Conductance and amantadine binding of a pore formed by a lysine-flanked transmembrane domain of SARS coronavirus envelope protein

The coronavirus responsible for the severe acute respiratory syndrome (SARS-CoV) contains a small envelope protein, E, with putative involvement in host cell apoptosis and virus morphogenesis. It has been suggested that E protein can form a membrane destabilizing transmembrane (TM) hairpin, or homooligomerize to form a regular TM alpha-helical bundle. We have shown previously that the topology of the alpha-helical putative TM domain of E protein (ETM), flanked by two lysine residues at C and N termini to improve solubility, is consistent with a regular TM alpha-helix, with orientational parameters in lipid bilayers that are consistent with a homopentameric model. Herein, we show that this peptide, reconstituted in lipid bilayers, shows sodium conductance. Channel activity is inhibited by the anti-influenza drug amantadine, which was found to bind our preparation with moderate affinity. Results obtained from single or double mutants indicate that the organization of the transmembrane pore is consistent with our previously reported pentameric alpha-helical bundle model.     

The transmembrane oligomers of coronavirus protein E

We have tested the hypothesis that severe acute respiratory syndrome (SARS) coronavirus protein E (SCoVE) and its homologs in other coronaviruses associate through their putative transmembrane domain to form homooligomeric alpha-helical bundles in vivo. For this purpose, we have analyzed the results of molecular dynamics simulations where all possible conformational and aggregational space was systematically explored. Two main assumptions were considered; the first is that protein E contains one transmembrane alpha-helical domain, with its N- and C-termini located in opposite faces of the lipid bilayer. The second is that protein E forms the same type of transmembrane oligomer and with identical backbone structure in different coronaviruses. The models arising from the molecular dynamics simulations were tested for evolutionary conservation using 13 coronavirus protein E homologous sequences. It is extremely unlikely that if any of our assumptions were not correct we would find a persistent structure for all the sequences tested. We show that a low energy dimeric, trimeric and two pentameric models appear to be conserved through evolution, and are therefore likely to be present in vivo. In support of this, we have observed only dimeric, trimeric, and pentameric aggregates for the synthetic transmembrane domain of SARS protein E in SDS. The models obtained point to residues essential for protein E oligomerization in the life cycle of the SARS virus, specifically N15. In addition, these results strongly support a general model where transmembrane domains transiently adopt many aggregation states necessary for function.     

Structure and ion channel activity of the human respiratory syncytial virus (hRSV) small hydrophobic protein transmembrane domain

The small hydrophobic (SH) protein from the human respiratory syncytial virus (hRSV) is a glycoprotein of approximately 64 amino acids with one putative alpha-helical transmembrane domain. Although SH protein is important for viral infectivity, its exact role during viral infection is not clear. Herein, we have studied the secondary structure, orientation, and oligomerization of the transmembrane domain of SH (SH-TM) in the presence of lipid bilayers. Only one oligomer, a pentamer, was observed in PFO-PAGE. Using polarized attenuated total reflection-Fourier transform infrared (PATR-FTIR) spectroscopy, we show that the SH-TM is alpha-helical. The rotational orientation of SH-TM was determined by site-specific infrared dichroism (SSID) at two consecutive isotopically labeled residues. This orientation is consistent with that of an evolutionary conserved pentameric model obtained from a global search protocol using 13 homologous sequences of RSV. Conductance studies of SH-TM indicate ion channel activity, which is cation selective, and inactive below the predicted pK(a) of histidine. Thus, our results provide experimental evidence that the transmembrane domain of SH protein forms pentameric alpha-helical bundles that form cation-selective ion channels in planar lipid bilayers. We provide a model for this pore, which should be useful in mutagenesis studies to elucidate its role during the virus cycle.     

Structure and Inhibition of the SARS Coronavirus Envelope Protein Ion Channel

The envelope (E) protein from coronaviruses is a small polypeptide that contains at least one α-helical transmembrane domain. Absence, or inactivation, of E protein results in attenuated viruses, due to alterations in either virion morphology or tropism. Apart from its morphogenetic properties, protein E has been reported to have membrane permeabilizing activity. Further, the drug hexamethylene amiloride (HMA), but not amiloride, inhibited in vitro ion channel activity of some synthetic coronavirus E proteins, and also viral replication. We have previously shown for the coronavirus species responsible for severe acute respiratory syndrome (SARS-CoV) that the transmembrane domain of E protein (ETM) forms pentameric α-helical bundles that are likely responsible for the observed channel activity. Herein, using solution NMR in dodecylphosphatidylcholine micelles and energy minimization, we have obtained a model of this channel which features regular α-helices that form a pentameric left-handed parallel bundle. The drug HMA was found to bind inside the lumen of the channel, at both the C-terminal and the N-terminal openings, and, in contrast to amiloride, induced additional chemical shifts in ETM. Full length SARS-CoV E displayed channel activity when transiently expressed in human embryonic kidney 293 (HEK-293) cells in a whole-cell patch clamp set-up. This activity was significantly reduced by hexamethylene amiloride (HMA), but not by amiloride. The channel structure presented herein provides a possible rationale for inhibition, and a platform for future structure-based drug design of this potential pharmacological target.     

In vitro dimerization of the bovine papillomavirus E5 protein transmembrane domain

The E5 protein from bovine papillomavirus is a type II membrane protein and the product of the smallest known oncogene. E5 causes cell transformation by binding and activating the platelet-derived growth factor beta receptor (PDGFbetaR). In order to productively interact with the receptor, it is thought that E5 binds as a dimer. However, wild-type E5 and various mutants have also been shown to form trimers, tetramers, and even higher order oligomers. The residues in E5 that drive and stabilize a dimeric state are also still in question. At present, two different models for the E5 dimer exist in the literature, one symmetric and one asymmetric. There is universal agreement, however, that the transmembrane (TM) domain plays a vital role in stabilizing the functional oligomer; indeed, mutation of various TM domain residues can abolish E5 function. In order to better resolve the role of the E5 TM domain in function, we have undertaken the first quantitative in vitro characterization of the E5 TM domain in detergent micelles and liposomes. Circular and linear dichroism analyses verify that the TM domain adopts a stable alpha-helical structure and is able to partition efficiently across lipid bilayers. SDS-PAGE and analytical ultracentrifugation demonstrate for the first time that the TM domain of E5 forms a strong dimer with a standard state free energy of dissociation of 5.0 kcal mol (-1). We have used our new results to interpret existing models of E5 dimer formation and provide a direct link between TM helix interactions and E5 function.     

The transmembrane homotrimer of ADAM 1 in model lipid bilayers

Fertilin is a transmembrane protein heterodimer formed by the two subunits fertilin alpha and fertilin beta that plays an important role in sperm-egg fusion. Fertilin alpha and beta are members of the ADAM family, and contain each one transmembrane alpha-helix, and are termed ADAM 1 and ADAM 2, respectively. ADAM 1 is the subunit that contains a putative fusion peptide, and we have explored the possibility that the transmembrane alpha-helical domain of ADAM 1 forms homotrimers, in common with other viral fusion proteins. Although this peptide was found to form various homooligomers in SDS, the infrared dichroic data obtained with the isotopically labeled peptide at specific positions is consistent with the presence of only one species in DMPC or POPC lipid bilayers. Comparison of the experimental orientational data with molecular dynamics simulations performed with sequence homologues of ADAM 1 show that the species present in lipid bilayers is only consistent with an evolutionarily conserved homotrimeric model for which we provide a backbone structure. These results support a model where ADAM 1 forms homotrimers as a step to create a fusion active intermediate.     

Synthetic null-cysteine phospholamban analogue and the corresponding transmembrane domain inhibit the Ca-ATPase

Chemical synthesis, functional reconstitution, and electron paramagnetic resonance (EPR) have been used to analyze the structure and function of phospholamban (PLB), a 52-residue integral membrane protein that regulates the calcium pump (Ca-ATPase) in cardiac sarcoplasmic reticulum (SR). PLB exists in equilibrium between monomeric and pentameric forms, as observed by SDS-PAGE, EPR, and fluorescence. It has been proposed that inhibition of the pump is due primarily to the monomeric form, with both pentameric stability and inhibition dependent primarily on the transmembrane (TM) domain. To test these hypotheses, we have studied the physical and functional properties of a synthetic null-cysteine PLB analogue that is entirely monomeric on SDS-PAGE, and compared it with the synthetic null-cysteine TM domain (residues 26-52). The TM domain was found to be primarily oligomeric on SDS-PAGE, and boundary lipid spin label analysis in lipid bilayers verified that the isolated TM domain is more oligomeric than the full-length parent molecule. These results indicate that the stability of the PLB pentamer is due primarily to attractive interactions between hydrophobic TM domains, overcoming the repulsive electrostatic interactions between the cationic cytoplasmic domains (residues 1-25). When reconstituted into liposomes containing the Ca-ATPase, the null-cysteine TM domain had the same inhibitory function as that of the full-length parent molecule. We conclude that the TM domain of PLB is sufficient for inhibitory function, the oligomeric stability of PLB does not determine its inhibitory activity, and the three Cys residues in the TM domain are not required for inhibitory function.     

Molecular links between the E2 envelope glycoprotein and nucleocapsid core in Sindbis virus

A three-dimensional reconstruction of Sindbis virus at 7.0 Å resolution presented here provides a detailed view of the virion structure and includes structural evidence for key interactions that occur between the capsid protein (CP) and transmembrane (TM) glycoproteins E1 and E2. Based on crystal structures of component proteins and homology modeling, we constructed a nearly complete, pseudo-atomic model of the virus. Notably, this includes identification of the 33-residue cytoplasmic domain of E2 (cdE2), which follows a path from the E2 TM helix to the CP where it enters and exits the CP hydrophobic pocket and then folds back to contact the viral membrane. Modeling analysis identified three major contact regions between cdE2 and CP, and the roles of specific residues were probed by molecular genetics. This identified R393 and E395 of cdE2 and Y162 and K252 of CP as critical for virus assembly. The N-termini of the CPs form a contiguous network that interconnects 12 pentameric and 30 hexameric CP capsomers. A single glycoprotein spike cross-links three neighboring CP capsomers as might occur during initiation of virus budding.     

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.     

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 alpha-helical conformation for peptide MTM7 and in DMSO three alpha-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 alpha-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.     

Chemical synthesis and single channel properties of tetrameric and pentameric TASPs (template-assembled synthetic proteins) derived from the transmembrane domain of HIV virus protein u (Vpu)

Vpu, an 81-residue membrane protein encoded by the genome of HIV-1, is involved in CD4 degradation and facilitates virion budding from infected cells. The latter activity requires an intact transmembrane (TM) domain; however, the mechanism remains unclear. Vpu forms ion channels, an activity linked to the TM domain and envisioned to arise by oligomerization. The precise number of Vpu monomers that structure the channel is not yet known. To address this issue, we have synthesized tetrameric and pentameric proteins consisting of a carrier template to which four or five peptides corresponding to the TM domain of Vpu are attached. Ketoxime-forming chemoselective ligation efficiently ligated four and five copies, respectively, of the linear transmembrane peptide that was solubilized by the addition of a cleavable polyethylene glycol-polyamide auxiliary to a template. Purified tetrameric and pentameric proteins, denoted as T(4)Vpu and T(5)Vpu, exhibit the predicted mass as determined by MS analysis and fold with a high helical content as evidenced by CD. Both T(4)Vpu and T(5)Vpu, after reconstitution in lipid bilayers, form discrete ion channels of distinct conductance and high propensity to be open. The most frequent openings have a single channel conductance of 42 +/- 5 pS for T(4)Vpu and 76 +/- 5 pS for T(5)Vpu in 0.5m KCl. These findings validate the notion that the channels formed by Vpu result from the self-assembly of monomers. We conclude that a five-helix bundle of the TM of Vpu may approximate the structural motif underlying the oligomeric state of the conductive channel.     

Structural model of the SARS coronavirus E channel in LMPG micelles

Coronaviruses (CoV) cause common colds in humans, but are also responsible for the recent Severe Acute, and Middle East, respiratory syndromes (SARS and MERS, respectively). A promising approach for prevention are live attenuated vaccines (LAVs), some of which target the envelope (E) protein, which is a small membrane protein that forms ion channels. Unfortunately, detailed structural information is still limited for SARS-CoV E, and non-existent for other CoV E proteins. Herein, we report a structural model of a SARS-CoV E construct in LMPG micelles with, for the first time, unequivocal intermolecular NOEs. The model corresponding to the detergent-embedded region is consistent with previously obtained orientational restraints obtained in lipid bilayers and in vivo escape mutants. The C-terminal domain is mostly α-helical, and extramembrane intermolecular NOEs suggest interactions that may affect the TM channel conformation.     

Sedimentation Equilibrium of a Small Oligomer-forming Membrane Protein: Effect of Histidine Protonation on Pentameric Stability

Analytical ultracentrifugation (AUC) can be used to study reversible interactions between macromolecules over a wide range of interaction strengths and under physiological conditions. This makes AUC a method of choice to quantitatively assess stoichiometry and thermodynamics of homo- and hetero-association that are transient and reversible in biochemical processes. In the modality of sedimentation equilibrium (SE), a balance between diffusion and sedimentation provides a profile as a function of radial distance that depends on a specific association model. Herein, a detailed SE protocol is described to determine the size and monomer-monomer association energy of a small membrane protein oligomer using an analytical ultracentrifuge. AUC-ES is label-free, only based on physical principles, and can be used on both water soluble and membrane proteins. An example is shown of the latter, the small hydrophobic (SH) protein in the human respiratory syncytial virus (hRSV), a 65-amino acid polypeptide with a single α-helical transmembrane (TM) domain that forms pentameric ion channels. NMR-based structural data shows that SH protein has two protonatable His residues in its transmembrane domain that are oriented facing the lumen of the channel. SE experiments have been designed to determine how pH affects association constant and the oligomeric size of SH protein. While the pentameric form was preserved in all cases, its association constant was reduced at low pH. These data are in agreement with a similar pH dependency observed for SH channel activity, consistent with a lumenal orientation of the two His residues in SH protein. The latter may experience electrostatic repulsion and reduced oligomer stability at low pH. In summary, this method is applicable whenever quantitative information on subtle protein-protein association changes in physiological conditions have to be measured.       

Toward a high-resolution structure of phospholamban: design of soluble transmembrane domain mutants

Determination of a high-resolution structure of the phospholamban (PLB) transmembrane domain by X-ray crystallography or NMR is handicapped by the hydrophobic nature of the peptide. Interestingly, the crystal structure of the five-stranded parallel coiled-coil oligomerization domain from cartilage oligomeric matrix protein (COMPcc) shows marked similarities to a model proposed for the pentameric transmembrane domain of PLB. Contrary to the putative coiled-coil domain of PLB, COMPcc contains mostly hydrophilic amino acids on the surface, resulting in a soluble molecule. Here, we report the design of soluble PLB transmembrane domain variants by combining the surface residues of COMPcc and the hydrophobic interior of the transmembrane domain of PLB. The soluble PLB variants formed pentameric structures as revealed by analytical ultracentrifugation. After redox shuffling, they showed unspecific disulfide bridge patterns similar to that of the chemically synthesized wild-type PLB transmembrane domain. These results suggest a structural homology between the soluble PLB mutants and the wild-type PLB transmembrane domain. Together with the data reported in the literature, they furthermore indicate that residues Leu37, Ile40, Leu44, and Ile47 of the PLB sequence specify pentamer formation. In contrast, a designed recombinant COMPcc mutant, COMP-ARCC, which was engineered to contain the two PLB cysteines that potentially could form an interchain disulfide bridge, formed a specific disulfide bond pattern. This finding indicates structural differences between the transmembrane domain of PLB and COMPcc. The soluble PLB variants may be used to determine a high-resolution structure of the PLB pentamer by X-ray crystallography.     

Solid-state NMR and molecular dynamics simulations reveal the oligomeric ion-channels of TM2-GABAA stabilized by intermolecular hydrogen bonding

The second transmembrane (TM2) domain of GABA_A receptor forms the inner-lining surface of chloride ion-channel and plays important roles in the function of the receptor protein. In this study, we report the first structure of TM2 in lipid bilayers determined using solid-state NMR and MD simulations. The interatomic ¹³C-¹⁵N distances measured from REDOR magic angle spinning experiments on multilamellar vesicles, containing a TM2 peptide site specifically labeled with ¹³C′ and ¹⁵N isotopes, were used to determine the secondary structure of the peptide. The ¹⁵N chemical shift and ¹H-¹⁵N dipolar coupling parameters measured from PISEMA experiments on mechanically aligned phospholipid bilayers, containing a TM2 peptide site specifically labeled with ¹⁵N isotopes, under static conditions were used to determine the membrane orientation of the peptide. Our results reveal that the TM2 peptide forms an alpha helical conformation with a tilted transmembrane orientation, which is unstable as a monomer but stable as pentameric oligomers as indicated by MD simulations. Even though the peptide consists of a number of hydrophilic residues, the transmembrane folding of the peptide is stabilized by intermolecular hydrogen bondings between the side chains of Ser and Thr residues as revealed by MD simulations. The results also suggest that peptide-peptide interactions in the tilted transmembrane orientation overcome the hydrophobic mismatch between the peptide and bilayer thickness.     

The transmembrane domain of the E5 oncoprotein contains functionally discrete helical faces

The E5 protein of bovine papillomavirus is a 44-amino acid, Golgi-resident, type II transmembrane protein that efficiently transforms immortalized mouse fibroblasts. The transmembrane (TM) domain of E5 is not only critical for biological activity, it also regulates interactions with cellular targets including the platelet derived growth factor receptor (PDGF-R) and the 16-kDa subunit of the vacuolar proton ATPase (V-ATPase). In order to define the specific TM amino acids essential for E5 biological and biochemical activity, we performed scanning alanine mutagenesis on 25 of the 30 potential TM residues and genetically mapped discrete alpha-helical domains which separately regulated the ability of E5 to bind PDGF-R, activate PDGF-R, and to form oligomers. Alanine substitutions at positions 17, 21, and 24 (which lie on the same helical face) greatly inhibited E5 association with the PDGF-R, suggesting that this region comprises the receptor binding site. PDGF-R activation also mapped to a specific but broader domain in E5; mutant proteins with alanines on one helical face (positions 8, 9, 11, 16, 19, 22, and 23) continued to induce PDGF-R tyrosine phosphorylation, whereas mutant proteins with alanines on the opposite helical face (positions 7, 10, 13, 17, 18, 21, 24, and 25) did not, indicating that the latter helical face was critical for mediating receptor transphosphorylation. Interestingly, these "activation-defective" mutants segregated into two classes: 1) those that were unable to form dimers but that could still form higher order oligomers and transform cells, and 2) those that were defective for PDGF-R binding and were transformation-incompetent. These findings suggest that the ability of E5 to dimerize and to bind PDGF-R is important for receptor activation. However, since several transformation-competent E5 mutants were defective for binding and/or activating PDGF-R, it is apparent that E5 must have additional activities to mediate cell transformation. Finally, alanine substitutions also defined two separate helical faces critical for E5/E5 interactions (homodimer formation). Thus, our data identify distinct E5 helical faces that regulate homologous and heterologous intramembrane interactions and define two new classes of biologically active TM mutants.     

Human immunodeficiency virus type 1 and 2 envelope glycoproteins oligomerize through conserved sequences.

Hetero-oligomerization between human immunodeficiency virus type 2 (HIV-2) envelope glycoprotein (Env) truncation mutants and epitope-tagged gp160 is dependent on the presence of gp41 transmembrane protein (TM) amino acids 552 to 589, a putative amphipathic alpha-helical sequence. HIV-2 Env truncation mutants containing this sequence were also able to form cross-type hetero-oligomers with HIV-1 Env. HIV-2/HIV-1 hetero-oligomerization was, however, more sensitive to disruption by mutagenesis or increased temperature. The conservation of the Env oligomerization function of the HIV-1 and HIV-2 alpha-helical sequences suggests that retroviral TM alpha-helical motifs may have a universal role in oligomerization.     

Molecular Dynamics Simulations Reveal the HIV-1 Vpu Transmembrane Protein to Form Stable Pentamers

The human immunodeficiency virus type I (HIV-1) Vpu protein is 81 residues long and has two cytoplasmic and one transmembrane (TM) helical domains. The TM domain oligomerizes to form a monovalent cation selective ion channel and facilitates viral release from host cells. Exactly how many TM domains oligomerize to form the pore is still not understood, with experimental studies indicating the existence of a variety of oligomerization states. In this study, molecular dynamics (MD) simulations were performed to investigate the propensity of the Vpu TM domain to exist in tetrameric, pentameric, and hexameric forms. Starting with an idealized α-helical representation of the TM domain, a thorough search for the possible orientations of the monomer units within each oligomeric form was carried out using replica-exchange MD simulations in an implicit membrane environment. Extensive simulations in a fully hydrated lipid bilayer environment on representative structures obtained from the above approach showed the pentamer to be the most stable oligomeric state, with interhelical van der Waals interactions being critical for stability of the pentamer. Atomic details of the factors responsible for stable pentamer structures are presented. The structural features of the pentamer models are consistent with existing experimental information on the ion channel activity, existence of a kink around the Ile17, and the location of tetherin binding residues. Ser23 is proposed to play an important role in ion channel activity of Vpu and possibly in virus propagation.     

Transmembrane helices that form two opposite homodimeric interactions: an asparagine scan study of alphaM and beta2 integrins

Integrins are alpha/beta heterodimers, but recent in vitro and in vivo experiments also suggest an ability to associate through their transmembrane domains to form homomeric interactions. While the results of some in vitro experiments are consistent with an interaction mediated by a GxxxG-like motif, homo-oligomers observed after in vivo cross-linking are consistent with an almost opposite helix-helix interface. We have shown recently that both models of interaction are compatible with evolutionary conservation data, and we predicted that the alpha-helices in both models would have a similar rotational orientation. Herein, we have tested our prediction using in vitro asparagine scan of five consecutive residues along the GxxxG-like motif of the transmembrane domain of alpha and beta integrins, alphaM and beta2. We show that Asn-mediated dimerization occurs twice for every turn of the helix, consistent with two almost opposite forms of interaction as suggested previously for alphaIIb and beta3 transmembrane domains. The orientational parameters helix tilt and rotational orientation of each of these two Asn-stabilized dimers were measured by site-specific infrared dichroism (SSID) in model lipid bilayers and were found to be consistent with our predicted computational models. Our results highlight an intrinsic tendency for integrin transmembrane alpha-helices to form two opposite types of homomeric interaction in addition to their heteromeric interactions and suggest that integrins may form complex and specific networks at the transmembrane domain during function.     

Structure of the C-terminal domain of the pro-apoptotic protein Hrk and its interaction with model membranes

The protein harakiri (Hrk) is a pro-apoptotic BH3-only protein which belongs to the Bcl-2 family. Hrk appears associated to the mitochondrial outer membrane, apparently by a putative transmembrane domain, where it exerts its function. In this work we have identified a 27mer peptide supposed to be the putative membrane domain of the protein at the C-terminal region, and used infrared and fluorescence spectroscopies to study its secondary structure as well as to characterize its effect on the physical properties of phospholipid model membranes. The results presented here showed that the C-terminal region of Hrk adopts a predominantly alpha-helical structure whose proportion and destabilization capability varied depending on phospholipid composition. Moreover it was found that the orientation of the alpha-helical component of this C-terminal Hrk peptide was nearly perpendicular to the plane of the membrane. These results indicate that this domain is able of inserting into membranes, where it adopts a transmembrane alpha-helical structure as well as it considerably perturbs the physical properties of the membrane.