Conformation of the transmembrane domain of the c-erbB-2 oncogene-encoded protein in its monomeric and dimeric states

The human c-erbB-2 oncogene is homologous to the ratneu oncogene, both encoding transmembrane growth factor receptors. Overexpression and point mutations in the transmembrane domain of the encoded proteins in both cases have been implicated in cell transformation and carcinogenesis. In the case of theneu protein, it has been proposed that these effects are mediated by conformational preferences for an-helix in the transmembrane domain, which facilitates receptor dimerization, an important step in the signal transduction process. To examine whether this is the case for c-erbB-2 as well, we have used conformational energy analysis to determine the preferred three-dimensional structures for the transmembrane domain of the c-erbB-2 protein from residues 650 to 668 with Val (nontransforming) and Glu (transforming) at position 659. The global minimum energy conformation for the Val-659 peptide from the normal, nontransforming protein was found to contain several bends, whereas the global minimum energy conformation for Glu-659 peptide from the mutant, transforming protein was found to be-helical. Thus, the difference in conformational preferences for these transmembrane domains may explain the difference in transforming ability of these proteins. The presence of higher-energy-helical conformations for the transmembrane domain from the normal Val-659 protein may provide an explanation for the presence of a transforming effect from overexpression of c-erbB-2. In addition, docking of the oncogenic sequences in their-helical and bend conformations shows that the all--helical dimer is clearly favored energetically over the bend dimer.     

Conformational changes induced by the transforming amino acid substitution in the transmembrane domain of theneu oncogene-encoded p185 protein

Theneu oncogene is frequently found in certain types of human carcinomas and has been shown to be activated in animal models by nitrosourea-induced mutation. The activating mutation in theneu oncogene results in the substitution of a glutamic acid for a valine at position 664 in the transmembrane domain of the encoded protein product of 185 kda (designated p185), which, on the basis of homology studies, is presumed to be a receptor for an as yet unidentified growth factor. It has been proposed that activating amino acid substitutions in this region of p185 lead to a conformational change in the protein which causes signal transduction via an increase in tyrosine kinase activity in the absence of any external signal. Using conformational energy analysis, we have determined the preferred three-dimensional structures for the transmembrane decapeptide (residues 658–667) of the p185 protein with valine and glutamic acid at the critical position 664. The results indicate that the global minimum energy conformation of the decapeptide from the normal protein with Val at position 664 is an α-helix with a sharp bend (CD* conformation at residues 664 and 665) in this region, whereas the global minimum conformation for the decapeptide from the mutant transforming protein with Glu at position 664 assumes an all α-helical configuration. Furthermore, the second highest energy conformation for the decapeptide from the normal protein is identical to the global minimum energy conformation for the decapeptide from the transforming protein, providing a possible explanation why overexpression of the normal protein also has a transforming effect. These results suggest there may be a normal and a transforming conformation for theneu-encoded p185 proteins which may explain their differences in transforming activity.     

Conformation of the transmembrane domain of the epidermal growth factor receptor

The transmembrane domain of growth factor receptors, such as the epidermal growth factor receptor (EGFR) and the relatedc-erbB-2/neu oncogene protein, has been implicated in the process of receptor dimerization and mitogenic signal transduction, and hence in cellular transformation and oncogenesis. Amino acid substitutions in the transmembrane domain of thec-erbB-2/neu protein that cause a transforming effect may exert this effect through a conformational change from a bend conformation to an-helical structure in this region of the protein, but similar amino acid substitutions at homologous positions in the transmembrane domain of the EGFR (e.g., ValGlu at position 627) fail to have a transforming effect. To examine whether this failure may be due to structural effects, we have used conformational energy analysis to determine the preferred three-dimensional structures for the nonapeptide sequence of the transmembrane domain of the EGFR from residues 623–631 with Val or Glu at position 627. The global minimum energy conformations of both nonapeptides were found to be non--helical with bends at positions 624–625 and 627–628. The failure of the ValGlu substitution to produce a conformational change to an-helix in this region may be responsible for its lack of transforming effect. However, the presence of higher energy-helical conformations for the nonapeptide from the normal EGFR may provide an explanation for the presence of a transforming effect from overexpression of the EGFR.     

Conformational changes induced by the transforming amino acid substitution in the transmembrane domain of the neu oncogene-encoded p185 protein

Theneu oncogene is frequently found in certain types of human carcinomas and has been shown to be activated in animal models by nitrosourea-induced mutation. The activating mutation in theneu oncogene results in the substitution of a glutamic acid for a valine at position 664 in the transmembrane domain of the encoded protein product of 185 kda (designated p185), which, on the basis of homology studies, is presumed to be a receptor for an as yet unidentified growth factor. It has been proposed that activating amino acid substitutions in this region of p185 lead to a conformational change in the protein which causes signal transduction via an increase in tyrosine kinase activity in the absence of any external signal. Using conformational energy analysis, we have determined the preferred three-dimensional structures for the transmembrane decapeptide (residues 658–667) of the p185 protein with valine and glutamic acid at the critical position 664. The results indicate that the global minimum energy conformation of the decapeptide from the normal protein with Val at position 664 is an -helix with a sharp bend (CD* conformation at residues 664 and 665) in this region, whereas the global minimum conformation for the decapeptide from the mutant transforming protein with Glu at position 664 assumes an all -helical configuration. Furthermore, the second highest energy conformation for the decapeptide from the normal protein is identical to the global minimum energy conformation for the decapeptide from the transforming protein, providing a possible explanation why overexpression of the normal protein also has a transforming effect. These results suggest there may be a normal and a transforming conformation for theneu-encoded p185 proteins which may explain their differences in transforming activity.     

Influence of a Mutation in the Transmembrane Domain of the pl85c-erbB2 Oncogene-Encoded Protein Studied by Molecular Dynamics Simulations

Abstract

The c-erbB2 proto-oncogene encodes for a protein of 185kDa (p 185) which becomes transforming upon the Val→-Glu transmembrane amino acid substitution. The transforming ability seems to be due to a substitution-resulting constitutive activation of the tyrosine kinase cytosolic domain of the protein. These observations prompted us to evaluate the structural and dynamical behavior of the transmembrane region of the wild and transforming p 185 protein in order to understand the role of this region in the transduction mechanism. 160 ps molecular dynamics simulations in vacuo have been performed on two peptides corresponding to the sequence [651-679] of p 185^c-erbB2 protein and its transforming mutant Val⁶⁵⁹→Glu⁶⁵⁹. These two sequences include the transmembrane domain and are initially postulated to be in an α- helix conformation. Noticeable differences in the flexibility of the two peptides are shown. The nontransforming sequence seems rather flexible and several conformational changes are detected at the junction of the mutation point [658-659] and at position Val⁶⁶⁵-Val⁶⁶⁶ during the 160 ps simulations. On the contrary, no transitions were observed for the mutated sequence which adopts a stable α-helix conformation. This difference in flexibility could be hypothesized as a factor involved in the regulation of the tyrosine kinase activity of 185^c-erbB2     

Unwinding of the Substrate Transmembrane Helix in Intramembrane Proteolysis

Intramembrane-cleaving proteases (I-CLiPs) activate pools of single-pass helical membrane protein signaling precursors that are key in the physiology of prokaryotic and eukaryotic cells. Proteases typically cleave peptide bonds within extended or flexible regions of their substrates, and thus the mechanism underlying the ability of I-CLiPs to hydrolyze the presumably α-helical transmembrane domain (TMD) of these membrane proteins is unclear. Using deep-ultraviolet resonance Raman spectroscopy in combination with isotopic labeling, we show that although predominantly in canonical α-helical conformation, the TMD of the established I-CLiP substrate Gurken displays 3₁₀-helical geometry. As measured by microscale thermophoresis, this substrate binds with high affinity to the I-CLiPs GlpG rhomboid and MCMJR1 presenilin homolog in detergent micelles. Binding results in deep-ultraviolet resonance Raman spectra, indicating conformational changes consistent with unwinding of the 3₁₀-helical region of the substrate’s TMD. This 3₁₀-helical conformation is key for intramembrane proteolysis, as the substitution of a single proline residue in the TMD of Gurken by alanine suppresses 3₁₀-helical content in favor of α-helical geometry and abolishes cleavage without affecting binding to the I-CLiP. Complemented by molecular dynamics simulations of the TMD of Gurken, our vibrational spectroscopy data provide biophysical evidence in support of a model in which the transmembrane region of cleavable I-CLiP substrates displays local deviations in canonical α-helical conformation characterized by chain flexibility, and binding to the enzyme results in conformational changes that facilitate local unwinding of the transmembrane helix for cleavage.     

Identification and characterization of the avian erythroblastosis virus erbB gene product as a membrane glycoprotein

Avian erythroblastosis virus causes erythroid leukemia and sarcomas in chickens. The viral oncogene responsible for these diseases, erb, is divided into two regions known as erbA and erbB, and recent evidence suggests that it is the erbB gene that is responsible for the transforming activity. From rats bearing avian erythroblastosis virus-induced sarcomas, we have obtained antisera which are specific for the erb gene products. Using such antisera, we have been able to characterize the erbB gene product as a 68,000 molecular weight protein. Pulse-chase and cell-free in vitro translation experiments show that the initial product is a 62,500 dalton protein which is initially modified to a 66,000 dalton protein, and then further modified to a 68,000 dalton form. These modifications could be shown to be associated with glycosylation and phosphorylation. Cell fractionation experiments revealed that the 66,000 and 68,000 dalton proteins were located in cell membrane fractions, and immunofluorescence results showed the erbB gene product to be expressed on the cell surface.     

Structural flexibility of the pentameric SARS coronavirus envelope protein ion channel

Coronaviruses contain a small envelope membrane protein with cation-selective ion channel activity mediated by its transmembrane domain (ETM). In a computational study, we proposed that ion channel activity can be explained by either of two similar ETM homopentameric transmembrane α-helical bundles, related by a ∼50° rotation of the helices. Later, we tested this prediction, using site-specific infrared dichroism of a lysine-flanked isotopically labeled ETM peptide from the virus responsible for the severe acute respiratory syndrome, SARS, reconstituted in lipid bilayers. However, the data were consistent with the presence of a kink at the center of the ETM α-helix, and it did not fit completely either computational model. Herein, we have used native ETM, without flanking lysines, and show that the helix orientation is now consistent with one of the predicted models. ETM only produced one oligomeric form, pentamers, in the lipid-mimic detergent dodecylphosphocholine and in perfluorooctanoic acid. We thus report the correct backbone model for the pentameric α-helical bundle of ETM. The disruptive effects caused by terminal lysines probably highlight the conformational flexibility required during ion channel function.     

Structural basis for epidermal growth factor receptor function

The receptor for epidermal growth factor (EGF) has been the subject of intense study primarily as a consequence of the pioneering studies of Cohen on growth factors and also because of its homology to the transforming protein encoded by the avian oncogene v-erbB, which is a truncated receptor, and its consequent role in cancer. Although similar structural mutation of the EGF receptor has not yet been found in human tumours, aberrant overexpression of both EGF receptors and c-erbB2, a closely related putative receptor [1], have been found to occur in squamous cell carcinomas and glial tumours, and mammary carcinomas respectively [2–4]. In addition to EGF, the related polypeptides transforming growth factor α (TGFα) and vaccinia virus growth factor [5] are also ligands for the EGF receptor. Expression of TGFα occurs during embryonal development and in specific adult tissues; it may also play a role in cellular transformation (reviewed in Ref. 6). These important properties, as well as the potential roles of both TGFα and EGF in wound repair, have emphasized the need to understand EGF receptor structure, function and regulation. This review discusses the structural properties of the EGF receptor and how these can be related to receptor function and regulation.     

Transmembrane Domain Sequence Requirements for Activation of the p185c-neu Receptor Tyrosine Kinase

The receptor tyrosine kinase p185^c-neu can be constitutively activated by the transmembrane domain mutation Val⁶⁶⁴→ Glu, found in the oncogenic mutant p185^neu. This mutation is predicted to allow intermolecular hydrogen bonding and receptor dimerization. Understanding the activation of p185^c-neu has assumed greater relevance with the recent observation that achondroplasia, the most common genetic form of human dwarfism, is caused by a similar transmembrane domain mutation that activates fibroblast growth factor receptor (FGFR) 3. We have isolated novel transforming derivatives of p185^c-neu using a large pool of degenerate oligonucleotides encoding variants of the transmembrane domain. Several of the transforming isolates identified were unusual in that they lacked a Glu at residue 664, and others were unique in that they contained multiple Glu residues within the transmembrane domain. The Glu residues in the transforming isolates often exhibited a spacing of seven residues or occurred in positions likely to represent the helical interface. However, the distinction between the sequences of the transforming clones and the nontransforming clones did not suggest clear rules for predicting which specific sequences would result in receptor activation and transformation. To investigate these requirements further, entirely novel transmembrane sequences were constructed based on tandem repeats of simple heptad sequences. Activation was achieved by transmembrane sequences such as [VVVEVVA]_n or [VVVEVVV]_n, whereas activation was not achieved by a transmembrane domain consisting only of Val residues. In the context of these transmembrane domains, Glu or Gln were equally activating, while Lys, Ser, and Asp were not. Using transmembrane domains with two Glu residues, the spacing between these was systematically varied from two to eight residues, with only the heptad spacing resulting in receptor activation. These results are discussed in the context of activating mutations in the transmembrane domain of FGFR3 that are responsible for the human developmental syndromes achondroplasia and acanthosis nigricans with Crouzon Syndrome.     

Solution NMR Structure and Functional Analysis of the Integral Membrane Protein YgaP from Escherichia coli

The solution NMR structure of the α-helical integral membrane protein YgaP from Escherichia coli in mixed 1,2-diheptanoyl-sn-glycerol-3-phosphocholine/1-myristoyl-2-hydroxy-sn-glycero-3-phospho-(1′-rac-glycerol) micelles is presented. In these micelles, YgaP forms a homodimer with the two transmembrane helices being the dimer interface, whereas the N-terminal cytoplasmic domain includes a rhodanese-fold in accordance to its sequence homology to the rhodanese family of sulfurtransferases. The enzymatic sulfur transfer activity of full-length YgaP as well as of the N-terminal rhodanese domain only was investigated performing a series of titrations with sodium thiosulfate and potassium cyanide monitored by NMR and EPR. The data indicate the thiosulfate concentration-dependent addition of several sulfur atoms to the catalytic Cys-63, which process can be reversed by the addition of potassium cyanide. The catalytic reaction induces thereby conformational changes within the rhodanese domain, as well as on the transmembrane α-helices of YgaP. These results provide insights into a potential mechanism of YgaP during the catalytic thiosulfate activity in vivo.     

The Crystal Structures of Yeast Get3 Suggest a Mechanism for Tail-Anchored Protein Membrane Insertion

Tail-anchored (TA) proteins represent a unique class of membrane proteins that contain a single C-terminal transmembrane helix. The post-translational insertion of the yeast TA proteins into the ER membrane requires the Golgi ER trafficking (GET) complex which contains Get1, Get2 and Get3. Get3 is an ATPase that recognizes and binds the C-terminal transmembrane domain (TMD) of the TA proteins. We have determined the crystal structures of Get3 from two yeast species, S. cerevisiae and D. hansenii, respectively. These high resolution crystal structures show that Get3 contains a nucleotide-binding domain and a “finger” domain for binding the TA protein TMD. A large hydrophobic groove on the finger domain of S. cerevisiae Get3 structure might represent the binding site for TMD of TA proteins. A hydrophobic helix from a symmetry-related Get3 molecule sits in the TMD-binding groove and mimics the TA binding scenario. Interestingly, the crystal structures of the Get3 dimers from S. cerevisiae and D. hansenii exhibit distinct conformations. The S. cerevisiae Get3 dimer structure does not contain nucleotides and maintains an “open” conformation, while the D. hansenii Get3 dimer structure binds ADP and stays in a “closed” conformation. We propose that the conformational changes to switch the Get3 between the open and closed conformations may facilitate the membrane insertions for TA proteins.     

Structural and Dynamic Properties of the Human Prion Protein

Prion diseases involve the conformational conversion of the cellular prion protein (PrP^C) to its misfolded pathogenic form (PrP^Sc). To better understand the structural mechanism of this conversion, we performed extensive all-atom, explicit-solvent molecular-dynamics simulations for three structures of the wild-type human PrP (huPrP) at different pH values and temperatures. Residue 129 is polymorphic, being either Met or Val. Two of the three structures have Met in position 129 and the other has Val. Lowering the pH or raising the temperature induced large conformational changes of the C-terminal globular domain and increased exposure of its hydrophobic core. In some simulations, HA and its preceding S1-HA loop underwent large displacements. The C-terminus of HB was unstable and sometimes partially unfolded. Two hydrophobic residues, Phe-198 and Met-134, frequently became exposed to solvent. These conformational changes became more dramatic at lower pH or higher temperature. Furthermore, Tyr-169 and the S2-HB loop, or the X-loop, were different in the starting structures but converged to common conformations in the simulations for the Met-129, but not the Val-129, protein. α-Strands and β-strands formed in the initially unstructured N-terminus. α-Strand propensity in the N-terminus was different between the Met-129 and Val129 proteins, but β-strand propensity was similar. This study reveals detailed structural and dynamic properties of huPrP, providing insight into the mechanism of the conversion of PrP^C to PrP^Sc.     

Differential Selection of Cells with Proviral c-myc and c-erbB Integrations after Avian Leukosis Virus Infection

Avian leukosis virus (ALV) infection induces bursal lymphomas in chickens after proviral integration within the c-myc proto-oncogene and induces erythroblastosis after integration within the c-erbB proto-oncogene. A nested PCR assay was used to analyze the appearance of these integrations at an early stage of tumor induction after infection of embryos. Five to eight distinct proviral c-myc integration events were amplified from bursas of infected 35-day-old birds, in good agreement with the number of transformed bursal follicles arising with these integrations. Cells containing these integrations are remarkably common, with an estimated 1 in 350 bursal cells having proviral c-myc integrations. These integrations were clustered within the 3′ half of c-myc intron 1, in a pattern similar to that observed in bursal lymphomas. Bone marrow and spleen showed a similar number and pattern of integrations clustered within 3′ c-myc intron 1, indicating that this region is a common integration target whether or not that tissue undergoes tumor induction. While all tissues showed equivalent levels of viral infection, cells with c-myc integrations were much more abundant in the bursa than in other tissues, indicating that cells with proviral c-myc integrations are preferentially expanded within the bursal environment. Proviral integration within the c-erbB gene was also analyzed, to detect clustered c-erbB intron 14 integrations associated with erythroblastosis. Proviral c-erbB integrations were equally abundant in the bone marrow, spleen, and bursa. These integrations were randomly situated upstream of c-erbB exon 15, indicating that cells carrying 3′ intron 14 integrations must be selected during induction of erythroblastosis.     

The c-erbB-2 proto-oncogene as a prognostic and predictive marker in breast cancer: A paradigm for the development of other macromolecular markers-A review

Seven years after the initial studies of the prognostic value of the proto-oncogene c-erbB-2 in breast cancer, its role is still being defined. The interpretation of studies on the use of this gene and its protein product in prognostic and predictive tests for breast cancer is complicated by multiple methodologies and the inherent difficulties in the studies. The work has moved beyond the stage at which small studies with short follow-up (useful for hypothesis generation) are of value, to the stage in which large studies with sufficient statistical power to find significant correlations are central. These larger studies do not lend support for the use of c-erbB-2 in the evaluation of axillary-node-negative patients, the group of breast cancer patients for whom refinement of prognostic estimates is now most important. There are, however, hints that c-erbB-2 may have value in predicting response to certain treatments, though the studies so far are too few, often too small and too conflicting to reliably confirm this.     

The Mechanism of VWF-Mediated Platelet GPIbα Binding

The binding of Von Willebrand Factor to platelets is dependent on the conformation of the A1 domain which binds to platelet GPIbα. This interaction initiates the adherence of platelets to the subendothelial vasculature under the high shear that occurs in pathological thrombosis. We have developed a thermodynamic strategy that defines the A1:GPIbα interaction in terms of the free energies (ΔG values) of A1 unfolding from the native to intermediate state and the binding of these conformational states to GPIbα. We have isolated the intermediate conformation of A1 under nondenaturing conditions by reduction and carboxyamidation of the disulfide bond. The circular dichroism spectrum of reduction and carboxyamidation A1 indicates that the intermediate has ∼10% less α-helical structure that the native conformation. The loss of α-helical secondary structure increases the GPIbα binding affinity of the A1 domain ∼20-fold relative to the native conformation. Knowledge of these ΔG values illustrates that the A1:GPIbα complex exists in equilibrium between these two thermodynamically distinct conformations. Using this thermodynamic foundation, we have developed a quantitative allosteric model of the force-dependent catch-to-slip bonding that occurs between Von Willebrand Factor and platelets under elevated shear stress. Forced dissociation of GPIbα from A1 shifts the equilibrium from the low affinity native conformation to the high affinity intermediate conformation. Our results demonstrate that A1 binding to GPIbα is thermodynamically coupled to A1 unfolding and catch-to-slip bonding is a manifestation of this coupling. Our analysis unites thermodynamics of protein unfolding and conformation-specific binding with the force dependence of biological catch bonds and it encompasses the effects of two subtypes of mutations that cause Von Willebrand Disease.     

The erbB gene of avian erythroblastosis virus is a member of the src gene family

The erbB gene of an avian erythroblastosis virus, AEV-H, was determined to be 1812 nucleotides long and was predicted to code for a protein of 67,638 daltons. Unexpectedly, a sequence of 285 amino acids in the middle of the protein showed a significant homology (38%) with the sequence in the carboxy terminus of p60^src. The nucleotide sequence of a mutant of AEV-H, td-130, which induces sarcomas but not erythroblastosis in chicken, was also analyzed. A deletion of 169 nucleotides was identified in the 3′ half of the erbB gene, indicating that the gene codes for a truncated protein with the predicted molecular weight of 46,667. These findings suggest that the homologous domain of erbB protein with its N-terminal portion is sufficient for the transformation of fibroblasts and that one-third of the carboxy-terminal domain has a key role for the transformation of erythroid cells.     

An activating amino acid substitution in the c-abl oncogene protein fails to produce a local conformational change

Thebcr-abl chimeric gene of Philadelphia chromosome positive chronic myelogenous leukemias is only weakly transforming. This transformation activity is greatly enhanced by a Lys-for-Glu substitution at position 832 in the c-abl gene, as occurs in the highly transforming v-abl genes. It has been suggested that this mutation results in a significant structural change in the encoded protein product. Using conformational energy analysis, we have determined the allowed low-energy conformations for residues 828–836 of this protein with Lys and Glu at position 832. In both cases, the overwhelmingly preferred conformation for this region is a bend-helix motif. The helix terminates at residue 836, and there are no discernible differences in conformation between the Lys- and Glu-containing sequences. These results suggest that the activating amino acid substitution at position 832 in the c-abl protein product does not produce its effect via a local conformational change.     

Conformational Analysis of the Partially Disordered Measles Virus NTAIL-XD Complex by SDSL EPR Spectroscopy

To characterize the structure of dynamic protein systems, such as partly disordered protein complexes, we propose a novel approach that relies on a combination of site-directed spin-labeled electron paramagnetic resonance spectroscopy and modeling of local rotation conformational spaces. We applied this approach to the intrinsically disordered C-terminal domain of the measles virus nucleoprotein (N_TAIL) both free and in complex with the X domain (XD, aa 459-507) of the viral phosphoprotein. By comparing measured and modeled temperature-dependent restrictions of the side-chain conformational spaces of 12 SL cysteine-substituted N_TAIL variants, we showed that the 490-500 region of N_TAIL is prestructured in the absence of the partner, and were able to quantitatively estimate, for the first time to our knowledge, the extent of the α-helical sampling of the free form. In addition, we showed that the 505-525 region of N_TAIL conserves a significant degree of freedom even in the bound form. The latter two findings provide a mechanistic explanation for the reported rather high affinity of the N_TAIL-XD binding reaction. Due to the nanosecond timescale of X-band EPR spectroscopy, we were also able to monitor the disordering in the 488-525 region of N_TAIL, in particular the unfolding of the α-helical region when the temperature was increased from 281 K to 310 K.     

Structure and localization of an essential transmembrane segment of the proton translocation channel of yeast H-V-ATPase

Vacuolar (H⁺)-ATPase (V-ATPase) is a proton pump present in several compartments of eukaryotic cells to regulate physiological processes. From biochemical studies it is known that the interaction between arginine 735 present in the seventh transmembrane (TM7) segment from subunit a and specific glutamic acid residues in the subunit c assembly plays an essential role in proton translocation. To provide more detailed structural information about this protein domain, a peptide resembling TM7 (denoted peptide MTM7) from Saccharomyces cerevisiae (yeast) V-ATPase was synthesized and dissolved in two membrane-mimicking solvents: DMSO and SDS. For the first time the secondary structure of the putative TM7 segment from subunit a is obtained by the combined use of CD and NMR spectroscopy. SDS micelles reveal an α-helical conformation for peptide MTM7 and in DMSO three α-helical regions are identified by 2D ¹H-NMR. Based on these conformational findings a new structural model is proposed for the putative TM7 in its natural environment. It is composed of 32 amino acid residues that span the membrane in an α-helical conformation. It starts at the cytoplasmic side at residue T719 and ends at the luminal side at residue W751. Both the luminal and cytoplasmatic regions of TM7 are stabilized by the neighboring hydrophobic transmembrane segments of subunit a and the subunit c assembly from V-ATPase.