Voltage-dependent orientation of membrane proteins

In order to study the influence of electrostatic forces on the disposition of proteins in membranes, we have examined the interaction of a receptor protein and of a membrane-active peptide with black lipid membranes. In the first study we show that the hepatic asialoglycoprotein receptor can insert spontaneously into lipid bilayers from the aqueous medium. Under the influence of a trans-positive membrane potential, the receptor, a negatively charged protein, appears to change its disposition with respect to the membrane. In the second study we consider melittin, an amphipathic peptide containing a generally hydrophobic stretch of 19 amino acids followed by a cluster of four positively charged residues at the carboxy terminus. The hydrophobic region contains two positively charged residues. In response to trans-negative electrical potential, melittin appears to assume a transbilayer position. These findings indicate that electrostatic forces can influence the disposition, and perhaps the orientation, of membrane proteins. Given the inside-negative potential of most or all cells, we would expect transmembrane proteins to have clusters of positively charged residues adjacent to the cytoplasmic ends of their hydrophobic transmembrane segments, and clusters of negatively charged residues just to the extracytoplasmic side. This expectation has been borne out by examination of the few transmembrane proteins for which there is sufficient information on both sequence and orientation. Surface and dipole potentials may similarly affect the orientation of membrane proteins.     

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

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

Interaction of mutant alkaline phosphatase precursors with membrane phospholipids in vivo and in vitro.

Positively charged amino acid residues in the N-terminal domain of the signal peptides of secreted proteins are thought to interact with negatively charged anionic phospholipids during the initiation of secretion. To test this hypothesis, substitutions of the uncharged Ala or the negatively charged Glu residue for the positively charged Lys-20 of the N-terminus of the signal peptide of Escherichia coli alkaline phosphatase were introduced using a modified method of oligonucleotide-directed mutagenesis. We found that Lys-20 is involved in the interaction of the signal peptide with anionic phospholipids in vivo and effects the efficiency of insertion of the signal peptide of isolated precursor into model phospholipid membranes in vitro. We also show that the efficiency of signal peptide insertion into the lipid bilayer depends on the fluidity of the bilayer.     

Two distinct anionic phospholipid-dependent events involved in SecA-mediated protein translocation

Protein translocation across the bacterial cytoplasmic membrane is an essential process catalyzed by the Sec translocase, which in its minimal form consists of the protein-conducting channel SecYEG, and the motor ATPase SecA. SecA binds via its positively charged N-terminus to membranes containing anionic phospholipids, leading to a lipid-bound intermediate. This interaction induces a conformational change in SecA, resulting in a high-affinity association with SecYEG, which initiates protein translocation. Here, we examined the effect of anionic lipids on the SecA-SecYEG interaction in more detail, and discovered a second, yet unknown, anionic lipid-dependent event that stimulates protein translocation. Based on molecular dynamics simulations we identified an anionic lipid-enriched region in vicinity of the lateral gate of SecY. Here, the anionic lipid headgroup accesses the lateral gate, thereby stabilizing the pre-open state of the channel. The simulations suggest flip-flop movement of phospholipid along the lateral gate. Electrostatic contribution of the anionic phospholipids at the lateral gate may directly stabilize positively charged residues of the signal sequence of an incoming preprotein. Such a mechanism allows for the correct positioning of the entrant peptide, thereby providing a long-sought explanation for the role of anionic lipids in signal sequence folding during protein translocation.     

Ligand-induced functions of the epidermal growth factor receptor require the positively charged region asymmetrically distributed across plasma membrane.

Many plasma membrane proteins, including the epidermal growth factor (EGF) receptor, possess basic regions on the cytoplasmic surface of the membrane. To examine the function of these positively charged regions, we constructed mutated EGF receptor genes lacking this region by substitution of the basic amino acid residues with 3 approximately 8 neutral Asn residues, or by their complete deletion. There was no significant difference in the affinities for EGF of the wild-type and mutant receptors which are produced in rodent fibroblasts through transfection. However, EGF-induced tyrosine phosphorylation of the receptor was strongly inhibited by removal of the 3 approximately 8 positively charged residues. On addition of EGF, cells expressing the mutant EGF receptors did not show morphological changes, whereas cells expressing the wild-type receptor did. These findings suggest that the positively charged regions of membrane proteins that are asymmetrically distributed on the cytoplasmic surface of the membrane may be required for the functions of membrane proteins in general.     

SecA interacts with secretory proteins by recognizing the positive charge at the amino terminus of the signal peptide in Escherichia coli

SecA is an acidic, peripheral membrane protein involved in the translocation of secretory proteins across the cytoplasmic membrane. The direct interaction of SecA with secretory proteins was demonstrated by means of chemical cross-linking with 1-ethyl-3-(3-dimethylaminoprophyl)carbodiimide. OmpF-Lpp, a model secretory protein, carries either an uncleavable or cleavable signal peptide, and mutant secretory proteins derived from uncleavable OmpF-Lpp were used as translocation substrates. The interaction was SecA-specific. None of the control proteins, which are as acidic as SecA, was cross-linked with uncleavable OmpF-Lpp. The interaction was signal peptide-dependent. The interaction was increasingly enhanced as the number of positively charged amino acid residues at the amino-terminal region of the signal peptide was increased, irrespective of the species of amino acid residues donating the charge. Finally, parallelism was observed between the efficiency of interaction and that of translocation among mutant secretory proteins. It is suggested that precursors of secretory proteins interact with SecA to initiate the translocation reaction.     

Signal and membrane anchor functions overlap in the type II membrane protein I gamma CAT

I gamma CAT is a hybrid protein that inserts into the membrane of the endoplasmic reticulum as a type II membrane protein. These proteins span the membrane once and expose the NH2-terminal end on the cytoplasmic side and the COOH terminus on the exoplasmic side. I gamma CAT has a single hydrophobic segment of 30 amino acid residues that functions as a signal for membrane insertion and anchoring. The signal-anchor region in I gamma CAT was analyzed by deletion mutagenesis from its COOH-terminal end (delta C mutants). The results show that the 13 amino acid residues on the amino-terminal side of the hydrophobic segment are not sufficient for membrane insertion and translocation. Mutant proteins with at least 16 of the hydrophobic residues are inserted into the membrane, glycosylated, and partially proteolytically processed by a microsomal protease (signal peptidase). The degree of processing varies between different delta C mutants. Mutant proteins retaining 20 or more of the hydrophobic amino acid residues can span the membrane like the parent I gamma CAT protein and are not proteolytically processed. Our data suggest that in the type II membrane protein I gamma CAT, the signals for membrane insertion and anchoring are overlapping and that hydrophilic amino acid residues at the COOH-terminal end of the hydrophobic segment can influence cleavage by signal peptidase. From this and previous work, we conclude that the function of the signal-anchor sequence in I gamma CAT is determined by three segments: a positively charged NH2 terminus, a hydrophobic core of at least 16 amino acid residues, and the COOH-terminal flanking hydrophilic segment.     

Leader peptidase

The Escherichia coli leader peptidase has been vital for unravelling problems in membrane assembly and protein export. The role of this essential peptidase is to remove amino-terminal leader peptides from exported proteins after they have crossed the plasma membrane. Strikingly, almost all periplasmic proteins, many outer membrane proteins, and a few inner membrane proteins are made with cleavable leader peptides that are removed by this peptidase. This enzyme of 323 amino acid residues spans the membrane twice, with its large carboxyl-terminal domain protruding into the periplasm. Recent discoveries show that its membrane orientation is controlled by positively charged residues that border (on the cytosolic side) the transmembrane segments. Cleavable pre-proteins must have small residues at -1 and a small or aliphatic residue at -3 (with respect to the cleavage site). Leader peptidase does not require a histidine or cysteine amino acid for catalysis. Interestingly, serine 90 and aspartic acid 153 are essential for catalysis and are also conserved in a mitochondrial leader peptidase, which is 30.7% homologous with the bacterial enzyme over a 101-residue stretch.     

A single negatively charged residue affects the orientation of a membrane protein in the inner membrane of Escherichia coli only when it is located adjacent to a transmembrane domain

The orientation of membrane proteins is determined by the asymmetric distribution of charged residues in the sequences flanking the transmembrane domains. For the inner membrane of Escherichia coli, numerous studies have shown that an excess of positively charged residues defines a cytoplasmic domain of a membrane protein ("positive inside" rule). The role of negatively charged residues in establishing membrane protein topology, however, is not completely understood. To investigate the influence of negatively charged residues on this process in detail, we have constructed a single spanning chimeric receptor fragment comprising the N terminus and first transmembrane domain of the heptahelical G protein-coupled vasopressin V(2) receptor and the first cytoplasmic loop of the beta(2)-adrenergic receptor. When fused to alkaline phosphatase (PhoA), the receptor fragment inserted into the inner membrane of E. coli with its N terminus facing the cytoplasm (N(in)-C(out) orientation), although both membrane-flanking domains had rather similar topogenic determinants. The orientation of the receptor fragment was changed after the introduction of single glutamate residues into the N terminus. Orientation inversion, however, was found to be dependent on the location of the glutamate substitutions, which had to lie within a narrow window up to 6 residues distant from the transmembrane domain. These results demonstrate that a single negatively charged residue can play an active role as a topogenic determinant of membrane proteins in the inner membrane of E. coli, but only if it is located adjacent to a transmembrane domain.     

Molecular dynamics study of the membrane interaction of a membranotropic dengue virus C protein-derived peptide

Dengue virus C protein, essential in the dengue virus life cycle, possesses a segment, peptide PepC, known to bind membranes composed of negatively charged phospholipids. To characterize its interaction with the membrane, we have used the molecular dynamics HMMM membrane model system. This approach is capable of achieving a stable system and sampling the peptide/lipid interactions which determine the orientation and insertion of the peptide upon membrane binding. We have been able to demonstrate spontaneous binding of PepC to the 1,2-divaleryl-sn-glycero-3-phosphate/1,2-divaleryl-sn-glycero-3-phosphocholine membrane model system, whereas no binding was observed at all for the 1,2-divaleryl-sn-glycero-3-phosphocholine one. PepC, adopting an α-helix profile, did not insert into the membrane but did bind to its surface through a charge anchor formed by its three positively charged residues. PepC, maintaining its three-dimensional structure along the whole simulation, presented a nearly parallel orientation with respect to the membrane when bound to it. The positively charged amino acid residues Arg-2, Lys-6, and Arg-16 are mainly responsible for the peptide binding to the membrane stabilizing the structure of the bound peptide. The segment of dengue virus C protein where PepC resides is a fundamental protein–membrane interface which might control protein/membrane interaction, and its positive amino acids are responsible for membrane binding defining its specific location in the bound state. These data should help in our understanding of the molecular mechanism of DENV life cycle as well as making possible the future development of potent inhibitor molecules, which target dengue virus C protein structures involved in membrane binding.     

Dependence of prePhoA-phospholipid interaction in vivo and in vitro on charge of signal peptide N-terminus and content of anionic phospholipids in membranes

Replacement of the positively charged signal peptide with neutral or negatively charged peptides due to substitution of Lys(–20) in the N-terminal region of the signal peptide leads to decreases in the rate of prePhoA membrane translocation in vivo and in the efficiency of prePhoA insertion into liposomes in vitro. The effect of anionic phospholipids on prePhoA insertion into model membranes is determined by the signal peptide N-terminus charge, while the dependence of prePhoA translocation across the cytoplasmic membrane in vivo is not, under the studied variations in the content of anionic phospholipids. This is evidence of the possibility of direct electrostatic interaction between the signal peptide N-terminus and anionic phospholipids, which in vivo, however, seems to involve some proteins of the Sec machinery.     

Introduction of basic amino acid residues after the signal peptide inhibits protein translocation across the cytoplasmic membrane of Escherichia coli. Relation to the orientation of membrane proteins

The introduction of positive charges at the amino terminus of the mature domain of secretory proteins resulted in strong inhibition of their translocation across the cytoplasmic membrane of Escherichia coli, both in vitro and in vivo. The model secretory proteins used were OmpF-Lpp chimeric proteins possessing a cleavable or uncleavable signal peptide, beta-lactamase (Bla) and Bla-Lpp chimeric proteins. It is suggested that positively charged residues preceding the hydrophobic domain of the signal peptide have a positive effect, and ones following the hydrophobic domain, a negative effect on the translocation. These findings are discussed in relation to the orientation of membrane proteins, of which positive charges are predominant on the cytoplasmic surface.     

Ezrin/Radixin/Moesin (ERM) Proteins Bind to a Positively Charged Amino Acid Cluster in the Juxta-Membrane Cytoplasmic Domain of CD44, CD43, and ICAM-2

Abstract. CD44 has been identified as a membrane-binding partner for ezrin/radixin/moesin (ERM) proteins, plasma membrane/actin filament cross-linkers. ERM proteins, however, are not necessarily colocalized with CD44 in tissues, but with CD43 and ICAM-2 in some types of cells. We found that glutathione-S-transferase fusion proteins with the cytoplasmic domain of CD43 and ICAM-2, as well as CD44, bound to moesin in vitro. The regions responsible for the in vitro binding of CD43 and CD44 to moesin were narrowed down to their juxta-membrane 20–30–amino acid sequences in the cytoplasmic domain. These sequences and the cytoplasmic domain of ICAM-2 (28 amino acids) were all characterized by the positively charged amino acid clusters. When E-cadherin chimeric molecules bearing these positively charged amino acid clusters of CD44, CD43, or ICAM-2 were expressed in mouse L fibroblasts, they were co-concentrated with ERM proteins at microvilli, whereas those lacking these clusters were diffusely distributed on the cell surface. The specific binding of ERM proteins to the juxta-membrane positively charged amino acid clusters of CD44, CD43, and ICAM-2 was confirmed by immunoprecipitation and site-directed mutagenesis. From these findings, we conclude that ERM proteins bind to integral membrane proteins bearing a positively charged amino acid cluster in their juxta-membrane cytoplasmic domain.     

Decoding signals for membrane protein assembly using alkaline phosphatase fusions.

We have used genetic methods to investigate the role of the different domains of a bacterial cytoplasmic membrane protein, MalF, in determining its topology. This was done by analyzing the effects of MalF topology of deleting various domains of the protein using MalF-alkaline phosphatase fusion proteins. Our results show that the cytoplasmic domains of the protein are the pre-eminent topogenic signals. These domains contain information that determines their cytoplasmic location and, thus, the orientation of the membrane spanning segments surrounding them. Periplasmic domains do not appear to have equivalent information specifying their location and membrane spanning segments do not contain information defining their orientation in the membrane. The strength of cytoplasmic domains as topogenic signals varies, correlated with the density of positively charged amino acids within them.     

Primary structure of sarcotoxin I, an antibacterial protein induced in the hemolymph of Sarcophaga peregrina (flesh fly) larvae

The primary structure of sarcotoxin I, a potent bactericidal protein induced in the hemolymph of larvae of Sarcophaga peregrina (flesh fly), was investigated. Sarcotoxin I was a mixture of three proteins (sarcotoxins IA, IB, and IC) with almost identical primary structures. These proteins were found to consist of 39 amino acid residues and to differ in only 2-3 amino acid residues. The amino-terminal half of the molecules was rich in charged amino acids and was hydrophilic, whereas the carboxyl-terminal half was hydrophobic. It is suggested that the carboxyl-terminal half of sarcotoxin I penetrates into the bacterial membrane and that its amino-terminal half rich in basic amino acid residues interacts with acidic phospholipids in the bacterial membrane, resulting in perturbation of the membrane and loss of viability of the bacteria.     

Topology of eukaryotic type II membrane proteins: importance of N-terminal positively charged residues flanking the hydrophobic domain

We have tested the role of different charged residues flanking the sides of the signal/anchor (S/A) domain of a eukaryotic type II (N(cyt)C(exo)) integral membrane protein in determining its topology. The removal of positively charged residues on the N-terminal side of the S/A yields proteins with an inverted topology, while the addition of positively charged residues to only the C-terminal side has very little effect on orientation. Expression of chimeric proteins composed of domains from a type II protein (HN) and the oppositely oriented membrane protein M2 indicates that the HN N-terminal domain is sufficient to confer a type II topology and that the M2 N-terminal ectodomain can direct a type II topology when modified by adding positively charged residues. These data suggest that eukaryotic membrane protein topology is governed by the presence or absence of an N-terminal signal for retention in the cytoplasm that is composed in part of positive charges.     

Different positively charged amino acids have similar effects on the topology of a polytopic transmembrane protein in Escherichia coli.

Integral membrane proteins from a wide variety of sources conform to a "positive-inside rule," with many more positively charged amino acids in their cytoplasmic as compared to extracytoplasmic domains. A growing body of experimental work also points to positively charged residues in regions flanking the apolar transmembrane segments as being the main topological determinants. In this paper, we report a systematic comparison of the effects of positively (Arg, Lys, His) as well as negatively (Asp, Glu) charged residues on the membrane topology of a model Escherichia coli inner membrane protein. Our results show that positive charge is indeed the major factor determining the transmembrane topology, with Arg and Lys being of nearly equal efficiency. His, although normally a very weak topological determinant, can be potentiated by a lowering of the cytoplasmic pH. Asp and Glu affect the topology to similar extents and only when present in very high numbers.     

Lipids and topological rules governing membrane protein assembly

Membrane protein folding and topogenesis are tuned to a given lipid profile since lipids and proteins have co-evolved to follow a set of interdependent rules governing final protein topological organization. Transmembrane domain (TMD) topology is determined via a dynamic process in which topogenic signals in the nascent protein are recognized and interpreted initially by the translocon followed by a given lipid profile in accordance with the Positive Inside Rule. The net zero charged phospholipid phosphatidylethanolamine and other neutral lipids dampen the translocation potential of negatively charged residues in favor of the cytoplasmic retention potential of positively charged residues (Charge Balance Rule). This explains why positively charged residues are more potent topological signals than negatively charged residues. Dynamic changes in orientation of TMDs during or after membrane insertion are attributed to non-sequential cooperative and collective lipid–protein charge interactions as well as long-term interactions within a protein. The proportion of dual topological conformers of a membrane protein varies in a dose responsive manner with changes in the membrane lipid composition not only in vivo but also in vitro and therefore is determined by the membrane lipid composition. Switching between two opposite TMD topologies can occur in either direction in vivo and also in liposomes (designated as fliposomes) independent of any other cellular factors. Such lipid-dependent post-insertional reversibility of TMD orientation indicates a thermodynamically driven process that can occur at any time and in any cell membrane driven by changes in the lipid composition. This dynamic view of protein topological organization influenced by the lipid environment reveals previously unrecognized possibilities for cellular regulation and understanding of disease states resulting from mis-folded proteins. This article is part of a Special Issue entitled: Protein trafficking and secretion in bacteria. Guest Editors: Anastassios Economou and Ross Dalbey.     

Efficient translocation of positively charged residues of M13 procoat protein across the membrane excludes electrophoresis as the primary force for membrane insertion.

The coat protein of bacteriophage M13 is inserted into the Escherichia coli plasma membrane as a precursor protein, termed procoat, with a typical leader peptide of 23 amino acid residues. Its membrane insertion requires the electrochemical potential but not the cellular components SecA and SecY. Since the electrochemical gradients result in the periplasmic side of the membrane being positively charged, the membrane potential could contribute to the transfer of the negatively charged central region of procoat across the membrane. Here we demonstrate that the central domain following the leader peptide can be translocated across the membrane even when the net charge of the region is changed from -3 to +3. This rules out an electrophoresis-like insertion mechanism for procoat. We also show that the sec independence of procoat insertion is linked to the presence of the second apolar domain. The deletion of most of the second apolar domain from a procoat fusion protein results in sec dependent membrane insertion of the hybrid protein. Moreover, like other proteins that require the sec genes, translocation of this sec dependent procoat protein is inhibited when positively charged residues are introduced after the leader peptide. Loop models involving one or two hydrophobic regions are presented that account for the differences in tolerance of positively charged residues.