Expression, purification, and activities of full-length and truncated versions of the integral membrane protein Vpu from HIV-1

Structural implications of mutations assessed by molecular dynamics: Vpu1-32 from HIV-1

Structural pore models are generated for Vpu(1-32)WT from HIV-1 as well as for three mutants W23L, S24L and R31V. A computational methodology is employed which samples the whole conformational space of the pentameric assemblies of Vpu. The analysis of the related energy landscape reveals a small set of reasonable pore models, which are thoroughly investigated regarding their structural properties as well as their putative stability under native-like conditions. The models are also discussed in respect of earlier experimental findings about their channel activities. The study proposes functional pores reflecting the experimentally found conductance states of Vpu and its mutants.

Ligand binding in the conserved interhelical loop of CorA, a magnesium transporter from Mycobacterium tuberculosis

CorA is a constitutively expressed magnesium transporter in many bacteria. The crystal structures of Thermotoga maritima CorA provide an excellent structural framework for continuing studies. Here, the ligand binding properties of the conserved interhelical loop, the only portion of the protein exposed to the periplasmic space, are characterized by solution nuclear magnetic resonance spectroscopy. Through titration experiments performed on the isolated transmembrane domain of Mycobacterium tuberculosis CorA, it was found that two CorA substrates (Mg2+ and Co2+) and the CorA-specific inhibitor (Co(III) hexamine chloride) bind in the loop at the same binding site. This site includes the glutamic acid residue from the conserved "MPEL" motif. The relatively large dissociation constants indicate that such interactions are weak but not atypical for channels. The present data support the hypothesis that the negatively charged loop could act as an electrostatic ring, increasing local substrate concentrations before transport across the membrane.

Vpu enhances HIV-1 virus release in the absence of Bst-2 cell surface down-modulation and intracellular depletion

HIV-1 Vpu enhances the release of virions from infected cells. Recent work identified Bst-2/CD317/tetherin as a host factor whose inhibitory activity on viral release is counteracted by Vpu. A current working model proposes that Bst-2 inhibits virus release by tethering viral particles to the cell surface. Here, we analyzed endogenous Bst-2 with respect to its effect on virus release from HeLa cells, T cells, and macrophages. We noted significant cell type-dependent variation in Bst-2 expression. Vpu caused a reduction in Bst-2 expression in transfected HeLa cells and long-term infected macrophages. However, Vpu expression did not result in cell surface down-modulation of Bst-2 or a reduction in intracellular Bst-2 expression in CEMx174 or H9 cells, yet virus replication in these cells was Vpu-responsive. Surprisingly, Bst-2 was undetectable in cell-free virions that were recovered from the surface of HeLa cells by physical shearing, suggesting that a tethering model may not explain all of the functional properties of Bst-2. Taken together we conclude that enhancement of virus release by Vpu does not, at least in CEMx174 and H9 cells, require cell surface down-modulation or intracellular depletion of Bst-2, nor does it entail exclusion of Bst-2 from viral particles.

Viral channel-forming proteins

Channel-forming proteins are found in a number of viral genomes. In some cases, their role in the viral life cycle is well understood, in some cases it needs still to be elucidated. A common theme is that their mode of action involves a change of electrochemical or proton gradient across the lipid membrane which modulates the viral or cellular activity. Blocking these proteins can be a suitable therapeutic strategy as for some viruses this may be "lethal." Besides the many biological relevant questions still to be answered, there are also many open questions concerning the biophysical side as well as structural information and the mechanism of function on a molecular level. The immanent biophysical issues are addressed and the work in the field is summarized.

Exploring the conformational space of Vpu from HIV-1: a versatile adaptable protein

The dynamic behavior of monomeric Vpu(1-32) from HIV-1 in different lipid environments has been studied. The peptide shows highly flexible behavior during the simulations and easily adapts to changing lipid environments as it experiences when travelling through the Golgi apparatus. Protein-lipid interactions do not show any significant correlation towards lipid type or thickness based on multiple 10 ns simulations. The averaged structure of a series of 16 independent simulations suggest kink around Ser-24, which compensates the polarity of its side chain by forming hydrogen bonds with the carbonyl backbone of adjacent amino acids towards the N-terminus.

Structural consequences of phosphorylation of two serine residues in the cytoplasmic domain of HIV-1 VpU

The human immunodeficiency virus type 1 (HIV-1) protein U (VpU) is an accessory protein responsible for enhancement of viral particle release and down regulation of the T-lymphocyte coreceptor CD4. Direct binding between the cytoplasmic domains of CD4 and VpU as well as phosphorylation of serines 53 and 57 in the cytoplasmic domain of VpU plays a central role in CD4 downregulation. We investigated structural consequences of phosphorylation of the two serines using nuclear magnetic resonance spectroscopy. A uniformly 15N and 13C stable isotope-labeled 45-residue peptide comprising the cytoplasmic domain of VpU (VpUcyt) was recombinantly produced in E .coli. The peptide forms two helices (commonly referred to as helix 2 and 3) in the presence of membrane mimicking dodecylphosphocholine (DPC) micelles, which flank a flexible region containing the two phosphorylation sites. Phosphorylation does not cause any drastic structural changes in the secondary structure of VpUcyt. However, an N-terminal elongation of helix 3 and a slightly reduced helicity at the C-terminus of helix 2 are observed upon phosphorylation based on characteristic changes of 13Calpha and 13Cbeta chemical shifts. Phosphorylation also reduces the local mobility of the protein backbone in the loop region containing the phosphorylation sites according to heteronuclear 1H--15N nuclear Overhauser enhancement (NOE) data.

Biophysical characterization of Vpu from HIV-1 suggests a channel-pore dualism

Vpu from HIV‐1 is an 81 amino acid type I integral membrane protein which consists of a cytoplasmic and a transmembrane (TM) domain. The TM domain is known to alter membrane permeability for ions and substrates when inserted into artificial membranes. Peptides corresponding to the TM domain of Vpu (Vpu_1‐32) and mutant peptides (Vpu_1‐32‐W23L, Vpu_1‐32‐R31V, Vpu_1‐32‐S24L) have been synthesized and reconstituted into artificial lipid bilayers. All peptides show channel activity with a main conductance level of around 20 pS. Vpu_1‐32‐W23L has a considerable flickering pattern in the recordings and longer open times than Vpu_1‐32. Whilst recordings for Vpu_1‐32‐R31V are almost indistinguishable from those of the WT peptide, recordings for Vpu_1‐32‐S24L do not exhibit any noticeable channel activity. Recordings of WT peptide and Vpu_1‐32‐W23L indicate Michaelis–Menten behavior when the salt concentration is increased. Both peptide channels follow the Eisenman series I, indicative for a weak ion channel with almost pore like characteristics. Proteins 2008. © 2007 Wiley‐Liss, Inc.

Biosynthesis, purification, and characterization of a cannabinoid receptor 2 fragment (CB2(271-326))

Obtaining sufficient amount of purified G-protein coupled receptors (GPCRs) is almost always one of the major challenges for their structural studies. CB2(271-326), a human cannabinoid receptor 2 (CB2) fragment comprising part of the third extracellular loop (EL3), the seventh transmembrane domain (TM7) and C-terminal juxtamembrane region of the receptor, was over-expressed as a fusion protein into inclusion body (IB) of Escherichia coli. The fusion protein was purified by histidine-selected nickel affinity chromatography under denaturing conditions. Then, the fusion protein IBs were solubilized in detergent (Brij58) and the expression fusion leader sequence (TrpLE) was specifically cleaved with tobacco etch virus (TEV) protease. The target fragment, CB2(271-326), was subsequently purified by reverse-phase HPLC and confirmed by SDS-PAGE and mass spectrometry. This hydrophobic fragment can refold in mild detergents digitonin and Brij58. Circular dichroism (CD) spectroscopy of CB2(271-326) in digitonin and Brij58 micelles showed that the fragment adopts a more than 75% alpha-helical structure, with the remainder having beta-strand structure. Fluorescence spectroscopy and quenching studies suggested that the C-terminal region lies near the surface of the digitonin micelles and the TM7 region is folded relatively close to the center of the micelles. This study may provide an alternative strategy for the production and structure/functional studies of GPCRs such as CB2 receptor protein produced in the form of IBs.

Structural biology of transmembrane domains: efficient production and characterization of transmembrane peptides by NMR

Structural characterization of transmembrane peptides (TMPs) is justified because transmembrane domains of membrane proteins appear to often function independently of the rest of the protein. However, the challenge in obtaining milligrams of isotopically labeled TMPs to study these highly hydrophobic peptides by nuclear magnetic resonance (NMR) is significant. In the present work, a protocol is developed to produce, isotopically label, and purify TMPs in high yield as well as to initially characterize the TMPs with CD and both solution and solid-state NMR. Six TMPs from three integral membrane proteins, CorA, M2, and KdpF, were studied. CorA and KdpF are from Mycobacterium tuberculosis, while M2 is from influenza A virus. Several milligrams of each of these TMPs ranging from 25 to 89 residues were obtained per liter of M9 culture. The initial structural characterization results showed that these peptides were well folded in both detergent micelles and lipid bilayer preparations. The high yield, the simplicity of purification, and the convenient protocol represents a suitable approach for NMR studies and a starting point for characterizing the transmembrane domains of membrane proteins.

Cytopathic mechanisms of HIV-1

The human immunodeficiency virus type 1 (HIV-1) has been intensely investigated since its discovery in 1983 as the cause of acquired immune deficiency syndrome (AIDS). With relatively few proteins made by the virus, it is able to accomplish many tasks, with each protein serving multiple functions. The Envelope glycoprotein, composed of the two noncovalently linked subunits, SU (surface glycoprotein) and TM (transmembrane glycoprotein) is largely responsible for host cell recognition and entry respectively. While the roles of the N-terminal residues of TM is well established as a fusion pore and anchor for Env into cell membranes, the role of the C-terminus of the protein is not well understood and is fiercely debated. This review gathers information on TM in an attempt to shed some light on the functional regions of this protein.

Expression, purification, and membrane reconstitution of a CD4 fragment comprising the transmembrane and cytoplasmic domains of the receptor

The transmembrane glycoprotein CD4 plays a prominent role in the adaptive immune response. CD4 is displayed primarily on the surface of T helper cells, but also on subsets of memory and regulatory T lymphocytes, macrophages, and dendritic cells. Binding of the lymphocyte specific tyrosine kinase p56(lck) to the cytoplasmic domain of CD4 is crucial for antigen receptor-mediated signal transduction. The human immunodeficiency virus (HIV) utilizes CD4 as the main receptor for T cell invasion. The virus has developed multiple strategies for down-regulation of CD4 in infected cells. Physical interactions of viral proteins VpU and Nef with the cytoplasmic tail of CD4 initiate a cascade of events leading to degradation of CD4. Here we report heterologous expression and purification of a CD4 fragment comprising the transmembrane and cytoplasmic domains of human CD4. A synthetic gene encoding CD4 amino acid residues 372-433 and a protease cleavage site was cloned into the pTKK19xb/ub plasmid. The CD4 fragment was expressed in Escherichia coli C43(DE3) cells as a ubiquitin fusion with an N-terminal His-tag, isolated, released by PreScission proteolytic cleavage, and purified to homogeneity. Incorporation of the recombinant CD4 fragment in lipid membranes and physical interaction with the cytoplasmic domain of VpU was demonstrated by centrifugation assays followed by reversed phase chromatographic analysis of the composition of the proteoliposomes. A high resolution NMR spectrum of uniformly (15)N-labeled CD4 peptide in membrane simulating micelles proves the possibility of solution NMR studies of this CD4 fragment and of its molecular complexes.

Towards a Mechanism of Function of the Viral Ion Channel Vpu from HIV-1

Vpu, an integral membrane protein encoded in HIV-1, is implicated in the release of new virus particles from infected cells, presumably mediated by ion channel activity of homo-oligomeric Vpu bundles. Reconstitution of both full length Vpu(1-81) and a short, the transmembrane (TM) domain comprising peptide Vpu(1-32) into bilayers under a constant electric field results in an asymmetric orientation of those channels. For both cases, channel activity with similar kinetics is observed. Channels can open and remain open within a broad series of conductance states even if a small or no electric potential is applied. The mean open time for Vpu peptide channels is voltage-independent. The rate of channel opening shows a biphasic voltage activation, implicating that the gating is influenced by the interaction of the dipole moments of the TM helices with an electric field.

Expression and purification of milligram levels of inactive G-protein coupled receptors in E. coli

G-protein coupled receptors (GPCRs) are seven transmembrane helical proteins involved in cell signaling and response. They are targets for many existing therapeutic agents, and numerous drug discovery efforts. Production of large quantities of these receptors for drug screening and structural biology remains challenging. To address this difficulty, we sought to express genes for several human GPCRs in Escherichia coli. For most of the receptors, expression was poor, and was not markedly improved even in strains designed to compensate for differences in codon bias between human and E. coli genes. However, the gene for human NK(1) receptor (hNK(1)R) was expressed in large quantities as inclusion bodies in E. coli. The inclusion bodies were not soluble in chemical denaturants such as guanidine chloride or urea, but were soluble in ionic detergents such as SDS, and the zwitterionic detergent fos-choline. Using immobilized metal affinity chromatography, we purified milligram amounts of hNK(1)R. Although inactive in ligand-binding assays, purified hNK(1)R in fos-choline micelles appeared to have a high content of alpha-helix, and was well-behaved in solution. Thus this protein is suitable for additional biophysical characterization and refolding studies.

Drug–protein interaction with Vpu from HIV-1: proposing binding sites for amiloride and one of its derivatives

Vpu is an 81-amino-acid auxiliary protein of the genome of HIV-1. It is proposed that one of its roles is to enhance particle release by self-assembling to form water-filled channels enabling the flux of ions at the site of the plasma membrane of the infected cell. Hexamethylene amiloride has been shown to block Vpu channel activity when the protein is reconstituted into lipid bilayers. In a docking approach with monomeric, pentameric and hexameric bundle models of Vpu corresponding to the transmembrane part of the protein, a putative binding site of hexamethylene amiloride is proposed and is compared with the site for the nonpotent amiloride. The binding mode for both ligands is achieved by optimizing hydrogen bond interactions with serines. Binding energies and binding constants are the lowest for protonated hexamethylene amiloride in the pentameric bundle.

Comparative analysis and "expression space" coverage of the production of prokaryotic membrane proteins for structural genomics

Membrane proteins comprise up to one-third of prokaryotic and eukaryotic genomes, but only a very small number of membrane protein structures are known. Membrane proteins are challenging targets for structural biology, primarily due to the difficulty in producing and purifying milligram quantities of these proteins. We are evaluating different methods to produce and purify large numbers of prokaryotic membrane proteins for subsequent structural and functional analysis. Here, we present the comparative expression data for 37 target proteins, all of them secondary transporters, from the mesophilic organism Salmonella typhimurium and the two hyperthermophilic organisms Aquifex aeolicus and Pyrococcus furiosus in three different Escherichia coli expression vectors. In addition, we study the use of Lactococcus lactis as a host for integral membrane protein expression. Overall, 78% of the targets were successfully produced under at least one set of conditions. Analysis of these results allows us to assess the role of different variables in increasing "expression space" coverage for our set of targets. This analysis implies that to maximize the number of nonhomologous targets that are expressed, orthologous targets should be chosen and tested in two vectors with different types of promoters, using C-terminal tags. In addition, E. coli is shown to be a robust host for the expression of prokaryotic transporters, and is superior to L. lactis. These results therefore suggest appropriate strategies for high-throughput heterologous overproduction of membrane proteins.

Three-dimensional structure of the transmembrane domain of Vpu from HIV-1 in aligned phospholipid bicelles

The three-dimensional backbone structure of the transmembrane domain of Vpu from HIV-1 was determined by solid-state NMR spectroscopy in two magnetically-aligned phospholipid bilayer environments (bicelles) that differed in their hydrophobic thickness. Isotopically labeled samples of Vpu(2-30+), a 36-residue polypeptide containing residues 2-30 from the N-terminus of Vpu, were incorporated into large (q = 3.2 or 3.0) phospholipid bicelles composed of long-chain ether-linked lipids (14-O-PC or 16-O-PC) and short-chain lipids (6-O-PC). The protein-containing bicelles are aligned in the static magnetic field of the NMR spectrometer. Wheel-like patterns of resonances characteristic of tilted transmembrane helices were observed in two-dimensional (1)H/(15)N PISEMA spectra of uniformly (15)N-labeled Vpu(2-30+) obtained on bicelle samples with their bilayer normals aligned perpendicular or parallel to the direction of the magnetic field. The NMR experiments were performed at a (1)H resonance frequency of 900 MHz, and this resulted in improved data compared to lower-resonance frequencies. Analysis of the polarity-index slant-angle wheels and dipolar waves demonstrates the presence of a transmembrane alpha-helix spanning residues 8-25 in both 14-O-PC and 16-O-PC bicelles, which is consistent with results obtained previously in micelles by solution NMR and mechanically aligned lipid bilayers by solid-state NMR. The three-dimensional backbone structures were obtained by structural fitting to the orientation-dependent (15)N chemical shift and (1)H-(15)N dipolar coupling frequencies. Tilt angles of 30 degrees and 21 degrees are observed in 14-O-PC and 16-O-PC bicelles, respectively, which are consistent with the values previously determined for the same polypeptide in mechanically-aligned DMPC and DOPC bilayers. The difference in tilt angle in C14 and C16 bilayer environments is also consistent with previous results indicating that the transmembrane helix of Vpu responds to hydrophobic mismatch by changing its tilt angle. The kink found in the middle of the helix in the longer-chain C18 bilayers aligned on glass plates was not found in either of these shorter-chain (C14 or C16) bilayers.

Comprehensive evaluation of solution nuclear magnetic resonance spectroscopy sample preparation for helical integral membrane proteins

The preparation of high quality samples is a critical challenge for the structural characterization of helical integral membrane proteins. Solving the structures of this diverse class of proteins by solution nuclear magnetic resonance spectroscopy (NMR) requires that well-resolved 2D 1H/15N chemical shift correlation spectra be obtained. Acquiring these spectra demands the production of samples with high levels of purity and excellent homogeneity throughout the sample. In addition, high yields of isotopically enriched protein and efficient purification protocols are required. We describe two robust sample preparation methods for preparing high quality, homogeneous samples of helical integral membrane proteins. These sample preparation protocols have been combined with screens for detergents and sample conditions leading to the efficient production of samples suitable for solution NMR spectroscopy. We have examined 18 helical integral membrane proteins, ranging in size from approximately 9 kDa to 29 kDa with 1-4 transmembrane helices, originating from a number of bacterial and viral genomes. 2D 1H/15N chemical shift correlation spectra acquired for each protein demonstrate well-resolved resonances, and >90% detection of the predicted resonances. These results indicate that with proper sample preparation, high quality solution NMR spectra of helical integral membrane proteins can be obtained greatly enhancing the probability for structural characterization of these important proteins.

Frequency-selective homonuclear dipolar recoupling in solid state NMR

We introduce a new approach to frequency-selective homonuclear dipolar recoupling in solid state nuclear magnetic resonance (NMR) with magic-angle spinning (MAS). This approach, to which we give the acronym SEASHORE, employs alternating periods of double-quantum recoupling and chemical shift evolution to produce phase modulations of the recoupled dipole-dipole interactions that average out undesired couplings, leaving only dipole-dipole couplings between nuclear spins with a selected pair of NMR frequencies. In principle, SEASHORE is applicable to systems with arbitrary coupling strengths and arbitrary sets of NMR frequencies. Arbitrary MAS frequencies are also possible, subject only to restrictions imposed by the pulse sequence chosen for double-quantum recoupling. We demonstrate the efficacy of SEASHORE in experimental (13)C NMR measurements of frequency-selective polarization transfer in uniformly (15)N, (13)C-labeled L-valine powder and frequency-selective intermolecular polarization transfer in amyloid fibrils formed by a synthetic decapeptide containing uniformly (15)N, (13)C-labeled residues.

Full Length Vpu from HIV-1: Combining Molecular Dynamics Simulations with NMR Spectroscopy

Based on structures made available by solution NMR, molecular models of the protein Vpu from HIV-1 were built and refined by 6 ns MD simulations in a fully hydrated lipid bilayer. Vpu is an 81 amino acid type I integral membrane protein encoded by the human immunodeficiency virus type-1 (HIV-1) and closely related simian immunodeficiency viruses (SIVs). Its role is to amplify viral release. Upon phosphorylation, the cytoplasmic domain adopts a more compact shape with helices 2 and 3 becoming almost parallel to each other. A loss of helicity for several residues belonging to the helices adjacent to both ends of the loop region containing serines 53 and 57 is observed. A fourth helix, present in one of the NMR-based structures of the cytoplasmic domain and located near the C-terminus, is lost upon phosphorylation.

High-throughput production of prokaryotic membrane proteins

Membrane proteins constitute ~30% of prokaryotic and eukaryotic genomes but comprise a small fraction of the entries in protein structural databases. A number of features of membrane proteins render them challenging targets for the structural biologist, among which the most important is the difficulty in obtaining sufficient quantities of purified protein. We are exploring procedures to express and purify large numbers of prokaryotic membrane proteins. A set of 280 membrane proteins from Escherichia coli and Thermotoga maritima, a thermophile, was cloned and tested for expression in Escherichia coli. Under a set of standard conditions, expression could be detected in the membrane fraction for approximately 30% of the cloned targets. About 22 of the highest expressing membrane proteins were purified, typically in just two chromatographic steps. There was a clear correlation between the number of predicted transmembrane domains in a given target and its propensity to express and purify. Accordingly, the vast majority of successfully expressed and purified proteins had six or fewer transmembrane domains. We did not observe any clear advantage to the use of thermophilic targets. Two of the purified membrane proteins formed crystals. By comparison with protein production efforts for soluble proteins, where approximately 70% of cloned targets express and approximately 25% can be readily purified for structural studies [Christendat et al. (2000) Nat. Struct. Biol., 7, 903], our results demonstrate that a similar approach will succeed for membrane proteins, albeit with an expected higher attrition rate.

A transmembrane helix-bundle from G-protein coupled receptor CB2: Biosynthesis, purification, and NMR characterization

The cannabinoid receptor subtype 2 (CB2) is a member of the G-protein coupled receptor (GPCR) superfamily. As the relationship between structure and function for this receptor remains poorly understood, the present study was undertaken to characterize the structure of a segment including the first and second transmembrane helix (TM1 and TM2) domains of CB2. To accomplish this, a transmembrane double-helix bundle from this region was expressed, purified, and characterized by NMR. Milligrams of this hydrophobic fragment of the receptor were biosynthesized using a fusion protein overexpression strategy and purified by affinity chromatography combined with reverse phase HPLC. Chemical and enzymatic cleavage methods were implemented to remove the fusion tag. The resultant recombinant protein samples were analyzed and confirmed by HPLC, mass spectrometry, and circular dichroism (CD). The CD analyses of HPLC-purified protein in solution and in DPC micelle preparations suggested predominant alpha-helical structures under both conditions. The 13C/15N double-labeled protein CB2(27-101) was further verified and analyzed by NMR spectroscopy. Sequential assignment was accomplished for more than 80% of residues. The 15N HSQC NMR results show a clear chemical shift dispersion of the amide nitrogen-proton correlation indicative of a pure double-labeled polypeptide molecule. The results suggest that this method is capable of generating transmembrane helical bundles from GPCRs in quantity and purity sufficient for NMR and other biophysical studies. Therefore, the biosynthesis of GPCR transmembrane helix bundles represents a satisfactory alternative strategy to obtain and assemble NMR structures from recombinant "building blocks."

Computational analysis of mutations in the transmembrane region of Vpu from HIV-1

Vpu is an 81 amino acid integral membrane protein encoded by HIV-1. Its alpha-helical transmembrane (TM) domain (residues approximately 6-28) enhances virion release by oligomerizing into bundles and forming ion-conducting channels across the plasma membrane. Its cytoplasmic domain (residues approximately 29-81) is also alpha-helical and binds to the transmembrane protein CD4, inducing its degradation. Mutations within the TM domain have been found to abrogate enhanced particle release from the infected cell (Tiganos et al. Virology (1998) 251 96-107). A series of computational models of monomeric, pentameric and hexameric Vpu(1-31) mutants have been constructed, embedded in fully hydrated lipid bilayers and subjected to a 3 ns molecular dynamics (MD) simulation. None of the mutations has any destabilizing effect on the secondary and tertiary structure. One of the mutants, in which the position of a tryptophan residue within the TM domain is altered, is known not to induce CD4 degradation; an extended kinked model of this mutant has been generated (Vpu(1-52)IVW-k) and during subsequent MD simulations, the bend between the TM and a part of the cytoplasmic domain is found to unwind and a complex salt bridge involving Lys-37 is formed.

Structure, dynamics, and membrane topology of stannin: a mediator of neuronal cell apoptosis induced by trimethyltin chloride

Organotin compounds or alkyltins are ubiquitous environmental toxins that have been implicated in cellular death. Unlike other xenobiotic compounds, such as organomercurials and organoleads, alkyltins activate apoptotic cascades at low concentrations. Trimethyltin (TMT) chloride is amongst the most toxic organotin compounds, and is known to selectively inflict injury to specific regions of the brain. Stannin (SNN), an 88-residue mitochondrial membrane protein, has been identified as the specific marker for neuronal cell apoptosis induced by TMT intoxication. This high specificity of TMT makes SNN an ideal model system for understanding the mechanism of organotin neurotoxicity at a molecular level. Here, we report the three-dimensional structure and dynamics of SNN in detergent micelles, and its topological orientation in lipid bilayers as determined by solution and solid-state NMR spectroscopy. We found that SNN is a monotopic membrane protein composed of three domains: a single transmembrane helix (residues 10-33) that transverses the lipid bilayer at approximately a 20 degrees angle with respect to the membrane normal; a 28 residue unstructured linker, which includes a conserved CXC metal-binding motif and a putative 14-3-3zeta binding domain; and a distorted cytoplasmic helix (residues 61-79) that is partially absorbed into the plane of the lipid bilayer with a tilt angle of approximately 80 degrees from the membrane normal. The structure and architecture of SNN within the lipid environment provides insight about how this protein transmits toxic insults caused by TMT across the membrane.

Tilt Angle of a Trans-membrane Helix is Determined by Hydrophobic Mismatch

In order to investigate the compensation mechanism of a trans-membrane helix in response to hydrophobic mismatch, the tilt and rotation angles of the trans-membrane helix of Vpu aligned in lipid bilayers of various thickness were determined using orientation-dependent frequencies obtained from solid-state NMR experiments of aligned samples. A tilt angle of 18 degrees was observed in 18:1-O-PC/DOPG (9:1) lipid bilayers, which have a hydrophobic thickness that approximately matches the hydrophobic length of the trans-membrane helix of Vpu. Upon decreasing the hydrophobic thickness of lipid bilayers, no significant change in rotation angle was observed. However, the tilt angle increased systematically with increasing positive mismatch to 27 degrees in 14:0-O-PC/DMPG (9:1), 35 degrees in 12:0-O-PC/DLPG (9:1), and 51 degrees in 10:0 PC/10:0 PG (9:1) lipid bilayers, indicating that the change in tilt angle of the trans-membrane helix is a principal compensation mechanism for hydrophobic mismatch. In addition, the distinctive kink in the middle of the helix observed in 18:1 bilayers disappears in thinner bilayers. Although the opposite of what might be expected, this finding suggests that a helix kink may also be a part of the hydrophobic matching mechanism for trans-membrane helices.

Cloning and expression of multiple integral membrane proteins from Mycobacterium tuberculosis in Escherichia coli

Seventy integral membrane proteins from the Mycobacterium tuberculosis genome have been cloned and expressed in Escherichia coli. A combination of T7 promoter-based vectors with hexa-His affinity tags and BL21 E. coli strains with additional tRNA genes to supplement sparsely used E. coli codons have been most successful. The expressed proteins have a wide range of molecular weights and number of transmembrane helices. Expression of these proteins has been observed in the membrane and insoluble fraction of E. coli cell lysates and, in some cases, in the soluble fraction. The highest expression levels in the membrane fraction were restricted to a narrow range of molecular weights and relatively few transmembrane helices. In contrast, overexpression in insoluble aggregates was distributed over a broad range of molecular weights and number of transmembrane helices.

Functional domains within the human immunodeficiency virus type 2 envelope protein required to enhance virus production

Primate lentiviruses code for a protein that stimulates virus production. In human immunodeficiency virus type 1 (HIV-1), the activity is provided by the accessory protein, Vpu, while in HIV-2 and simian immunodeficiency virus it is a property of the envelope (Env) glycoprotein. Using a group of diverse retroviruses and cell types, we have confirmed the functional equivalence of the two proteins. However, despite these similarities, the two proteins have markedly different functional domains. While the Vpu activity is associated primarily with its membrane-spanning region, we have determined that the HIV-2 Env activity requires both the cytoplasmic tail and ectodomain of the protein, with the membrane-spanning domain being less important. Within the Env cytoplasmic tail, we further defined the necessary sequence as a membrane-proximal tyrosine-based motif. Providing the two Env regions separately as distinct CD8 chimeric proteins did not increase virus release. This suggests that the two domains must be either contained within a single protein or closely associated within a multiprotein oligomer, such as the Env trimer, in order to function. Finally, we observed that wild-type levels of incorporation of the HIV-2 Env into budding viruses were not required for this activity.

Mapping the interaction surface of a membrane protein: unveiling the conformational switch of phospholamban in calcium pump regulation

We have used magnetic resonance to map the interaction surface of an integral membrane protein for its regulatory target, an integral membrane enzyme. Phospholamban (PLN) regulates cardiac contractility via its modulation of sarco(endo)plasmic reticulum calcium ATPase (SERCA) activity. Impairment of this regulatory process causes heart failure. To map the molecular details of the PLN/SERCA interaction, we have functionally reconstituted SERCA with labeled PLN in dodecylphosphocholine micelles for high-resolution NMR spectroscopy and in both micelles and lipid bilayers for EPR spectroscopy. Differential perturbations in NMR linewidths and chemical shifts, measured as a function of position in the PLN sequence, provide a vivid picture of extensive SERCA contacts in both cytoplasmic and transmembrane domains of PLN and provide structural insight into previously reported functional mutagenesis data. NMR and EPR data show clear and complementary evidence for a dynamic (micros-to-ms) equilibrium between two conformational states in the cytoplasmic domain of PLN. These results support the hypothesis that SERCA attracts the cytoplasmic domain of PLN away from the lipid surface, shifting the preexisting equilibrium of PLN conformers toward a structure that is poised to interact with the regulatory target. EPR shows that this conformational switch behaves similarly in micelles and lipid membranes. Based on structural and dynamics data, we propose a model in which PLN undergoes allosteric activation upon encountering SERCA.

Expression and purification of a recombinant peptide from the Alzheimer's beta-amyloid protein for solid-state NMR

Fibrillar protein aggregates contribute to the pathology of a number of disease states. To facilitate structural studies of these amyloid fibrils by solid-state NMR, efficient methods for the production of milligram quantities of isotopically labeled peptide are necessary. Bacterial expression of recombinant amyloid proteins and peptides allows uniform isotopic labeling, as well as other patterns of isotope incorporation. However, large-scale production of recombinant amyloidogenic peptides has proven particularly difficult, due to their inherent propensity for aggregation and the associated toxicity of fibrillar material. Yields of recombinant protein are further reduced by the small molecular weights of short amyloidogenic fragments. Here, we report high-yield expression and purification of a peptide comprising residues 11-26 of the Alzheimer's beta-amyloid protein (Abeta(11-26)), with homoserine lactone replacing serine at residue 26. Expression in inclusion bodies as a ketosteroid isomerase fusion protein and subsequent purification under denaturing conditions allows production of milligram quantities of uniformly labeled (13)C- and (15)N-labeled peptide, which forms amyloid fibrils suitable for solid-state NMR spectroscopy. Initial structural data obtained by atomic force microscopy, electron microscopy, and solid-state NMR measurements of Abeta(11-26) fibrils are also presented.

NMR experiments on aligned samples of membrane proteins

NMR methods can be used to determine the structures of membrane proteins. Lipids can be chosen so that protein-containing micelles, bicelles, or bilayers are available as samples. All three types of samples can be aligned weakly or strongly, depending on their rotational correlation time. Solution NMR methods can be used with weakly aligned micelle and small bicelle samples. Solid-state NMR methods can be used with mechanically aligned bilayer and magnetically aligned bicelle samples.

Expression, purification, and isotope labeling of cannabinoid CB2 receptor fragment, CB2180–233

To develop an approach to obtain milligram quantities of purified isotope-labeled seven transmembrane G-protein coupled cannabinoid (CB) receptor for NMR structural analysis, we chose a truncated CB receptor fragment, CB2(180-233), spanning from the fifth transmembrane domain (TM5) to the associated loop regions of cannabinoid CB2 receptor. This highly hydrophobic membrane protein fragment was pursued for developmental studies of membrane proteins through expression and purification in Escherichia coli. The target peptide was cloned and over-expressed in a preparative scale as a fusion protein with a modified TrpDeltaLE1413 (TrpLE) leader sequence and a nine-histidine tag at its N-terminal. An experimental protocol for enzyme cleavage was developed by using Factor Xa to remove the TrpLE tag from the fusion protein. A purification process was also established using a nickel affinity column and reverse-phase HPLC, and then monitored by SDS-PAGE and MS. This expression level is one of the highest reported for a G-protein coupled receptor and fragments in E. Coli, and provided a sufficient amount of purified protein for further biophysical studies.

Recent developments in solid-state magic-angle spinning, nuclear magnetic resonance of fully and significantly isotopically labelled peptides and proteins

In recent years, a large number of solid-state nuclear magnetic resonance (NMR) techniques have been developed and applied to the study of fully or significantly isotopically labelled ((13)C, (15)N or (13)C/(15)N) biomolecules. In the past few years, the first structures of (13)C/(15)N-labelled peptides, Gly-Ile and Met-Leu-Phe, and a protein, Src-homology 3 domain, were solved using magic-angle spinning NMR, without recourse to any structural information obtained from other methods. This progress has been made possible by the development of NMR experiments to assign solid-state spectra and experiments to extract distance and orientational information. Another key aspect to the success of solid-state NMR is the advances made in sample preparation. These improvements will be reviewed in this contribution. Future prospects for the application of solid-state NMR to interesting biological questions will also briefly be discussed.

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.

Three-dimensional structure of the channel-forming trans-membrane domain of virus protein "u" (Vpu) from HIV-1

The three-dimensional structure of the channel-forming trans-membrane domain of virus protein "u" (Vpu) of HIV-1 was determined by NMR spectroscopy in micelle and bilayer samples. Vpu(2-30+) is a 36-residue polypeptide that consists of residues 2-30 from the N terminus of Vpu and a six-residue "solubility tag" at its C terminus that facilitates the isolation, purification, and sample preparation of this highly hydrophobic minimal channel-forming domain. Nearly all of the resonances in the two-dimensional 1H/15N HSQC spectrum of uniformly 15N labeled Vpu(2-30+) in micelles are superimposable on those from the corresponding residues in the spectrum of full-length Vpu, which indicates that the structure of the trans-membrane domain is not strongly affected by the presence of the cytoplasmic domain at its C terminus. The two-dimensional 1H/15N PISEMA spectrum of Vpu(2-30+) in lipid bilayers aligned between glass plates has been fully resolved and assigned. The "wheel-like" pattern of resonances in the spectrum is characteristic of a slightly tilted membrane-spanning helix. Experiments were also performed on weakly aligned micelle samples to measure residual dipolar couplings and chemical shift anisotropies. The analysis of the PISA wheels and Dipolar Waves obtained from both weakly and completely aligned samples show that Vpu(2-30+) has a trans-membrane alpha-helix spanning residues 8-25 with an average tilt of 13 degrees. The helix is kinked slightly at Ile17, which results in tilts of 12 degrees for residues 8-16 and 15 degrees for residues 17-25. A structural fit to the experimental solid-state NMR data results in a three-dimensional structure with precision equivalent to an RMSD of 0.4 A. Vpu(2-30+) exists mainly as an oligomer on PFO-PAGE and forms ion-channels, a most frequent conductance of 96(+/- 6) pS in lipid bilayers. The structural features of the trans-membrane domain are determinants of the ion-channel activity that may be associated with the protein's role in facilitating the budding of new virus particles from infected cells.

Viral and host cofactors facilitate HIV-1 replication in macrophages

Human immunodeficiency virus type 1 (HIV-1) infection of CD4+ T lymphocytes leads to their progressive loss, whereas HIV-1-infected macrophages appear to resist HIV-1-mediated apoptotic death. The differential response of these two host-cell populations may be critical in the development of immunodeficiency and long-term persistence of the virus. Multiple contributing factors may favor the macrophage as a resilient host, not only supporting infection by HIV-1 but also promoting replication and persistence of this member of the lentivirus subfamily of primate retroviruses. An encounter between macrophages and R5 virus engages a signal cascade eventuating in transcriptional regulation of multiple genes including those associated with host defense, cell cycle, nuclear factor-kappaB regulation, and apoptosis. It is important that enhanced gene expression is transient, declining to near control levels, and during this quiescent state, the virus continues its life cycle unimpeded. However, when viral replication becomes prominent, an increase in host genes again occurs under the orchestration of viral gene products. This biphasic host response must fulfill the needs of the parasitic virus as viral replication activity occurs and leads to intracellular and cell surface-associated viral budding. Inroads into understanding how HIV-1 co-opts host factors to generate a permissive environment for viral replication and transmission to new viral hosts may provide opportunities for targeted interruption of this lethal process.

The p7 polypeptide of hepatitis C virus is critical for infectivity and contains functionally important genotype-specific sequences

The role of the hepatitis C virus (HCV) p7 protein in the virus life cycle is not known. Previous in vitro data indicated that this 63-aa polypeptide is located in the endoplasmic reticulum and has two transmembrane domains (TMDs) connected by a cytoplasmic loop; the amino- and carboxyl-terminal tails are oriented toward the endoplasmic reticulum lumen. Furthermore, recent in vitro studies suggested that HCV p7 could function as a virus-encoded ion channel. It might therefore be a relevant target for future drug development. We studied the role of HCV p7 in vivo. Because HCV does not replicate efficiently in cell culture, we mutagenized p7 of an infectious genotype 1a cDNA clone and tested RNA transcripts of each mutant for infectivity in chimpanzees by intrahepatic transfection. Appropriate processing of mutant polypeptides was confirmed by studies in transfected mammalian cells. Mutants with deletions of all or part of p7 and a mutant with substitutions of two conserved residues in the cytoplasmic loop were not viable. Thus, p7 is essential for infectivity of HCV. A chimera in which the p7 of the 1a clone was replaced with p7 from an infectious genotype 2a clone also was not viable. This finding suggests a genotype-specific interaction between p7 and other genomic regions. To define which portions of p7 played the most significant role for this interaction, we tested three chimeras with the 1a backbone in which only specific domains of p7 had the 2a sequence. A p7 chimera with 2a tails and TMDs and the 1a cytoplasmic loop was not viable. A mutant with 2a tails and cytoplasmic loop and 1a TMDs also was not viable. However, a p7 chimera with 2a TMDs and cytoplasmic loop and 1a tails was viable. The transfected chimpanzee became viremic at week 2, and recovered viruses had the chimeric sequence. These data indicate that the amino- and/or carboxyl-terminal intraluminal tails of p7 contain sequences with genotype-specific function.

Vpu from HIV-1 on an atomic scale: experiments and computer simulations

Vpu is an 81 amino acid protein encoded by HIV-1. Its role is to amplify viral release by two mechanisms: (i) docking to CD4 with the consequence of targeting CD4 for ubiquitine-mediated degradation, and (ii) formation of ion channels to enhance particle release. The intensive research on its in vivo function, combined with structural investigations, makes this viral membrane protein one of the better characterised membrane proteins. The wealth of structural information enables the use of computational methods to elucidate the mechanisms of function on an atomic scale. The discovery of Vpu and the development of structural models in a chronological order is summarised and first efforts on investigating the mechanics are outlined.

Structure-function correlates of Vpu, a membrane protein of HIV-1

Vpu, a membrane protein from human immunodeficiency virus-1, folds into two distinct structural domains with different biological activities: a transmembrane (TM) helical domain involved in the budding of new virions from infected cells, and a cytoplasmic domain encompassing two amphipathic helices, which is implicated in CD4 degradation. The molecular mechanism by which Vpu facilitates virion budding is not clear. This activity of Vpu requires an intact TM helical domain. And it is known that oligomerization of the VPU TM domain results in the formation of sequence-specific, cation-selective channels. It has been shown that the channel activity of Vpu is confined to the TM domain, and that the cytoplasmic helices regulate the lifetime of the Vpu channel in the conductive state. Structure-function correlates based on the convergence of information about the channel activity of Vpu reconstituted in lipid bilayers and on its 3-D structure in membranes by a combination of solution and solid-state nuclear magnetic resonance spectroscopy may provide valuable insights to understand the role of Vpu in the pathogenesis of AIDS and for drug design aimed to block channel activity.

Dipolar waves map the structure and topology of helices in membrane proteins

Dipolar waves describe the structure and topology of helices in membrane proteins. The fit of sinusoids with the 3.6 residues per turn period of ideal alpha-helices to experimental measurements of dipolar couplings as a function of residue number makes it possible to simultaneously identify the residues in the helices, detect kinks or curvature in the helices, and determine the absolute rotations and orientations of helices in completely aligned bilayer samples and relative rotations and orientations of helices in a common molecular frame in weakly aligned micelle samples. Since as much as 80% of the structured residues in a membrane protein are in helices, the analysis of dipolar waves provides a significant step toward structure determination of helical membrane proteins by NMR spectroscopy.

The hepatitis C virus p7 protein forms an ion channel that is inhibited by long-alkyl-chain iminosugar derivatives

We show that hepatitis C virus (HCV) p7 protein forms ion channels in black lipid membranes. HCV p7 ion channels are inhibited by long-alkyl-chain iminosugar derivatives, which have antiviral activity against the HCV surrogate bovine viral diarrhea virus. HCV p7 presents a potential target for antiviral therapy.

Molecular dynamics simulations on the first two helices of Vpu from HIV-1

Vpu is an 81 amino acid protein of HIV-1 with two phosphorylation sites. It consists of a short N-terminal end traversing the bilayer and a longer cytoplasmic part. The dual functional role of Vpu is attributed to these topological distinct regions of the protein. The first 52 amino acids of Vpu (HV1H2) have been simulated, which are thought to be embedded in a fully hydrated lipid bilayer and to consist of a transmembrane helix (helix-1) connected via a flexible linker region, including a Glu-Tyr-Arg (EYR) motif, with a second helix (helix-2) residing with its helix long axis on the bilayer surface. Repeated molecular dynamics simulations show that Glu-28 is involved in salt bridge formation with Lys-31 and Arg-34 establishing a kink between the two helices. Helix-2 remains in a helical conformation indicating its stability and function as a "peptide float," separating helix-1 from the rest of the protein. This leads to the conclusion that Vpu consists of three functional modules: helix-1, helix-2, and the remaining residues toward the C-terminal end.

Comparative structural studies of Vpu peptides in phospholipid monolayers by x-ray scattering

Vpu is an 81-residue HIV-1 accessory protein, its transmembrane and cytoplasmic domains each responsible for one of its two functions. Langmuir monolayers of phospholipid incorporating a membrane protein with a unidirectional vectorial orientation, on a semiinfinite aqueous subphase, provide one "membranelike" environment for the protein. The cytoplasmic domain's interaction with the surface of the phospholipid monolayer in determining the tertiary structure of the peptide within the monolayer was investigated, employing a comparative structural study of Vpu with its submolecular fragments Tm and TmCy truncated to different extents in the cytoplasmic domain, via synchrotron x-ray scattering utilizing a new method of analysis. Localizations of the transmembrane and cytoplasmic domains within the monolayer profile structure were similar for all three proteins, the hydrophobic transmembrane helix within the hydrocarbon chain region tilted with respect to the monolayer plane and the helices of the cytoplasmic domains lying on the surface of the headgroups parallel to the monolayer plane. The thickness of the hydrocarbon chain region, determined by the tilt of the hydrocarbon chains and transmembrane domain with respect to the monolayer plane, was slightly different for Tm, TmCy, and Vpu systematically with protein/lipid mole ratio. Localization of the helices in the cytoplasmic domains of the three proteins relative to the headgroups depends on their extents and amphipathicities. Thus, the interaction of the cytoplasmic domain of Vpu on the surface may affect the tilt of the transmembrane helix within the hydrocarbon chain region in determining its tertiary structure in the membrane.

Molecular dynamics simulation of human immunodeficiency virus protein U (Vpu) in lipid/water Langmuir monolayer

Virus protein U (Vpu) is an accessory membrane protein encoded by human immunodeficiency virus type 1 (HIV-1). Various NMR and CD studies have shown that the transmembrane domain of Vpu has a helical conformation and that the cytoplasmic domain adopts the helix-loop-helix-turn motif. This 3.5-ns molecular dynamics (MD) simulation of Vpu in a lipid/membrane environment has fully reproduced these structural characteristics. Membrane propensities of two amphipathic helices in the cytoplasmic domain are further compared here to understand better their complicated orientational behavior known from experiment. This study first reveals that the highly conserved loop region in the cytoplasmic domain can be closely associated with the membrane surface. It is known from the simulation that Vpu is associated with 34 lipids in this Langmuir monolayer. The lipids that are located between the Vpu transmembrane helix and the first helix in the cytoplasmic domain are pushed up by Vpu. These elevated lipids have increased P-N tilt angles for the head groups but unchanged acyl-chain tilt angles compared with lipids that do not interact with Vpu. This study verifies the significance of applying MD simulation in refining protein structure and revealing detailed protein-lipid interaction in membrane/water environment. Figure XZ view of a snapshot of Vpu/DLGPC/water system after 3.5 ns NP(N)gamma T MD simulation. Coloring scheme: Vpu, red; C, green; H, pink; N, blue; O, orange; P, magenta; water, light blue