Solution structure of the dimeric SAM domain of MAPKKK Ste11 and its interactions with the adaptor protein Ste50 from the budding yeast: implications for Ste11 activation and signal transmission through the Ste50-Ste11 complex

Ste11, a homologue of mammalian MAPKKKs, together with its binding partner Ste50 works in a number of MAPK signaling pathways of Saccharomyces cerevisiae. Ste11/Ste50 binding is mediated by their sterile alpha motifs or SAM domains, of which homologues are also found in many other intracellular signaling and regulatory proteins. Here, we present the solution structure of the SAM domain or residues D37-R104 of Ste11 and its interactions with the cognate SAM domain-containing region of Ste50, residues M27-Q131. NMR pulse-field-gradient (PFG) and rotational correlation time measurements (tauc) establish that the Ste11 SAM domain exists predominantly as a symmetric dimer in solution. The solution structure of the dimeric Ste11 SAM domain consists of five well-defined helices per monomer packed into a compact globular structure. The dimeric structure of the SAM domain is maintained by a novel dimer interface involving interactions between a number of hydrophobic residues situated on helix 4 and at the beginning of the C-terminal long helix (helix 5). The dimer structure may also be stabilized by potential salt bridge interactions across the interface. NMR H/2H exchange experiments showed that binding of the Ste50 SAM to the Ste11 SAM very likely involves the positively charged extreme C-terminal region as well as exposed hydrophobic patches of the dimeric Ste11 SAM domain. The dimeric structure of the Ste11 SAM and its interactions with the Ste50 SAM may have important roles in the regulation and activation of the Ste11 kinase and signal transmission and amplifications through the Ste50-Ste11 complex.     

Membrane association and selectivity of the antimicrobial peptide NK‐2: a molecular dynamics simulation study

In an effort to better understand the initial mechanism of selectivity and membrane association of the synthetic antimicrobial peptide NK‐2, we have applied molecular dynamics simulation techniques to elucidate the interaction of the peptide with the membrane interfaces. A homogeneous dipalmitoylphosphatidylglycerol (DPPG) and a homogeneous dipalmitoylphosphatidylethanolamine (DPPE) bilayers were taken as model systems for the cytoplasmic bacterial and human erythrocyte membranes, respectively. The results of our simulations on DPPG and DPPE model membranes in the gel phase show that the binding of the peptide, which is considerably stronger for the negatively charged DPPG lipid bilayer than for the zwitterionic DPPE, is mostly governed by electrostatic interactions between negatively charged residues in the membrane and positively charged residues in the peptide. In addition, a characteristic distribution of positively charged residues along the helix facilitates a peptide orientation parallel to the membrane interface. Once the peptides reside close to the membrane surface of DPPG with the more hydrophobic side chains embedded into the membrane interface, the peptide initially disturbs the respective bilayer integrity by a decrease of the order parameter of lipid acyl chain close to the head group region, and by a slightly decrease in bilayer thickness. We found that the peptide retains a high content of helical structure on the zwitterionic membrane‐water interface, while the loss of α‐helicity is observed within a peptide adsorbed onto negatively charged lipid membranes. Copyright © 2009 European Peptide Society and John Wiley & Sons, Ltd.     

Alpha-synuclein association with phosphatidylglycerol probed by lipid spin labels

Alpha-synuclein is a small presynaptic protein, which is linked to the development of Parkinson's disease. Alpha-synuclein partitions between cytosolic and vesicle-bound states, where membrane binding is accompanied by the formation of an amphipathic helix in the N-terminal section of the otherwise unstructured protein. The impact on alpha-synuclein of binding to vesicle-like liposomes has been studied extensively, but far less is known about the impact of alpha-synuclein on the membrane. The interactions of alpha-synuclein with phosphatidylglycerol membranes are studied here by using spin-labeled lipid species and electron spin resonance (ESR) spectroscopy to allow a detailed analysis of the effect on the membrane lipids. Membrane association of alpha-synuclein perturbs the ESR spectra of spin-labeled lipids in bilayers of phosphatidylglycerol but not of phosphatidylcholine. The interaction is inhibited at high ionic strength. The segmental motion is hindered at all positions of spin labeling in the phosphatidylglycerol sn-2 chain, while still preserving the chain flexibility gradient characteristic of fluid phospholipid membranes. Direct motional restriction of the lipid chains, resulting from penetration of the protein into the hydrophobic interior of the membrane, is not observed. Saturation occurs at a protein/lipid ratio corresponding to approximately 36 lipids/protein added. Alpha-synuclein exhibits a selectivity of interaction with different phospholipid spin labels when bound to phosphatidylglycerol membranes in the following order: stearic acid > cardiolipin > phosphatidylcholine > phosphatidylglycerol approximately phosphatidylethanolamine > phosphatidic acid approximately phosphatidylserine > N-acyl phosphatidylethanolamine > diglyceride. Accordingly, membrane-bound alpha-synuclein associates at the interfacial region of the bilayer where it may favor a local concentration of certain phospholipids.     

The importance of being kinked: role of Pro residues in the selectivity of the helical antimicrobial peptide P5

Antimicrobial peptides (AMPs) are promising compounds for developing new antibiotic drugs against drug‐resistant bacteria. Many of them kill bacteria by perturbing their membranes but exhibit no significant toxicity towards eukaryotic cells. The identification of the features responsible for this selectivity is essential for their pharmacological development. AMPs exhibit few conserved features, but a statistical analysis of an AMP sequence database indicated that many α‐helical AMPs surprisingly have a helix‐breaking Pro residue in the middle of their sequence. To discriminate among the different possible hypotheses for the functional role of this feature, we designed an analogue of the antimicrobial peptide P5, in which the central Pro was deleted (analogue P5Del). Pro removal resulted in a dramatic increase of toxicity. This was explained by the observation that P5Del binds both charged and neutral membranes, whereas P5 has no appreciable affinity towards neutral bilayers. CD and simulative data provided a rationalization of this behavior. In solution P5, due to the presence of Pro, attains compact conformations, in which its apolar residues are partially shielded from the solvent, whereas P5Del is more helical. These structural differences reduce the hydrophobic driving force for association of P5 to neutral membranes, whereas its binding to anionic bilayers can still take place because of electrostatic attraction. After membrane binding, the Pro residue does not preclude the attainment of a membrane‐active amphiphilic helical conformation. These findings shed light on the role of Pro residues in the selectivity of AMPs and provide hints for the design of new, highly selective compounds. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

Cell selectivity and mechanism of action of antimicrobial model peptides containing peptoid residues

To develop a useful method for designing cell-selective antimicrobial peptides and to investigate the effect of incorporating peptoid residues into an alpha-helical model peptide on structure, function, and mode of action, we synthesized a series of model peptides incorporating Nala (Ala-peptoid) into different positions of an amphipathic alpha-helical model peptide (KLW). Incorporation of one or two Nala residues into the hydrophobic helix face of KLW was more effective at disrupting the alpha-helical structure and bacterial cell selectivity than incorporation into the hydrophilic helix face or hydrophobic/hydrophilic interface. Tryptophan fluorescence studies of peptide interaction with model membranes indicated that the cell selectivity of KLW-L9-a and KLW-L9,13-a is closely correlated with their selective interactions with negatively charged phospholipids. KLW-L9,13-a, which has two Nala residues in its hydrophobic helix face, showed a random structure in membrane-mimicking conditions. KLW-L9,13-a exhibited the highest selectivity toward bacterial cells, showing no hemolytic activity and no or less cytotoxicity compared with other peptides against four mammalian cell lines. Unlike other model peptides, KLW-L9,13-a caused no or little membrane depolarization in Staphylococcus aureus or lipid flip-flop in negatively charged vesicles. In addition, KLW-L9,13-a caused very little fluorescent dye leakage from negatively charged vesicles. Furthermore, confocal laser-scanning microscopy and DNA-binding assays showed that KLW-L9,13-a probably exerts its antibacterial action by penetrating the bacterial membrane and binding to cytoplasmic compounds (e.g., DNA), resulting in cell death. Collectively, our results demonstrate that the incorporation of two Nala residues into the central position of the hydrophobic helix face of noncell-selective alpha-helical peptides is a promising strategy for the rational design of intracellular, cell-selective antimicrobial peptides.     

Membrane Binding, Structure, and Localization of Cecropin-Mellitin Hybrid Peptides: A Site-Directed Spin-Labeling Study

The interaction of antimicrobial peptides with membranes is a key factor in determining their biological activity. In this study we have synthesized a series of minimized cecropin-mellitin hybrid peptides each containing a single cysteine residue, modified the cysteine with the sulfhydryl-specific methanethiosulfonate spin-label, and used electron paramagnetic resonance spectroscopy to measure membrane-binding affinities and determine the orientation and localization of peptides bound to membranes that mimic the bacterial cytoplasmic membrane. All of the peptides were unstructured in aqueous solution but underwent a significant conformational change upon membrane binding that diminished the rotational mobility of the attached spin-label. Apparent partition coefficients were similar for five of the six constructs examined, indicating that location of the spin-label had little effect on peptide binding as long as the attachment site was in the relatively hydrophobic C-terminal domain. Depth measurements based on accessibility of the spin-labeled sites to oxygen and nickel ethylenediaminediacetate indicated that at high lipid/peptide ratios these peptides form a single α-helix, with the helical axis aligned parallel to the bilayer surface and immersed ~5 Å below the membrane-aqueous interface. Such a localization would provide exposure of charged/polar residues on the hydrophilic face of the amphipathic helix to the aqueous phase, and allow the nonpolar residues along the opposite face of the helix to remain immersed in the hydrophobic phase of the bilayer. These results are discussed with respect to the mechanism of membrane disruption by antimicrobial peptides.     

Membrane association, electrostatic sequestration, and cytotoxicity of Gly-Leu-rich peptide orthologs with differing functions

The skins of closely related frog species produce Gly-Leu-rich peptide orthologs that have very similar sequences, hydrophobicities, and amphipathicities but differ markedly in their net charge and membrane-damaging properties. Cationic Gly-Leu-rich peptides are hemolytic and very potent against microorganisms. Peptides with no net charge have only hemolytic activity. We have used ancestral protein reconstruction and peptide analogue design to examine the roles of electrostatic and hydrophobic interactions in the biological activity and mode of action of functionally divergent Gly-Leu-rich peptides. The structure and interaction of the peptides with anionic and zwitterionic model membranes were investigated by circular dichroism with 2-dimyristoyl-sn-glycero-3-phosphatidylcholine or 1,2-dimyristoyl-sn-glycero-3-phosphatidylglycerol vesicles and surface plasmon resonance with immobilized bilayers. The results, combined with antimicrobial assays, the kinetics of bacterial killing, and membrane permeabilization assays, reveal that Gly, Val, Thr, and Ile can all be accommodated in an amphipathic alpha helix when the helix is in a membrane environment. Binding to anionic and zwitterionic membranes fitted to a 2-stage interaction model (adsorption to the membrane followed by membrane insertion). The first step is governed by hydrophobic interactions between the nonpolar surface of the peptide helix and the membranes. The strong binding of Gly-Leu-rich cationic peptides to anionic membranes is due to the second binding step and involves short-range Coulombic interactions that prolong the residence time of the membrane-inserted peptide. The data demonstrate that evolution has positively selected charge-altering nucleotide substitutions to generate an orthologous cationic variant of neutral hemolytic peptides that bind to and permeate bacterial cell membranes.     

Association of alpha-synuclein and mutants with lipid membranes: spin-label ESR and polarized IR

Alpha-synuclein is a presynaptic protein, the A53T and A30P mutants of which are linked independently to early-onset familial Parkinson's disease. The association of wild-type alpha-synuclein with lipid membranes was characterized previously by electron spin resonance (ESR) spectroscopy with spin-labeled lipids [Ramakrishnan, M., Jensen, P. H., and Marsh, D. (2003) Biochemistry 42, 12919-12926]. Here, we study the interaction of the A53T and A30P alpha-synuclein mutants and a truncated form that lacks the acidic C-terminal domain with phosphatidylglycerol bilayer membranes, using anionic phospholipid spin labels. The strength of the interaction with phosphatidylglycerol membranes lies in the order: wild type approximately truncated > A53T > A30P > fibrils approximately 0, and only the truncated form interacts with phosphatidylcholine membranes. The selectivity of the interaction of the mutant alpha-synucleins with different spin-labeled lipid species is reduced considerably, relative to the wild-type protein, whereas that of the truncated protein is increased. Polarized infrared (IR) spectroscopy is used to study the interactions of the wild-type and truncated proteins with aligned lipid membranes and additionally to characterize the fibrillar form. Wild-type alpha-synuclein is natively unfolded in solution and acquires secondary structure upon binding to membranes containing phosphatidylglycerol. Up to 30-40% of the amide I band intensity of the membrane-bound wild-type and truncated proteins is attributable to beta-sheet structure, at the surface densities used for IR spectroscopy. The remainder is alpha-helix and residual unordered structure. Fibrillar alpha-synuclein contains 62% antiparallel beta-sheet and is oriented on the substrate surface but does not interact with deposited lipid membranes. The beta-sheet secondary-structural elements of the wild-type and truncated proteins are partially oriented on the surface of membranes with which they interact.     

Mutational Analysis of the Class IIa Bacteriocin Curvacin A and Its Orientation in Target Cell Membranes

To analyze the orientation in target cell membranes of the pediocin-like bacteriocin (antimicrobial peptide) curvacin A, 55 variants were generated by site-directed mutagenesis and their potencies against four different target cells determined. The result suggest that the somewhat hydrophilic short central helix (residues 19 to 24), along with the N-terminal β-sheet-like structure (residues 1 to 16), inserts in the interface region of the target cell membrane, with Ala22 close to the hydrophobic core of the membrane. The following hinge region, with Gly28 as an important residue, may then form a turn wherein Gly28 becomes positioned near the border between the interface and the hydrophobic regions, thus permitting the longer and more-hydrophobic C-terminal helix (residues 29 to 41) to insert into the hydrophobic core of the membrane. This helix contains three glycine residues (G33, G37, and G40) that form a putative helix-helix-interacting GxxxGxxG motif. The replacement of any of these glycines with a larger residue was very detrimental, suggesting their possible involvement in helix-helix interactions with a membrane-embedded receptor protein.     

Characterizing the binding of annexin V to a lipid bilayer using molecular dynamics simulations

Annexins play critical roles in membrane organization, membrane trafficking and vesicle transport. The family members share the ability to bind to membranes with high affinities, but the interactions between annexins and membranes remain unclear. Here, using long‐time molecular dynamics simulations, we provide detailed information for the binding of an annexin V trimer to a POPC/POPS lipid bilayer. Calcium ions function as bridges between several negatively charged residues of annexin V and the oxygen atoms of lipids. The preferred calcium‐bridges are those formed via the carboxyl oxygen atoms of POPS lipids. H‐bonds and hydrophobic interactions formed by several critical residues have also been observed in the annexin‐membrane interface. The annexin‐membrane binding causes small changes of annexin trimer structures, while has significant effects on lipid bilayer structures. The lipid bilayer shows a bent shape and forms a concave region in the annexin‐membrane interaction interface, which provides an atomic‐level evidence to support the view that annexins could disturb the stability of lipids and bend membranes. This study provides insights into the commonly occurring PS‐dependent and calcium‐dependent binding of proteins to membranes. Proteins 2014; 82:312–322. © 2013 Wiley Periodicals, Inc.     

Implicit solvent simulations of peptide interactions with anionic lipid membranes

A recently developed implicit membrane model (IMM1) is supplemented with a Gouy-Chapman term describing counterion-screened electrostatic interactions of a solute with negatively charged membrane lipids. The new model is tested on peptides that bind to anionic membranes. Pentalysine binds just outside the plane of negative charge, whereas Lys-Phe peptides insert their aromatic rings into the hydrophobic core. Melittin and magainin 2 bind more strongly to anionic than to neutral membranes and in both cases insert their hydrophobic residues into the hydrocarbon core. The third domain of Antennapedia homeodomain (penetratin) binds as an alpha-helix in the headgroup region. Cardiotoxin II binds strongly to anionic membranes but marginally to neutral ones. In all cases, the location and configuration of the peptides are consistent with experimental data, and the effective energy changes upon binding compare favorably with experimental binding free energies. The model opens the way to exploring the effect of membrane charge on the location, conformation, and dynamics of a large variety of biologically active peptides on membranes.     

Ca2+-independent Binding of Anionic Phospholipids by Phospholipase C δ1 EF-hand Domain

Recombinant EF-hand domain of phospholipase C δ1 has a moderate affinity for anionic phospholipids in the absence of Ca²⁺ that is driven by interactions of cationic and hydrophobic residues in the first EF-hand sequence. This region of PLC δ1 is missing in the crystal structure. The relative orientation of recombinant EF with respect to the bilayer, established with NMR methods, shows that the N-terminal helix of EF-1 is close to the membrane interface. Specific mutations of EF-1 residues in full-length PLC δ1 reduce enzyme activity but not because of disturbing partitioning of the protein onto vesicles. The reduction in enzymatic activity coupled with vesicle binding studies are consistent with a role for this domain in aiding substrate binding in the active site once the protein is transiently anchored at its target membrane.     

Structural determinants of the specificity of a membrane binding domain of the scaffold protein Ste5 of budding yeast: Implications in signaling by the scaffold protein in MAPK pathway

In the mitogen activated protein kinase (MAPK) cascades of budding yeast, the scaffold protein Ste5 is recruited to the plasma membrane to transmit pheromone induced signal. A region or domain of Ste5 i.e. residues P44-R67, referred here as Ste5PM24, has been known to be involved in direct interactions with the membrane. In order to gain structural insights into membrane interactions of Ste5, here, we have investigated structures and interactions of two synthetic peptide fragments of Ste5, Ste5PM24, and a hyperactive mutant, Ste5PM24LM, by NMR, ITC, and fluorescence spectroscopy, with lipid membranes. We observed that Ste5PM24 predominantly interacted only with the anionic lipid vesicles. By contrast, Ste5PM24LM exhibited binding with negatively charged as well as zwitterionic or mixed lipid vesicles. Binding of Ste5 peptides with the negatively charged lipid vesicles were primarily driven by hydrophobic interactions. NMR studies revealed that Ste5PM24 assumes dynamic or transient conformations in zwitterionic dodecylphosphocholine (DPC) micelles. By contrast, NMR structure, obtained in anionic sodium dodecyl sulphate (SDS), demonstrated amphipathic helical conformations for the central segment of Ste5PM24. The hydrophobic surface of the helix was found to be buried inside the micelles. Taken together, these results provide important insights toward the structure and specificity determinants of the scaffold protein interactions with the plasma membrane.     

Helical structure and orientation of melittin in dispersed phospholipid membranes from amide exchange analysis in situ.

A trapping method combined with high-resolution nuclear magnetic resonance spectroscopy is described for the measurement of hydrogen-deuterium exchange rates for individual amides of polypeptides bound to fully hydrated, dispersed phospholipid bilayers. Exchange rates were measured for 22 of the 24 amide hydrogens of bee venom melittin bound to bilayers composed of egg phosphatidylcholine/phosphatidylserine (88:12, mol/mol) dispersed in 20 mM sodium acetate, pH 4.0. Amides of residues 5-11 and 16-22 had exchange rates suppressed by between 30- and 1000-fold, and the rate suppression exhibited a helical periodicity with amides on the hydrophobic helix face up to 20-fold more stable than those on the hydrophilic face of the helix. These results demonstrate that under the conditions studied melittin adopts a helical conformation with stable helical hydrogen bonds extending to residue 22 and that the helix is oriented with the hydrophobic face directed toward the membrane interior.     

Micelle bound structure and DNA interaction of brevinin‐2‐related peptide,an antimicrobial peptide derived from frog skin

Brevinin‐2‐related peptide (BR‐II), a novel antimicrobial peptide isolated from the skin of frog, Rana septentrionalis, shows a broad spectrum of antimicrobial activity with low haemolytic activity. It has also been shown to have antiviral activity, specifically to protect cells from infection by HIV‐1. To understand the active conformation of the BR‐II peptide in membranes, we have investigated the interaction of BR‐II with the prokaryotic and eukaryotic membrane‐mimetic micelles such as sodium dodecylsulfate (SDS) and dodecylphosphocholine (DPC), respectively. The interactions were studied using fluorescence and circular dichroism (CD) spectroscopy. Fluorescence experiments revealed that the N‐terminus tryptophan residue of BR‐II interacts with the hydrophobic core of the membrane mimicking micelles. The CD results suggest that interactions with membrane‐mimetic micelles induce an α‐helix conformation in BR‐II. We have also determined the solution structures of BR‐II in DPC and SDS micelles using NMR spectroscopy. The structural comparison of BR‐II in the presence of SDS and DPC micelles showed significant conformational changes in the residues connecting the N‐terminus and C‐terminus helices. The ability of BR‐II to bind DNA was elucidated by agarose gel retardation and fluorescence experiments. The structural differences of BR‐II in zwitterionic versus anionic membrane mimics and the DNA binding ability of BR‐II collectively contribute to the general understanding of the pharmacological specificity of this peptide towards prokaryotic and eukaryotic membranes and provide insights into its overall antimicrobial mechanism. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.     

RGS4 binds to membranes through an amphipathic alpha -helix

RGS4, a mammalian GTPase-activating protein for G protein alpha subunits, requires its N-terminal 33 amino acids for plasma membrane localization and biological activity (Srinivasa, S. P., Bernstein, L. S., Blumer, K. J., and Linder, M. E. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 5584-5589). In this study, we tested the hypothesis that the N-terminal domain mediates membrane binding by forming an amphipathic alpha-helix. RGS4 bound to liposomes containing anionic phospholipids in a manner dependent on the first 33 amino acids. Circular dichroism spectroscopy of a peptide corresponding to amino acids 1-31 of RGS4 revealed that the peptide adopted an alpha-helical conformation in the presence of anionic phospholipids. Point mutations that either neutralized positive charges on the hydrophilic face or substituted polar residues on the hydrophobic face of the model helix disrupted plasma membrane targeting and biological activity of RGS4 expressed in yeast. Recombinant mutant proteins were active as GTPase-activating proteins in solution but exhibited diminished binding to anionic liposomes. Peptides corresponding to mutants with the most pronounced phenotypes were also defective in forming an alpha-helix as measured by circular dichroism spectroscopy. These results support a model for direct interaction of RGS4 with membranes through hydrophobic and electrostatic interactions of an N-terminal alpha-helix.     

A structural and functional role for 11-mer repeats in alpha-synuclein and other exchangeable lipid binding proteins

We have used NMR spectroscopy and limited proteolysis to characterize the structural properties of the Parkinson's disease-related protein alpha-synuclein in lipid and detergent micelle environments. We show that the lipid or micelle surface-bound portion of the molecule adopts a continuously helical structure with a single break. Modeling alphaS as an ideal alpha-helix reveals a hydrophobic surface that winds around the helix axis in a right-handed fashion. This feature is typical of 11-mer repeat containing sequences that adopt right-handed coiled coil conformations. In order to bind a flat or convex lipid surface, however, an unbroken helical alphaS structure would need to adopt an unusual, slightly unwound, alpha11/3 helix conformation (three complete turns per 11 residues). The break we observe in the alphaS helix may allow the protein to avoid this unusual conformation by adopting two shorter stretches of typical alpha-helical structure. However, a quantitative analysis suggests the possibility that the alpha11/3 conformation may in fact exist in lipid-bound alphaS. We discuss how structural features of helical 11-mer repeats could play a role in the reversible lipid binding function of alpha-synuclein and generalize this argument to include the 11-mer repeat-containing apolipoproteins, which also require the ability to release readily from lipid surfaces. A search of protein sequence databases confirms that synuclein-like 11-mer repeats are present in other proteins that bind lipids reversibly and predicts such a role for a number of hypothetical proteins of unknown function.     

Revisiting Hydrophobic Mismatch with Free Energy Simulation Studies of Transmembrane Helix Tilt and Rotation

Protein-lipid interaction and bilayer regulation of membrane protein functions are largely controlled by the hydrophobic match between the transmembrane (TM) domain of membrane proteins and the surrounding lipid bilayer. To systematically characterize responses of a TM helix and lipid adaptations to a hydrophobic mismatch, we have performed a total of 5.8-μs umbrella sampling simulations and calculated the potentials of mean force (PMFs) as a function of TM helix tilt angle under various mismatch conditions. Single-pass TM peptides called WALPn (n = 16, 19, 23, and 27) were used in two lipid bilayers with different hydrophobic thicknesses to consider hydrophobic mismatch caused by either the TM length or the bilayer thickness. In addition, different flanking residues, such as alanine, lysine, and arginine, instead of tryptophan in WALP23 were used to examine their influence. The PMFs, their decomposition, and trajectory analysis demonstrate that 1), tilting of a single-pass TM helix is the major response to a hydrophobic mismatch; 2), TM helix tilting up to ∼10° is inherent due to the intrinsic entropic contribution arising from helix precession around the membrane normal even under a negative mismatch; 3), the favorable helix-lipid interaction provides additional driving forces for TM helix tilting under a positive mismatch; 4), the minimum-PMF tilt angle is generally located where there is the hydrophobic match and little lipid perturbation; 5), TM helix rotation is dependent on the specific helix-lipid interaction; and 6), anchoring residues at the hydrophilic/hydrophobic interface can be an important determinant of TM helix orientation.     

Competition between Anion Binding and Dimerization Modulates Staphylococcus aureus Phosphatidylinositol-specific Phospholipase C Enzymatic Activity

Staphylococcus aureus phosphatidylinositol-specific phospholipase C (PI-PLC) is a secreted virulence factor for this pathogenic bacterium. A novel crystal structure shows that this PI-PLC can form a dimer via helix B, a structural feature present in all secreted, bacterial PI-PLCs that is important for membrane binding. Despite the small size of this interface, it is critical for optimal enzyme activity. Kinetic evidence, increased enzyme specific activity with increasing enzyme concentration, supports a mechanism where the PI-PLC dimerization is enhanced in membranes containing phosphatidylcholine (PC). Mutagenesis of key residues confirm that the zwitterionic phospholipid acts not by specific binding to the protein, but rather by reducing anionic lipid interactions with a cationic pocket on the surface of the S. aureus enzyme that stabilizes monomeric protein. Despite its structural and sequence similarity to PI-PLCs from other Gram-positive pathogenic bacteria, S. aureus PI-PLC appears to have a unique mechanism where enzyme activity is modulated by competition between binding of soluble anions or anionic lipids to the cationic sensor and transient dimerization on the membrane.     

Interactions of the fatty acid-binding protein ReP1-NCXSQ with lipid membranes. Influence of the membrane electric field on binding and orientation

The regulatory protein of the squid nerve sodium calcium exchanger (ReP1-NCXSQ) is a 15 kDa soluble, intracellular protein that regulates the activity of the Na⁺/Ca ²⁺ exchanger in the squid axon. It is a member of the cellular retinoic acid-binding proteins family and the fatty acid-binding proteins superfamily. It is composed of ten beta strands defining an inner cavity and a domain of two short alpha helix segments. In this work, we studied the binding and orientation of ReP1-NCXSQ in anionic and zwitterionic lipid membranes using molecular dynamics (MD) simulations. Binding to lipid membranes was also measured by filtration binding assay. ReP1-NCXSQ acquired an orientation in the anionic membranes with the positive end of the macrodipole pointing to the lipid membrane. Potential of mean force calculations, in agreement with experimental measurements, showed that the binding to the anionic interfaces in low ionic strength was stronger than the binding to anionic interfaces in high ionic strength or to zwitterionic membranes. The results of MD showed that the electrostatic binding can be mediated not only by defined patches or domains of basic residues but also by a global asymmetric distribution of charges. A combination of dipole–electric field interaction and local interactions determined the orientation of ReP1-NCXSQ in the interface.