfer - HEPES N-2-hydroxyethyl piperazine-N-2-ethane sulfonic acid - K _sv Stern-Volmer constant - K _q bimolecular quenching coefficient - _em emission wavelength - _ex excitation wavelength - MBP major basic protein - MOPC 1-oleoyl-2-hydroxy-sn-glycero-3-phosphocholine - NBD-PE N-(7-nitro-2,1,3-benzo-xadiazol-4-yl)-phosphatidylethanolamine - nMBP native major basic protein - PBS phosphate-buffered saline - POPC 1-palmit-oyl-2-oleoyl-sn-glycero-3-phosphocholine - POPS 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphatidyl serine - raMBP reduced and alkylated major basic protein - RHO-PE rhodamine-phosphatidylethanolamine - Tes N-tris[hydroxymethyl]-methyl-2-amino-ethane-sulfonic acid - Tris tris[hydroxymethyl]-amino-methane We would like to thank Dr. Predrag J.K. Ilich for assistance with initial data analysis, Dr. Salah S. Sedarous for the lifetime data and for helpful discussions, Dr. S. Yu. Venyaminov for helpful discussions, Mr. Kenneth D. Peters and Mr. Peter J. Callahan for assistance with some of the illustrations, and Ms. Jill Wagner for performing the radioimmunoassays. We would also like to thank Ms. Jill Kappers for excellent secretarial work. This work was supported in part by a Fellowship grant from the American Heart Association, Minnesota Affiliate, and by grants from the National Institutes of Health AI 09728 and from the Mayo Foundation. RIA-G is a Fellow of the American Heart Association.     

Interactions of Folch-Lees proteolipid apoprotein with planar lipid bilayers

Summary Water-soluble Folch-Lees proteolipid apoprotein from bovine CNS white matter induces a voltage-dependent conductance in black lipid membranes. Na⁺ is required for the induced conductance change but the established conductance has very low ionic selectivity. The induced conductance fluctuates with a minimum amplitude of 10^–11–10^–10 mho. The magnitude of the conductivity change is dependent on protein concentration and on the composition of lipid bilayers. At a fixed voltage the induced conductance of a phosphatidylcholine-cholesterol membrane is proportional to the sixth power of the protein concentration and the first power of Na⁺ concentration. The interactions between the apoprotein and the lipids are both electrostatic and hydrophobic, but the interaction leading to the conductance increase appears to be mainly hydrophobic. Both the increase in conductance and the current fluctuations remain after extensive washing of the chambers to remove the protein. Furthermore, pronase or glutaraldehyde added to either the cis or trans side of the membrane does not affect the apoprotein-established conductance. However, if the bilayer is formed in the presence of both the apoprotein and pronase or if the apoprotein is treated with pronase prior to its addition to the chamber, no conductance change is observed. The association of the apoprotein with the membrane thus appears to render the protein inaccessible to proteolytic digestion, suggesting that the apoprotein is at least partially imbedded in the membrane interior.     

Neutron diffraction studies of fluid bilayers with transmembrane proteins: structural consequences of the achondroplasia mutation

Achondroplasia, the most common form of human dwarfism, is due to a G380R mutation in the transmembrane domain of fibroblast growth factor receptor 3 (FGFR3) in >97% of the studied cases. While the molecular mechanism of pathology induction is under debate, the structural consequences of the mutation have not been studied. Here we use neutron diffraction to determine the disposition of FGFR3 transmembrane domain in fluid lipid bilayers, and investigate whether the G380R mutation affects the topology of the protein in the bilayer. Our results demonstrate that, in a model system, the G380R mutation induces a shift in the segment that is embedded in the membrane. The center of the hydrocarbon core-embedded segment in the mutant is close to the midpoint between R380 and R397, supporting previous measurements of arginine insertion energetics into the endoplasmic reticulum. The presented results further our knowledge about basic amino-acid insertion into bilayers, and may lead to new insights into the mechanism of pathogenesis in achondroplasia.     

Effects of protein perturbants on phospholipid bilayers

Series of alcohols, amides, ureas, and sulfoxides with increasingly longer hydrocarbon chains have been shown to lower progressively the thermal denaturation temperature of proteins. This effect is presumably due to a hydrophobic interaction between the solute and nonpolar domains of the protein. Theoretically, these interactions should occur between the solute and any macromolecular structure having a nonpolar region to which the solute has access. A recent review by Arakawa et al. has summarized evidence for such an interaction between organic solutes and proteins and suggested that these interactions are favored at higher temperatures. The present study investigates the effects of several classes of compounds on the stability of phospholipid vesicles. The results show that many compounds that are known to perturb protein function also destabilize phospholipid bilayers as reflected by solute-induced loss of vesicle contents.     

Insertion of bacteriorhodopsin into polymerized diacetylenic phosphatidylcholine bilayers

We have developed a method to incorporate the membrane protein bacteriorhodopsin into polymerized bilayers composed of a diacetylenic phosphatidylcholine, 1,2-bis(tricosa-10,12-diynoyl)-sn-glycero-3-phosphocholine (DC8,9PC) and a non-polymerizable phospholipid, dinonanoylphosphatidylcholine (DNPC). The extent of DC8,9PC polymerization in the bilayer was significantly improved when 2:1 mole ratio DNPC-DC8,9PC was used. Octyl glucopyranoside-solubilized bacteriorhodopsin was inserted into the polymerized DNPC-DC8,9PC bilayers by overnight incubation at 4 degrees C followed by dialysis to remove the detergent. The protein was inserted into the membranes after photo-polymerization to avoid inactivation of the protein due to the UV irradiation. The insertion of bacteriorhodopsin into the polymerized DNPC-DC8,9PC membranes was confirmed by density gradient centrifugation, UV/visible spectroscopy, and freeze fracture electron microscopy. The polymerized DNPC-DC8,9PC membranes containing bacteriorhodopsin were about 10% protein by weight. These results suggest that mixed lipid systems such as the DNPC-DC8,9PC can be used to improve both the extent of polymerization and the efficiency of membrane protein incorporation in the polymerized bilayer.     

A theoretical study of lipid-protein interactions in bilayers.

We present a theoretical study of the effect of different types of lipid-protein interactions on the thermodynamic properties of protein-containing lipid bilayers. The basis of this work is a theoretical model for pure lipid bilayer phase transitions developed earlier by Scott. Simple assumptions on the nature of the lipid conformations near a protein strongly affect the predicted properties of the model. Here we consider (a) random protein-lipid contacts, (b) enhanced contact between protein and lipid with a number of gauche bonds, and (c) enhanced contact between protein and all-trans but tilted lipid chains. Comparison of predicted results with experimental data seems to favor point c above but, by itself point c does not work well at larger protein concentrations. The results are discussed in the light of spectroscopic data, lipid-protein (plus annular lipid) miscibility, and interprotein forces.     

Dynamics of fd coat protein in lipid bilayers

The dynamics of backbone and side-chain sites of the membrane-bound form of fd coat protein are described with solid-state 2H and 15N NMR experiments. The samples were isotopically labeled coat protein in phospholipid bilayers in excess water. The protein itself is immobile and does not undergo rapid rotation within the bilayer. Like the structural form of the protein, the membrane-bound form has four mobile residues at the N-terminus. The membrane-bound form differs from the structural form in having several mobile residues at the C-terminus. Many of the side chains of residues with immobile backbone sites undergo large amplitude jump motions. The dynamics are generally similar in both the structural and membrane-bound forms of the protein.     

Effect of phosphorylation of phosphatidylinositol on myelin basic protein-mediated binding of actin filaments to lipid bilayers in vitro

Myelin basic protein (MBP) binds to negatively charged lipids on the cytosolic surface of oligodendrocytes and is believed to be responsible for adhesion of these surfaces in the multilayered myelin sheath. It can also assemble actin filaments and tether them to lipid bilayers through electrostatic interactions. Here we investigate the effect of increased negative charge of the lipid bilayer due to phosphorylation of phosphatidylinositol (PI) on MBP-mediated binding of actin to the lipid bilayer, by substituting phosphatidylinositol 4-phosphate or phosphatidylinositol 4,5-bisphosphate for PI in phosphatidylcholine/phosphatidylglycerol lipid vesicles. Phosphorylation of PI caused dissociation of the MBP/actin complex from the lipid vesicles due to repulsion of the negatively charged complex from the negatively charged membrane surface. An effect of phosphorylation could be detected even if the inositol lipid was only 2mol% of the total lipid. Calcium-calmodulin dissociated actin from the MBP-lipid vesicles and phosphorylation of PI increased the amount dissociated. These results show that changes to the lipid composition of myelin, which could occur during signaling or other physiological events, could regulate the ability of MBP to act as a scaffolding protein and bind actin filaments to the lipid bilayer.     

Redox- and pH-dependent association of plastocyanin with lipid bilayers: effect on protein conformation and thermal stability

The effect of electrostatic interactions on the conformation and thermal stability of plastocyanin (Pc) was studied by infrared spectroscopy. Association of any of the two redox states of the protein with positively charged membranes at neutral pH does not significantly change the secondary structure of Pc. However, upon membrane binding, the denaturation temperature decreases, regardless of the protein redox state. The extent of destabilization depends on the proportion of positively charged lipid headgroups in the membrane, becoming greater as the surface density of basic phospholipids increases. In contrast, at pH 4.8 the membrane binding-dependent conformational change becomes redox-sensitive. While the secondary structures and thermal stabilities of free and membrane-bound oxidized Pc are similar under acidic conditions, the conformation of the reduced form of the protein drastically rearranges upon membrane association. This rearrangement does not depend on electrostatic interactions to occur, since it is also observed in the presence of uncharged lipid bilayers. The conformational transition, only observed for reduced Pc, involves the exposure of hydrophobic regions that leads to intermolecular interactions at the membrane surface. Membrane-mediated partial unfolding of reduced Pc can be reversed by readjusting the pH to neutrality, in the absence of electrostatic interactions. This redox-dependent behavior might reflect specific structural requirements for the interaction of Pc with its redox partners.