Protein-protein interactions within the membrane are involved in many vital cellular processes. Consequently, deficient oligomerization is associated with known diseases. The interactions can be partially or fully mediated by transmembrane domains (TMD). However, in contrast to soluble regions, our knowledge of the factors that control oligomerization and recognition between the membrane-embedded domains is very limited. Due to the unique chemical and physical properties of the membrane environment, rules that apply to interactions between soluble segments are not necessarily valid within the membrane. This review summarizes our knowledge on the sequences mediating TMD-TMD interactions which include conserved motifs such as the GxxxG, QxxS, glycine and leucine zippers, and others. The review discusses the specific role of polar, charged and aromatic amino acids in the interface of the interacting TMD helices. Strategies to determine the strength, dynamics and specificities of these interactions by experimental (ToxR, TOXCAT, GALLEX and FRET) or various computational approaches (molecular dynamic simulation and bioinformatics) are summarized. Importantly, the contribution of the membrane environment to the TMD-TMD interaction is also presented. Studies utilizing exogenously added TMD peptides have been shown to influence in vivo the dimerization of intact membrane proteins involved in various diseases. The chirality independent TMD-TMD interactions allows for the design of novel short d- and l-amino acids containing TMD peptides with advanced properties. Overall these studies shed light on the role of specific amino acids in mediating the assembly of the TMDs within the membrane environment and their contribution to protein function. This article is part of a Special Issue entitled: Protein Folding in Membranes.
Protein assembly is a critical process involved in a wide range of cellular events and occurs through extracellular and/or transmembrane domains (TMs). Previous studies demonstrated that a GXXXG motif is crucial for homodimer formation. Here we selected the TMs of ErbB1 and ErbB2 as a model since these receptors function both as homodimers and as heterodimers. Both TMs contain two GXXXG-like motifs located at the C and N termini. The C-terminal motifs were implicated previously in homodimer formation, but the role of the Nterminal motifs was not clear. We used the ToxR system and expressed the TMs of both ErbB1 and ErbB2 containing only the N-terminal GXXXG motifs. The data revealed that the ErbB2 but not the ErbB1 construct formed homodimers. Importantly, a synthetic ErbB1 TM peptide was able to form a heterodimer with ErbB2, by displacing the ErbB2 TM homodimer. The specificity of the interaction was demonstrated by using three controls: (i) Two single mutations within the GXXXG-like motif of the ErbB1 peptide reduced or preserved its activity, in agreement with similar mutations in glycophorin A. (ii) A TM peptide of the bacterial Tar receptor did not assemble with the ErbB2 construct. (iii) The ErbB1 peptide had no effect on the dimerization of a construct containing the TM-1 domain of the Tar receptor. Fluorescence microscopy demonstrated that all the peptides localized on the membrane. Furthermore, incubation with the peptides had no effect on bacterial growth and protein expression levels. Our results suggest that the N-terminal GXXXG-like motif of the ErbB1 TM plays a role in heterodimerization with the ErbB2 transmembrane domain. To our knowledge, this is the first demonstration of a transmembrane domain with two distinct recognition motifs, one for homodimerization and the other for heterodimerization.Protein recognition within the membrane milieu is crucial for a wide range of processes in all organisms. Membrane proteins associate via their extracellular and transmembrane (TM) 1 or solely via their TM domains. Understanding the interactions involved in peptide-peptide recognition within the membrane milieu is therefore an important task. Despite advances, the limited number of studies conducted report mainly on homodimerization and not on heterodimerization of TM segments in vitro and in vivo (1-7). The ability of TM domains to homodimerize in vivo was reported using either the ToxR (2) system or the TOXCAT (8) system. To our knowledge, only a few studies reported on hetero-association of TM domains in vivo. These studies include: (i) introducing exogenous TM peptide mutants of glycophorin A (GPA) to the ToxR system, which expresses the TM domain of glycophorin A, and observing a dominant negative effect (9); and (ii) the study of hetero-association of the TM domain ␣ and  integrin subunits, using the GALLEX system (10). Furthermore, a direct identification of two assembly motifs within a single TM domain has not been reported.For this purpose, we investigated the recognition patterns of the ErbB ...
EmrE is a small multidrug transporter, 110 amino acids long that extrudes various drugs in exchange with protons, thereby rendering Escherichia coli cells resistant to these compounds. Negative dominance studies and radiolabeled substrate-binding studies suggested that EmrE functions as an oligomer. Projection structure of two-dimensional crystals of the protein revealed an asymmetric dimer. To identify the functional unit of EmrE, a novel approach was developed. In this method, quantitative monomer swapping is induced in detergent-solubilized EmrE by exposure to 80°C, a treatment that does not impair transport activity. Oligomer formation is highly specific as judged by several criteria, among them the fact that 35 S-EmrE can be "pulled out" from a mixture prepared from generally labeled cells. Using this technique, we show that inactive mutant subunits are functionally complemented when mixed with wild type subunits. The hetero-oligomers thus formed display a decreased affinity to substrates. In addition, sulfhydryl reagents inhibit the above hetero-oligomer even though Cys residues are present only in the inactive monomer. It is concluded that, in EmrE, the oligomer is the functional unit.
Aromatic residues have been previously shown to mediate the self-assembly of different soluble proteins through -interactions (McGaughey, G. B., Gagne, M., and Rappe, A. K. (1998) J. Biol. Chem. 273, 15458 -15463). However, their role in transmembrane (TM) assembly is not yet clear. In this study, we performed statistical analysis of the frequency of occurrence of aromatic pairs in a bacterial TM data base that provided an initial indication that the appearance of a specific aromatic pattern, Aromatic-XX-Aromatic, is not coincidental, similar to the well characterized QXXS motif. The QXXS motif was previously shown to be both critical and sufficient for stabilizing TM selfassembly. Using the ToxR system, we monitored the dimerization propensities of TM domains that contain mutations of interacting residues to aromatic amino acids and demonstrated that aromatic residues can adequately stabilize self-association. Importantly, we have provided an example of a natural TM domain, the cholera toxin secretion protein EpsM, whose TM self-assembly is mediated by an aromatic motif (WXXW). This is, in fact, the first evidence that aromatic residues are involved in the dimerization of a wild type TM domain. The association mediated by aromatic residues was found to be sensitive to the TM sequence, suggesting that aromatic residue motifs can provide a general means for specificity in TM assembly. Molecular dynamics provided a structural explanation for this backbone sequence sensitivity.Receptor self-assembly is a central process in a variety of signal transduction cascades. This assembly is mainly mediated by the extracellular or the intracellular domains. However, considerable data have been accumulated concerning the causal involvement of the transmembrane (TM) 2 domains in this process as well (1-5). In contrast to the soluble regions of membrane proteins, our knowledge of the factors that control protein-protein interactions and recognition of the membraneembedded domains is still limited.To date, the non-covalent association of native TM domains was reported to be mediated by (i) a heptad motif of leucines through their side chain residues packing interaction (6); (ii) a GXXXG motif, which was first found in the glycophorin A TM domain (4, 8, 9); or (iii) polar residues through the formation of hydrogen bonds (10 -14). However, the involvement of additional motifs or key factors that may mediate protein-protein interactions within the membrane merit further investigation.Examination of the assembly of soluble proteins reveals that aromatic residues serve as key structural elements that mediate the molecular recognition and the self-assembly of amyloid polypeptides as well as bacterial toxins and several proteins such as acetylcholinesterase (15)(16)(17)(18)(19)(20). The interactions are formed between the planar aromatic rings and are referred to as -interactions (21-23). Even a single mutation of aromatic amino acid in the sequence of the short amyloid peptide abolishes the ability of the peptide to form amyloid fibri...
Membrane-active peptides comprise a large group of toxins used in the defense and offense systems of all organisms including plants and humans. They act on diverse targets including microorganisms and mammalian cells, but the factors that determine their target cell selectivity are not yet clear. Here, we tested the role of peptide length and preassembly on the ability of diastereomeric cationic antimicrobial peptides to discriminate among bacteria, erythrocytes, and fungal cells, by using peptides with variable lengths (13, 16, and 19 amino acids long) and their covalently linked pentameric bundles. All the bundles expressed similar potent antifungal activity (minimal inhibitory concentration of 0.2-0.3 microM) and high antimicrobial activity. Hemolytic activity was also observed at concentrations higher than those required for antifungal activity. In contrast, all the monomers showed length-dependent antimicrobial activity, were less active toward bacteria and fungi, and were devoid of hemolytic activity. BIAcore biosensor experiments revealed a approximately 300-fold increase in peptide-membrane binding affinity between the 13- and 19-residue monomers toward zwitterionic (egg phosphatidylcholine (PC)/egg spingomyelin (SM)/cholesterol) vesicles. All the monomeric peptides display a similar high affinity to negatively charged (E. coli phosphatidylethanolamine (PE)/egg phosphatidylglycerol (PG)) vesicles regardless of their length. In contrast, irrespective of the size of the monomeric subunit, all the bundles bind irreversibly and strongly disrupt both PC/SM/cholesterol and PE/PG membranes. Attenuated total reflectance Fourier-transform infrared spectroscopy revealed that peptide assembly also affects structure as observed by an increased alpha-helical and beta-sheet content in membranes and enhances acyl chain disruption of PC/cholesterol. The correlation between the antibacterial activity and ability to depolarize the transmembrane potential of E. coli spheroplasts, as well as the ability to induce calcein release from vesicles, suggests that the bacterial membrane is their target. The data demonstrate that preassembly of cationic diastereomeric antimicrobial peptides is an essential factor in their membrane targeting.
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