Assignment of amide 1H and 15N NMR resonances in detergent-solubilized M13 coat protein: a model for the coat protein dimer

Filamentous Bacteriophage Proteins and Assembly

Filamentous bacteriophages, also known as filamentous bacterial viruses or Inoviruses, have been studied extensively over the years. They are interesting paradigms in structural molecular biology and offer insight into molecular assembly, a process that remains to be fully understood. In this chapter, an overview on filamentous bacteriophages will be provided. In particular, we review the constituent proteins of filamentous bacteriophage and discuss assembly by examining the structure of the major coat protein at various stages of the process. The minor coat proteins will also be briefly reviewed. Structural information provides key snapshots into the dynamic process of assembly.

Impact of Differential Detergent Interactions on Transmembrane Helix Dimerization Affinities

Interactions between transmembrane (TM) helices play a critical role in the fundamental processes required for cells to communicate and exchange materials with their surroundings. Our understanding of the factors that promote TM helix interactions has greatly benefited from our ability to study these interactions in the solution phase through the use of membrane-mimetic micelles. However, less is known about the potential influence of juxtamembrane regions flanking the interacting TM helices that may modulate dimerization affinities, even when the interacting surface itself is not altered. To investigate this question, we used solution NMR to quantitate the dimerization affinity of the major coat protein from the M13 bacteriophage in sodium dodecyl sulfate (SDS), a well-characterized model of a single-spanning self-associating TM protein. Here, we showed that a shorter construct lacking the N-terminal amphipathic helix has a higher dimerization affinity relative to that of the full-length protein, with no change in the helical structure between the monomeric and dimeric states in both cases. Although this translated into a 0.6 kcal/mol difference in free energy when the SDS solvent was approximated as a continuous phase, there were deviations from this model at high protein to detergent ratios. Instead, the equilibria were better fit to a model that treats the empty micelle as an active participant in the reaction, giving rise to standard free energies of association that were the same for both full-length and TM-segment constructs. According to this model, the higher apparent affinity of the shorter peptide could be completely explained by the enhanced detergent binding by the monomer relative to that bound by the dimer. Therefore, differential detergent binding between the monomeric and dimeric states provides a mechanism by which TM helix interactions can be modulated by noninteracting juxtamembrane regions.

Contemporary methods in structure determination of membrane proteins by solution NMR

Integral membrane proteins are vital to life, being responsible for information and material exchange between a cell and its environment. Although high-resolution structural information is needed to understand how these functions are achieved, membrane proteins remain an under-represented subset of the protein structure databank. Solution NMR is increasingly demonstrating its ability to help address this knowledge shortfall, with the development of a diverse array of techniques to counter the challenges presented by membrane proteins. Here we document the advances that are helping to define solution NMR as an effective tool for membrane protein structure determination. Developments introduced over the last decade in the production of isotope-labeled samples, reconstitution of these samples into the growing selection of NMR-compatible membrane-mimetic systems, and the approaches used for the acquisition and application of structural restraints from these complexes are reviewed.

Membrane binding properties of EBV gp110 C-terminal domain; evidences for structural transition in the membrane environment

Gp110 of Epstein-Barr virus (EBV) mainly localizes on nuclear/ER membranes and plays a role in the assembly of EBV nucleocapsid. The C-terminal tail domain (gp110 CTD) is essential for the function of gp110 and the nuclear/ER membranes localization of gp110 is ruled by its C-terminal unique nuclear localization signal (NLS), consecutive four arginines. In the present study, the structural properties of gp110 CTD in membrane mimics were investigated using CD, size-exclusion chromatography, and NMR, to elucidate the effect of membrane environment on the structural transition and to compare the structural feature of the protein in the solution state with that of the membrane-bound form. CD and NMR analysis showed that gp110 CTD in a buffer solution appears to adopt a stable folding intermediate which lacks compactness, and a highly helical structure is formed only in membrane environments. The helical content of gp110 CTD was significantly affected by the negative charge as well as the size of membrane mimics. Based on the elution profiles of the size-exclusion chromatography, we found that gp110 CTD intrinsically forms a trimer, revealing that a trimerization region may exist in the C-terminal domain of gp110 like the ectodomain of gp110. The mutation of NLS (RRRR) to RTTR does not affect the overall structure of gp110 CTD in membrane mimics, while the helical propensity in a buffer solution was slightly different between the wild-type and the mutant proteins. This result suggests that not only the helicity induced in membrane environment but also the local structure around NLS may be related to trafficking to the nuclear membrane. More detailed structural difference between the wild-type and the mutant in membrane environment was examined using synthetic two peptides including the wild-type NLS and the mutant NLS.

Chemical shift assignment and structural plasticity of a HIV fusion peptide derivative in dodecylphosphocholine micelles

A "HFPK3" peptide containing the 23 residues of the human immunodeficiency virus (HIV) fusion peptide (HFP) plus three non-native C-terminal lysines was studied in dodecylphosphocholine (DPC) micelles with 2D 1H NMR spectroscopy. The HFP is at the N-terminus of the gp41 fusion protein and plays an important role in fusing viral and target cell membranes which is a critical step in viral infection. Unlike HFP, HFPK3 is monomeric in detergent-free buffered aqueous solution which may be a useful property for functional and structural studies. H alpha chemical shifts indicated that DPC-associated HFPK3 was predominantly helical from I4 to L12. In addition to the highest-intensity crosspeaks used for the first chemical shift assignment (denoted I), there were additional crosspeaks whose intensities were approximately 10% of those used for assignment I. A second assignment (II) for residues G5 to L12 as well as a few other residues was derived from these lower-intensity crosspeaks. Relative to the I shifts, the II shifts were different by 0.01-0.23 ppm with the largest differences observed for HN. Comparison of the shifts of DPC-associated HFPK3 with those of detergent-associated HFP and HFP derivatives provided information about peptide structures and locations in micelles.

Probing the structure of the Ff bacteriophage major coat protein transmembrane helix dimer by solution NMR

The transmembrane (TM) segment of the major coat protein from Ff bacteriophage has been extensively studied as an example of dimerization in detergent and lipid bilayer systems. However, almost all the information regarding this interaction has been gained through mutagenesis studies, with little direct structural information being available. To this end solution NMR has the potential to provide new insights into structure of the dimer. In order to evaluate the utility of this approach we have studied a selectively 15N-labeled peptide containing the TM segment of MCP (MCPTM) by solution NMR. This peptide was found to give rise to detergent concentration-dependent spectra that were assigned to monomeric and dimeric forms. The standard free energy of this interaction in SDS was estimated from these spectra and found to be consistent with weak but specific dimerization. In addition, similar spectra could be obtained in beta-octyl glucoside with intermolecular paramagnetic relaxation experiments demonstrating a parallel arrangement of TM helices in the dimer. In both detergents backbone chemical shift differences between monomeric and dimeric forms of MCPTM showed that the largest changes occur around its GXXXG motif. The resulting structural model is consistent with observations made for MCP mutants previously characterized in biological membranes, opening the door to detailed structural characterization of this form of MCP. These results also have general implications for the study of weakly interacting TM segments by solution NMR since the use of similar sample conditions should allow structural data to be accessed for oligomeric states from a wide range systems that undergo biologically relevant but weak associations in the membrane.

Anchoring mechanisms of membrane-associated M13 major coat protein

Bacteriophage M13 major coat protein is extensively used as a biophysical, biochemical, and molecular biology reference system for studying membrane proteins. The protein has several elements that control its position and orientation in a lipid bilayer. The N-terminus is dominated by the presence of negatively charged amino acid residues (Glu2, Asp4, and Asp5), which will always try to extend into the aqueous phase and therefore act as a hydrophilic anchor. The amphipathic and the hydrophobic transmembrane part contain the most important hydrophobic anchoring elements. In addition there are specific aromatic and charged amino acid residues in these domains (Phe 11, Tyr21, Tyr24, Trp26, Phe42, Phe45, Lys40, Lys43, and Lys44) that fine-tune the association of the protein to the lipid bilayer. The interfacial Tyr residues are important recognition elements for precise protein positioning, a function that cannot be performed optimally by residues with an aliphatic character. The Trp26 anchor is not very strong: depending on the context, the tryptophan residue may move in or out of the membrane. On the other hand, Lys residues and Phe residues at the C-terminus of the protein act in a unique concerted action to strongly anchor the protein in the lipid bilayer.

Expression and characterization of N-terminal domain of Epstein-Barr virus latent membrane protein 2A in Escherichia coli

Latency of Epstein-Barr virus (EBV) is maintained by the transmembrane protein latent membrane protein (LMP) 2A, which mimics the B-cell receptor (BCR) and perturbs BCR signaling. LMP2A contains a cytoplasmic N-terminal domain composed of 119 amino acids, which provides signals that are responsible for the association with various signal molecules, resulting in negative regulation of B-cell signaling and the EBV lytic cycle. In the present study, to obtain N-terminal domain of LMP2A (LMP2A NTD, 13 kDa) in Escherichia coli for structural analysis, a strategy for obtaining the unfused form of LMP2A NTD without any fusion partners was proposed. Recombinant LMP2A NTD has previously been expressed using the GST fusion system in E. coli [Virology 268 (2000) 178, J. Virol. 71 (1997) 4752, Mol. Cell. Biol. 20 (2000) 8526]. However, we were unable to obtain untagged LMP2A NTD from this construct because of rapid proteolysis by thrombin. To overcome the proteolysis by thrombin, C-terminal His-tagged LMP2A NTD and intein-fused LMP2A NTD were prepared. As a result, LMP2A NTD without a fusion partner could be successfully obtained using non-enzymatic cleavage. The secondary structure of the recombinant LMP2A NTD was analyzed using circular dichroism. In aqueous solution, LMP2A NTD adopts an unordered structure, which was not affected by varying pH and salt concentration. In addition, any secondary structural components of LMP2A NTD were not induced in the membrane-mimicking environments, suggesting that LMP2A NTD may intrinsically have a random coil-like structure. The biological activity of recombinant LMP2A NTD was monitored by chemical shift perturbation in HSQC spectra of LMP2A NTD with or without WW domains, which result supports that the structural change induced by WW domains is restricted within narrow region.

Structure of the coat protein in fd filamentous bacteriophage particles determined by solid-state NMR spectroscopy

The atomic resolution structure of fd coat protein determined by solid-state NMR spectroscopy of magnetically aligned filamentous bacteriophage particles differs from that previously determined by x-ray fiber diffraction. Most notably, the 50-residue protein is not a single curved helix, but rather is a nearly ideal straight helix between residues 7 and 38, where there is a distinct kink, and then a straight helix with a different orientation between residues 39 and 49. Residues 1-5 have been shown to be mobile and unstructured, and proline 6 terminates the helix. The structure of the coat protein in virus particles, in combination with the structure of the membrane-bound form of the same protein in bilayers, also recently determined by solid-state NMR spectroscopy, provides insight into the viral assembly process. In addition to their roles in molecular biology and biotechnology, the filamentous bacteriophages continue to serve as model systems for the development of experimental methods for determining the structures of proteins in biological supramolecular assemblies. New NMR results include the complete sequential assignment of the two-dimensional polarization inversion spin-exchange at the magic angle spectrum of a uniformly 15N-labeled 50-residue protein in a 1.6 x 107 Da particle in solution, and the calculation of the three-dimensional structure of the protein from orientational restraints with an accuracy equivalent to an rms deviation of approximately 1A.

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.

Protein-lipid interactions of bacteriophage M13 major coat protein

During the past years, remarkable progress has been made in our understanding of the replication cycle of bacteriophage M13 and the molecular details that enable phage proteins to navigate in the complex environment of the host cell. With new developments in molecular membrane biology in combination with spectroscopic techniques, we are now in a position to ask how phages carry out this delicate process on a molecular level, and what sort of protein-lipid and protein-protein interactions are involved. In this review we will focus on the molecular details of the protein-protein and protein-lipid interactions of the major coat protein (gp8) that may play a role during the infection of Escherichia coli by bacteriophage M13.

Simultaneous assignment and structure determination of a membrane protein from NMR orientational restraints

A solid-state NMR approach for simultaneous resonance assignment and three-dimensional structure determination of a membrane protein in lipid bilayers is described. The approach is based on the scattering, hence the descriptor "shotgun," of (15)N-labeled amino acids throughout the protein sequence (and the resulting NMR spectra). The samples are obtained by protein expression in bacteria grown on media in which one type of amino acid is labeled and the others are not. Shotgun NMR short-circuits the laborious and time-consuming process of obtaining complete sequential assignments prior to the calculation of a protein structure from the NMR data by taking advantage of the orientational information inherent to the spectra of aligned proteins. As a result, it is possible to simultaneously assign resonances and measure orientational restraints for structure determination. A total of five two-dimensional (1)H/(15)N PISEMA (polarization inversion spin exchange at the magic angle) spectra, from one uniformly and four selectively (15)N-labeled samples, were sufficient to determine the structure of the membrane-bound form of the 50-residue major pVIII coat protein of fd filamentous bacteriophage. Pisa (polarity index slat angle) wheels are an essential element in the process, which starts with the simultaneous assignment of resonances and the assembly of isolated polypeptide segments, and culminates in the complete three-dimensional structure of the protein with atomic resolution. The principles are also applicable to weakly aligned proteins studied by solution NMR spectroscopy. [The structure we determined for the membrane-bound form of the Fd bacteriophage pVIII coat protein has been deposited in the Protein Data Bank as PDB file 1MZT.]

Effect of tandem rare codon substitution and vector-host combinations on the expression of the EBV gp110 C-terminal domain in Escherichia coli

Gp110 of Epstein-Barr virus (EBV) is a glycoprotein that functions exclusively during the assembly of EBV nucleocapsid and the release of infectious EBV. Its C-terminal tail domain (gp110 CTD) is essential for gp110's function and may provide signals that are responsible for the assembly and release of EBV. In the present study, to get large amounts of gp110 CTD for structural analysis, the effects of vector system, codon usage, and host strain on expression levels of gp110 CTD in Escherichia coli have been investigated. The coding region of gp110 CTD (11 kDa) was subcloned into the expression vectors pSE 280, pET-15b, pET-29a, pMAL-c2x, and pGEX-4T-1. Except the pMAL-c2x construct, all the others failed to express detectable amounts of recombinant gp110 CTD. Substituting a tandem rare AGA (Arg) codon with a synonymous CGC (Arg) codon facilitated expression of the recombinant protein, while a protease-deficient host E. coli strain helped in the accumulation of a soluble form of gp110 CTD fusion. The secondary structures of the obtained recombinant gp110 CTD purified from soluble extracts and inclusion bodies were compared using circular dichroism analysis. In aqueous solutions, both samples equally adopt a mixed alpha-helix and beta-sheet conformation as well as a partly unordered structure. Notably, in the membrane-mimicking environments the helical propensity of gp110 CTD increased up to the previously predicted level based on its sequence, suggesting that gp110 CTD may fold into a more stable conformation through interactions with the cell membrane.

Transmembrane domain mediated self-assembly of major coat protein subunits from Ff bacteriophage

The 50-residue major coat protein (MCP) of Ff bacteriophage exists as a single-spanning membrane protein in the Escherichia coli host inner membrane prior to assembly into lipid-free virions. Here, the molecular bases for the specificity and stoichiometry that govern the protein-protein interactions of MCP in the host membrane are investigated in detergent micelles. To address these structural issues, as well as to circumvent viability requirements in mutants of the intact protein, peptides corresponding to the effective alpha-helical TM segment of wild-type and mutant bacteriophage MCPs were synthesized. Fluorescence resonance energy transfer (FRET) experiments on the dansyl and dabcyl-labeled MCP TM domain peptides in detergent micelles demonstrated that the peptides specifically associate into non-covalent homodimers, as postulated for the biologically relevant membrane-embedded MCP oligomer. MCP peptides labeled with short-range pyrene fluorophores at the N terminus displayed excimer fluorescence consistent with homodimerization occurring in a parallel fashion. Variant peptides synthesized with single substitutions at helix-interactive positions displayed a wide range of dimer/monomer ratios on SDS-PAGE gels, which are interpreted in terms of steric volume, presence or absence of beta-branching, and the effect of polar substituents. The overall results indicate discrete roles for helix-helix interfacial residues as packing recognition elements in the membrane-inserted state, and suggest a possible correlation between phage viability and efficacy of MCP TM-TM interactions.

Structure determination of membrane-associated proteins from nuclear magnetic resonance data

This Review covers the delineation and optimization of protein-lipid systems for study using solution-state NMR spectroscopy. The first half presents the necessary background for a membrane protein biochemist to initiate collaboration with an NMR spectroscopist. The second half provides guidelines for the spectroscopist on data collection, analysis for obtaining conformational information, and structure generation and assessment. Although the emphasis is on the study of peptides in detergent micelles, methods are outlined for larger membrane-associated proteins and for use of other solubilizing agents.

Structural characterization of peptide hormone/receptor interactions by NMR spectroscopy

The structural characterization of peptide hormones and their interaction with G-protein (guanine nucleotide-binding regulatory protein) coupled receptors by high-resolution nmr is described. The general approaches utilized can be categorized into three different classes based on their target: the ligand, the receptor, and the ligand/receptor complex. Examples of these different approaches, aimed at facilitating the rational design of peptides and peptidomimetics with improved pharmacological profiles, based on work carried out in our own laboratory, are given. In the ligand-based approach, the high-resolution structures of bradykinin analogues allowing for the development of a structure-activity relationship for activation of the B1 receptor are described. Studies targeting the receptor are to a large extent theoretical, based on computational molecular modeling. However, experimentally based structural features provided by high-resolution nmr can be used to great advantage, providing insight into the mechanism of receptor function, as illustrated here with results from parathyroid hormone. A similar combination of theoretical methods, supplemented by high-resolution structures from nmr has been utilized to probe the formation and stabilization of the ligand/receptor complex both for parathyroid hormone and cholecystokinin. In each of these three approaches, the importance of well-designed peptide mimetics and accurate structural analysis by high-resolution nmr, will be highlighted.

Conformational characterization of a peptide mimetic of the third cytoplasmic loop of the G-protein coupled parathyroid hormone/parathyroid hormone related protein receptor

The third-cytoplasmic loop of the G-protein coupled receptor responsible for the activity of parathyroid hormone and parathyroid hormone-related protein has been structurally characterized in aqueous solution in the presence of sodium dodecylsulfate and dodecylphosphocholine micelles. The high-resolution conformation of the 29-amino acid peptide containing the sequence of the cytoplasmic loop was obtained by CD and nmr. The structure was refined using a two-step distance geometry based method that first includes the removal of all side chains to quickly locate the globular fold of the peptide. After a simulated annealing protocol, the side chains are added in a random fashion. The resulting conformation was further refined with nuclear Overhauser enhancement restrained molecular dynamics using a two-phase simulation cell consisting of carbon tetrachloride and water as a mimetic of the biphasic, hydrophobic/hydrophilic character of the micelles in which the experimental measurements were carried out. The topological orientation of the cycloplasmic loop within the micelle was determined by addition of 5-doxylstearate and monitoring the decrease of nmr signal intensities from the radical-induced relaxation. The conformation and relative orientation of the peptide provided insight into the mechanism by which the cytoplasmic portion of the receptor activates the heterotrimeric, guanine nucleotide-binding regulatory protein, one of the first steps in signal transduction.

Effects of temperature and Y21M mutation on conformational heterogeneity of the major coat protein (pVIII) of filamentous bacteriophage fd

Solid-state NMR spectroscopy was used to analyze the conformational heterogeneity of the major coat protein (pVIII) of filamentous bacteriophage fd. Both one and two-dimensional solid-state NMR spectra of magnetically aligned samples of fd bacteriophage reveal that an increase in temperature and a single site substitution (Tyr21 to Met, Y21M) reduce the conformational heterogeneity observed throughout wild-type pVIII. The NMR results are consistent with previous studies indicating that conformational flexibility in the hinge-bend segment that links the amphipathic and hydrophobic helices in the membrane-bound form of the protein plays an essential role during phage assembly, which involves a major change in the tertiary, but not secondary, structure of the coat protein.

NMR structural studies of membrane proteins

The three-dimensional structures of membrane proteins are essential for understanding their functions, interactions and architectures. Their requirement for lipids has hampered structure determination by conventional approaches. With optimized samples, it is possible to apply solution NMR methods to small membrane proteins in micelles; however, lipid bilayers are the definitive environment for membrane proteins and this requires solid-state NMR methods. Newly developed solid-state NMR experiments enable completely resolved spectra to be obtained from uniformly isotopically labeled membrane proteins in phospholipid lipid bilayers. The resulting operational constraints can be used for the determination of the structures of membrane proteins.

Solution structure of the M13 major coat protein in detergent micelles: a basis for a model of phage assembly involving specific residues

The three-dimensional structure of the major coat protein of bacteriophage M13, solubilized in detergent micelles, has been determined using heteronuclear multidimensional NMR and restrained molecular dynamics. The protein consists of two alpha-helices, running from residues 8 to 16 and 25 to 45, respectively. These two helices are connected by a flexible and distorted helical hinge region. The structural properties of the coat protein make it resemble a flail, in which the hydrophobic helix (residues 25 to 45) is the handle and the other, amphipathic, helix the swingle. In this metaphor, the hinge region is the connecting piece of leather. The mobility of the residues in the hinge region is likely to enable a smooth transformation from the membrane-bound form, mimicked by the structure in detergent micelles, into the structure in the mature phage. A specific distribution of the residues over the surface of the two helices was observed in the presented high-resolution structure of the membrane-bound form of the major coat protein as well as in the structure in the mature phage. All data suggest that this arrangement of residues is important for the interactions of the protein with the membrane, for correct protein-DNA and protein-protein interactions in the phage and for a proper growth of the phage during the assembly process. By combining our findings with earlier NMR results on the major coat protein in detergent micelles, we were able to construct a model that addresses the role of specific residues in the assembly process.

Expression, purification, and characterization of Sss1p, an essential component of the yeast Sec61p protein translocation complex

Sss1p, a 8.9-kDa membrane protein, is an essential component of the protein translocation complex involved in the transport of secretory proteins across the Saccharomyces cerevisiae endoplasmic reticulum membrane. In order to determine the high resolution structure of Sss1p by NMR, we have undertaken its overexpression and purification. We first inserted the yeast SSS1 gene into the pGEX-2T plasmid expression vector. Sss1p was expressed as fusions with Schistosoma japonica glutathione S-transferase (GST-Sss1p) in MC1061 Escherichia coli cells. Maximum yield of GST-Sss1p was obtained from cells harvested 2 h after induction at 37 degreesC in Luria broth medium. GST-Sss1p was found associated predominantly with the membrane pool and was readily extracted with Triton X-100. Detergent-solubilized GST-Sss1p was isolated by adsorption on glutathione-agarose beads. Sss1p was released from its GST carrier by cleavage with thrombin and its recovery was maximized by addition of dodecyl maltoside. Desorbed Sss1p was loaded on a high-performance liquid chromatography hydroxyapatite column equilibrated in phosphate buffer supplemented with dodecyl maltoside and the fractions containing Sss1p were subsequently purified to homogeneity by reverse-phase chromatography on a C4 column. The entire purification protocol can be completed in 5-6 h and yields about 0.4 mg of Sss1p per gram of transformed cells. CD and preliminary 1H NMR experiments show that purified Sss1p solubilized in SDS micelles is very stable and adopts a helical secondary structure.

Magic angle-oriented sample spinning (MAOSS): A new approach toward biomembrane studies

The application of magic angle sample spinning (MAS) NMR to uniformly aligned biomembrane samples is demonstrated as a new general approach toward structural studies of membrane proteins, peptides, and lipids. The spectral linewidth from a multilamellar lipid dispersion is dominated, in the case of protons, by the dipolar coupling. For low-gamma or dilute spins, however, the chemical shift anisotropy dominates the spectral linewidth, which is reduced by the two-dimensional order in a uniformly aligned lipid membrane. The remaining line broadening, which is due to orientational defects ("mosaic spread") can be easily removed at low spinning speeds. This orientational order in the sample also allows the anisotropic intermolecular motions of membrane components (such as rotational diffusion, tauc = 10(-10) s) for averaging dipolar interactions to be utilized, e.g., by placing the membrane normal parallel to the rotor axis. The dramatic resolution improvement for protons which are achieved in a lipid sample at only 220 Hz spinning speed in a 9.4 T field is slightly better than any data published to date using ultra-high fields (up to 17.6 T) and high-speed spinning (14 kHz). Additionally, the analysis of spinning sidebands provides valuable orientational information. We present the first 1H, 31P, and 13C MAS spectra of uniformly aligned dimyristoylphosphatidylcholine (DMPC) bilayers. Also, 1H resolution enhancement for the aromatic region of the M13 coat protein reconstituted into DMPC bilayers is presented. This new method combines the high resolution usually achieved by MAS with the advantages of orientational constraints obtained by working with macroscopically oriented samples. We describe the general potential and possible perspectives of this technique.

Complete resolution of the solid-state NMR spectrum of a uniformly 15N-labeled membrane protein in phospholipid bilayers

Complete resolution of the amide resonances in a three-dimensional solid-state NMR correlation spectrum of a uniformly 15N-labeled membrane protein in oriented phospholipid bilayers is demonstrated. The three orientationally dependent frequencies, 1H chemical shift, 1H-15N dipolar coupling, and 15N chemical shift, associated with each amide resonance are responsible for resolution among resonances and provide sufficient angular restrictions for protein structure determination. Because the protein is completely immobilized by the phospholipids on the relevant NMR time scales (10 kHz), the linewidths will not degrade in the spectra of larger proteins. Therefore, these results demonstrate that solid-state NMR experiments can overcome the correlation time problem and extend the range of proteins that can have their structures determined by NMR spectroscopy to include uniformly 15N-labeled membrane proteins in phospholipid bilayers.

fd coat protein structure in membrane environments: structural dynamics of the loop between the hydrophobic trans-membrane helix and the amphipathic in-plane helix

By performing multidimensional solution NMR experiments on micelle samples it was possible to determine the structure of the membrane-bound form of fd coat protein based on short-range distance and dihedral angle constraints using distance geometry and simulated annealing calculations. Its dynamics were described by 15N relaxation measurements (T1, T2, heteronuclear nuclear Overhauser enhancement (NOE)) fitted with the Lipari-Szabo model-free formalism adapted for the transmembrane and in-plane helices of a membrane protein. The overall correlation time of the protein in micelles was found to be approximately 9 ns, and the local motion of each backbone N-H vector was described by an order parameter and an effective correlation time. The 50 residue protein has an amphipathic alpha-helix (residues 7 to 16) and a hydrophobic alpha-helix (residues 27 to 44), which were found to be approximately perpendicular on the basis of NOEs in the residues that connect the two helices. The residues connecting the helices are of particular interest in membrane proteins, and in this case the loop consists of two turns. The relaxation data show the presence of an extra motion in the amphipathic alpha-helix on the nanosecond timescale and additional flexibility of several residues in the loop connecting the two helices.

Conventional and saturation-transfer EPR of spin-labeled mutant bacteriophage M13 coat protein in phospholipid bilayers

A mutant of bacteriophage M13 was prepared in which a cysteine residue was introduced at position 25 of the major coat protein. The mutant coat protein was spin-labeled with a nitroxide derivative of maleimide and incorporated at different lipid-to-protein (L/P) ratios in DOPC or DOPG. The rotational dynamics of the reconstituted mutant coat protein was studied using EPR and saturation transfer (ST) EPR techniques. The spectra are indicative for an anisotropic motion of the maleimide spin label with a high order parameter (S = 0.94). This is interpreted as a wobbling motion of the spin label with a correlation time of about 10(-6) to 10(-5) s within a cone, and a rotation of the spin label about its long molecular axis with a correlation time of about l0(-7) s. The wobbling motion is found to correspond generally to the overall rotational motion of a coat protein monomer about the normal to the bilayer. This motion is found to be sensitive to the temperature and L/P ratio. The high value of the order parameter implies that the spin label experiences a strong squeezing effect by its local environment, that reduces the amplitude of the wobbling motion. This squeezing effect is suggested to arise from a turn structure in the coat protein from Gly23 to Glu20.

NMR structure of the principal neutralizing determinant of HIV-1 displayed in filamentous bacteriophage coat protein

An NMR approach for structure determination of short peptides displayed on the surface of filamentous bacteriophage virions is demonstrated using the hexapeptide GPGRAF that constitutes the principal neutralizing determinant of HIV-1. This peptide was inserted near the N terminus of the major coat protein of bacteriophage fd. NMR studies of the recombinant protein solubilized in detergent micelles showed that the inserted peptide adopts a double bend S-shaped conformation that is similar to the antibody-bound structure determined by X-ray crystallography. This indicates that a peptide displayed on the bacteriophage coat protein has an enhanced propensity to adopt a conformation similar to that found in the native protein from which it is derived. This approach may be generally applicable to the structure determination of peptide epitopes and other small peptides.

High resolution 1H nuclear magnetic resonance of a transmembrane peptide

Although the strong 1H-1H dipolar interaction is known to result in severe homogeneous broadening of the 1H nuclear magnetic resonance (NMR) spectra of ordered systems, in the fluid phase of biological and model membranes the rapid, axially symmetric reorientation of the molecules about the local bilayer normal projects the dipolar interaction onto the motional symmetry axis. Because the linewidth then scales as (3 cos2 theta-1)/2, where theta is the angle between the local bilayer normal and the magnetic field, the dipolar broadening has been reduced to an "inhomogeneous" broadening by the rapid axial reorientation. It is then possible to obtain high resolution 1H-NMR spectra of membrane components by using magic angle spinning (MAS). Although the rapid axial reorientation effectively eliminates the homogeneous dipolar broadening, including that due to n = 0 rotational resonances, the linewidths observed in both lipids and peptides are dominated by low frequency motions. For small peptides the most likely slow motions are either a "wobble" or reorientation of the molecular diffusion axis relative to the local bilayer normal, or the reorientation of the local bilayer normal itself through surface undulations or lateral diffusion over the curved surface. These motions render the peptide 1H-NMR lines too broad to be observed at low spinning speeds. However, the linewidths due to these slow motions are very sensitive to spinning rate, so that at higher speeds the lines become readily visible. The synthetic amphiphilic peptide K2GL20K2A-amide (peptide-20) has been incorporated into bilayers of 1,2-di-d 27-myristoyl-sn-glycero-3-phosphocholine (DMPC-d54) and studied by high speed 1H-MAS-NMR. The linewidths observed for this transbilayer peptide, although too broad to be observable at spinning rates below -5 kHz, are reduced to 68 Hz at a spinning speed of 14 kHz (at 500C). Further improvements in spinning speed and modifications in sample composition designed to reduce the effectiveness of the slow motions responsible for the linewidth should result in significant further reduction in peptide linewidths. With this technique, there is now the potential for the use of 1H-MAS-NMR for the study of conformation, folding, and dynamics of small membrane peptides and protein fragments.

NMR studies of the major coat protein of bacteriophage M13. Structural information of gVIIIp in dodecylphosphocholine micelles

The membrane-bound form of the major coat protein (gVIIIp) of bacteriophage M13 has been studied using nuclear magnetic resonance spectroscopy. As membrane mimetics, we used dodecylphosphocholine (DodPCho) detergent micelles to solubilize the protein. We were able to nearly completely assign all resonances of the protein solubilized in DodPCho micelles by using both homonuclear and heteronuclear multidimensional experiments. Based on the patterns of the nuclear Overhauser enhancements and the chemical shifts of the resonances, we deduced the secondary structure of the protein. Additional structural information was obtained from amide proton exchange data and J-coupling constants. The protein consists of two alpha-helices which are connected by a hinge region around residue 21. From spin-label experiments, the location of the protein relative to the DodPCho micelles was determined. One, hydrophobic, helix spans the micelle, and another, amphipathic, helix, is located beneath the surface of the micelle. Comparison of the data of gVIIIp in DodPCho micelles with those of gVIIIp in sodium dodecyl sulfate (SDS) micelles [Van de Ven, F. J. M., van Os, J. W. M., Aelen, J. M. A., Wymenga, S. S., Remerowski, M. L., Konings, R. N. H. & Hilbers, C. W. (1993) Biochemistry 32, 8322-8328; Papavoine, C. H. M., Konings, R. N. H., Hilbers, C. W. & Van de Ven, F. J. M. (1994) Biochemistry 33, 12,990-12,997] reveals that the structures of the protein in the two detergent micelles are very similar. They differ only in the arrangement of the detergent molecules around the protein. For gVIIIp in SDS micelles, we found a micellar structure which is distorted near the C-terminus of the protein; whereas for DodPCho micelles, both distorted and regular elliptical micelles occur. This distortion is probably due to the interaction of the positively charged lysine side chains with the negatively charged head group of the detergent molecules.

FT-IR spectroscopy of the major coat protein of M13 and Pf1 in the phage and reconstituted into phospholipid systems

FT-IR spectroscopy has been applied to study the secondary structure of the major coat protein of Pf1 and M13 as present in the phage and reconstituted in DOPG and mixed DOPC/DOPG (4/1) bilayers. Infrared absorbance spectra of the samples were examined in dehydrated films and in suspensions of D2O and H2O. The secondary structure of the coat protein is investigated by second-derivative analysis, Fourier self-deconvolution, and curve fitting of the infrared bands in the amide I region (1600-1700 cm-1). It is found that, in dehydrated films of Pf1 and M13 phage, the amide I region contains three bands located at about 1633, 1657, and 1683 cm-1, that are assigned to hydrogen-bonded turn, alpha-helix/random coil, and non-hydrogen-bonded turn, respectively. From a comparison of the infrared spectra in dehydrated film with those in aqueous suspension, the percentages of secondary structure were found with an accuracy of about +/- 5%. For the coat protein of Pf1 phage, the FT-IR quantification gives 69% alpha-helix conformation, 19% turn structure, and 12% random coil structure. For Pf1 coat protein in the membrane-embedded state, the amount of alpha-helix is 57%, whereas 42% is in a turn structure and 1% in a random coil structure. The same assignment strategy was used for the analysis of the data obtained for M13 coat protein reconstitution into phospholipid systems. For M13 coat protein in the phage, this gives 75% alpha-helix conformation, 21% turn structure, and 4% random coil structure.(ABSTRACT TRUNCATED AT 250 WORDS)

13C NMR studies of wheat germ agglutinin interactions with N-acetylglucosamine at a magnetically oriented bilayer surface

The orientation of synthetic 13C-labeled glycolipid receptors and their interaction with the plant lectin wheat germ agglutinin have been studied in an oriented membrane system using NMR spectroscopy. A series of 2-[1,2-13C2]acetamido-2-deoxy-beta-D-glucopyranosides were synthesized with between zero and four hydrophilic ethoxy units between the headgroup and an alkyl chain which anchors the receptors in the bilayers. The chemical shift anisotropy of the 13C carbonyl and a 13C-13C dipolar coupling between the labeled carbons provide information about the orientation and dynamics of the receptor headgroup in oriented membrane systems. It was found that the headgroups of the receptors with two, three, or four ethoxy units appeared isotropic when incorporated in the oriented bilayers, but those of the receptors with zero or one ethoxy units were significantly ordered by the bilayers. The average orientations consistent with measured spectral parameters were determined for the receptors with zero and one ethoxy units and were found to coincide with low-energy conformations from molecular modeling. When the plant lectin wheat germ agglutinin was added to the sample, only the receptors with two, three, or four ethoxy units separating the headgroup from the alkyl chain showed evidence of binding by the lectin. Although the 13C-labeled resonances broadened when the protein bound, no changes in dipolar couplings or chemical shift anisotropies could be detected, suggesting that the motion of the headgroup was slowed by protein binding, but average orientation and overall order changed little. Competition studies demonstrated that none of the lectin/receptor complexes are more stable than the complex of the lectin and N-acetylglucosamine in solution. These results suggest that the membrane does not stabilize the interactions of wheat germ agglutinin with these cell-surface receptors. Furthermore, molecular modeling demonstrates that the zero- and one-spacer receptors may not bind wheat germ agglutinin because the orientations of the N-acetyl groups in these receptors would result in significant steric contacts between the lectin/receptor complex and the membrane.

Specificity and promiscuity in membrane helix interactions

The membrane-spanning portions of many integral membrane proteins consist of one or a number of transmembrane α-helices, which are expected to be independently stable on thermodynamic grounds. Side-by-side interactions between these transmembrane α-helices are important in the folding and assembly of such integral membrane proteins and their complexes. In considering the contribution of these helix–helix interactions to membrane protein folding and oligomerization, a distinction between the energetics and specificity should be recognized. A number of contributions to the energetics of transmembrane helix association within the lipid bilayer will be relatively non-specific, including those resulting from charge–charge interactions and lipid–packing effects. Specificity (and part of the energy) in transmembrane α-helix association, however, appears to rely mainly upon a detailed stereochemical fit between sets of dynamically accessible states of particular helices. In some cases, these interactions are mediated in part by prosthetic groups.

Backbone dynamics of (1-71)bacterioopsin studied by two-dimensional 1H-15N NMR spectroscopy

The backbone dynamics of a uniformly 15N-labelled proteolytic fragment (residues 1-71) of bacteriorhodopsin, solubilized in two media [methanol/chloroform (1:1), 0.1 M 2HCO2NH4 and SDS micelles] have been investigated using two-dimensional proton-detected heteronuclear 1H-15N NMR spectroscopy. A set of longitudinal and transverse relaxation rates of 15N nuclei and 1H-15N NOE were obtained for 61 backbone amide groups. The contribution of the conformational exchange to transverse relaxation rates of individual nitrogens was elucidated using a set of different rates of the Carr-Purcell-Meiboom-Gill (CPMG) spin-lock pulse train. We found that most of the backbone amide groups are involved in the co-operative exchange process over the rate range 10(3)-10(4) s-1, with the chemical-shift dispersion near 1 ppm. Contributions of conformational exchange to the measured transverse relaxation were essentially suppressed by the 3-kHz (spin-echo period tau = 0.083 ms) CPMG spin-lock. Under these conditions, the measured longitudinal, transverse relaxation rates and NOE values were interpreted using the model-free approach of Lipari and Szabo [Lipari, G. & Szabo, A. (1982) J. Am. Chem. Soc. 104, 4546-4559]. In both media used, the protein exhibits very similar dynamic properties, and has overall rotational correlation times of 7.0 ns and 6.6 ns in organic mixture and in SDS micelles, respectively. In addition to overall rotation of the molecule, the backbone N-H vectors are involved in two types of internal motions; fast, on a time scale of < 20 ps, and intermediate, close to 1 ns. Distinctly mobile regions are identified by a large decrease in the overall order parameter and correspond to N-terminal residues (residues 1-7 both for organic solvent and micelles), C-terminal residues (residues 65-71 and 69-71 for organic solvent and micelles, respectively) and residues connecting alpha helices (residues 33-41 and 33-38, for organic solvent and micelles, respectively). A decrease in the order parameter was also observed for residues next to Pro50, indicating a higher flexibility in this region. Thus, backbone dynamic parameters of (1-71)bacterioopsin are in good correspondence with its spatial structure [Pervushin, K. V., Orekhov, V. Yu., Popov, A., Musina, L. Yu., Arseniev, A. S., (1994) Eur. J. Biochem., in the press]. The observed conformational exchange behavior of alpha helices seems to be induced by the flickering helix-helix interaction and could be important for the functioning of bacteriorhodopsin.

Methods to study membrane protein structure in solution

Membrane protein structure is difficult to determine by any technique. NMR spectroscopy of membrane proteins in solution can proceed using methods identical to those that have been successfully applied to numerous water-soluble proteins providing suitable solubilization conditions can be found. Organic solvents and small detergent micelles have correlation times short enough for structure determination based on 1H NOEs. Although it is difficult to generalize as each system is unique, organic solvents and micelles of strong detergents such as SDS are useful for amphiphilic peptides and small membrane proteins, whereas larger proteins need milder treatment to preserve the tertiary structure. Small unilamellar phospholipid vesicles are much too large for NOE-based structure determination, but they still fall under the domain of solution-state NMR and can be useful in certain circumstances.

Secondary structure of M13 coat protein in phospholipids studied by circular dichroism, Raman, and Fourier transform infrared spectroscopy

There is considerable uncertainty about the precise secondary structure adopted by the M13 coat protein when embedded in a phospholipid bilayer. Circular dichroism (CD) spectroscopy suggests that a major change in the structure of the coat protein occurs upon membrane insertion. It is reported that the structure of the protein in the membrane has only about 50% alpha-helix, the rest being mainly in a beta-sheet conformation, whereas the protein is almost completely alpha-helical when intact in the phage. In this study we have undertaken a spectroscopic analysis using Fourier transform infrared, Raman, and CD spectroscopy to characterize the secondary structure of M13 coat protein when present in membranes consisting of dioleoylphosphatidylglycerol and dimyristoylphosphatidylglycerol. In sharp contrast to earlier CD studies, our results indicate that the coat protein in its membrane-embedded state has a very high alpha-helical content with virtually no beta-sheet structures present. This result indicates that the structures of the coat protein when intact in the phage or when embedded in the membrane are similar. Although our results differ from earlier CD studies, they are consistent with a recent NMR study, which showed that the M13 coat protein in sodium dodecyl sulfate micelles is primarily alpha-helical with no evidence for beta-sheet structure [Henry, G. D., & Sykes, B.D. (1992) Biochemistry 31, 5284-5297]. These results lead to the conclusion that the M13 coat protein can insert from the membrane-bound state into a virus particle with a similar secondary structure, without large energy implications.(ABSTRACT TRUNCATED AT 250 WORDS)

The macroscopic organization of reconstituted M13 coat protein-phospholipid systems. An EPR spectroscopy and polarizing microscope study

The coat protein of the bacteriophage M13 in the alpha-helical state is reconstituted in macroscopically oriented systems of dioleoylphosphatidylcholine that are prepared by squeezing the reconstituted material between glass plates. The coat protein dramatically influences the macroscopic orientation of the multibilayers, as is investigated by polarizing microscopy and EPR spectroscopy of the cholestane spin label embedded in the bilayers. It is found that with increasing amounts of protein the spontaneous macroscopic orientation of the reconstituted system decreases. This effect is proposed to be due to an increase of the apparent viscosity of the lipid-protein systems with increasing amounts of protein. This is assumed to arise from a sticky effect of the C- and N-terminal protein parts that extend into the aqueous phase between the bilayers.

Evaluation of transmembrane helix prediction methods using the recently defined NMR structures of the coat proteins from bacteriophages M13 and Pf1

Currently, there are a large number of hydropathy scales available to predict the presence of transmembrane segments within integral membrane proteins. These scales and their subsequent numerical manipulations provide an aid in the determination of topology in transmembrane proteins. In order to analyse the accuracy of these procedures to correctly identify the boundaries of a transmembrane segment, 13 methods were applied to the amino-acid sequence of the coat proteins from the bacteriophages Pf1 and M13. These monotopic integral membrane proteins have been incorporated into detergent micelles and their structures have recently been solved using NMR. The predicted regions were then compared to their NMR-determined structures. All methods used were able to detect a transmembrane region within the protein sequence. However, there was considerable differences in their accuracy in determining the boundaries of the main transmembrane alpha-helix. Surprisingly, the methods which worked the best for Pf1 coat protein had poor accuracy in identifying the transmembrane region correctly in the M13 protein. It was concluded that a number of methods should be utilized in order to obtain a clear model of transmembrane protein topology, and that regardless of how closely related two proteins are, a different conclusion may be obtained from different prediction procedures.

Assignment of 1H, 15N, and backbone 13C resonances in detergent-solubilized M13 coat protein via multinuclear multidimensional NMR: a model for the coat protein monomer

The major coat protein (gVIIIp) of bacteriophage M13 complexed with SDS detergent micelles was used as a model system to study the lipid-bound conformation of the protein. Conditions were found that allowed the recording of good quality of NMR spectra. By making extensive use of three-dimensional heteronuclear (13C, 15N) NMR, we obtained a complete set of resonance assignments for 1HN, 1H alpha, 1H beta, 13C alpha, CO, and 15N and partially assigned the rest of the 1H spectrum. Analysis of NOE and chemical shift data reveals that gVIIIp is composed of two alpha-helical domains, one ranging from Pro-6 to Glu20 and the other ranging from Tyr-24 all the way to the C-terminus Ser-50. In contrast to the results reported by Henry and Sykes [Henry, G.D., & Sykes, B.D. (1992) Biochemistry 31, 5285-5297], at a high SDS to protein ratio the protein appears to be monomeric.