Crystal structure of the sensor domain of BaeS from Serratia marcescens FS14

The sensor histidine kinases of two‐component signal‐transduction systems (TCSs) are essential for bacteria to adapt to variable environmental conditions. The two‐component regulatory system BaeS/R increases multidrug and metal resistance in Salmonella and Escherichia coli. In this study, we report the X‐ray structure of the periplasmic sensor domain of BaeS from Serratia marcescens FS14. The BaeS sensor domain (34–160) adopts a mixed α/β‐fold containing a central four‐stranded antiparallel β‐sheet flanked by a long N‐terminal α‐helix and additional loops and a short C‐terminal α‐helix on each side. Structural comparisons revealed that it belongs to the PDC family with a remarkable difference in the orientation of the helix α2. In the BaeS sensor domain, this helix is situated perpendicular to the long helix α1 and holds helix α1 in the middle with the beta sheet, whereas in other PDC domains, helix α2 is parallel to helix α1. Because the helices α1 and α2 is involved in the dimeric interface, this difference implies that BaeS uses a different dimeric interface compared with other PDC domains. Proteins 2017; 85:1784–1790. © 2017 Wiley Periodicals, Inc.     

Spectroscopy-Based Modelling of the 3D Structure of the β Subunit of the High Affinity IgE Receptor

Abstract

The high affinity IgE receptor, possesses a tetrameric structure. The 243 residue β subunit is a polytopic protein with four hydrophobic membrane-spanning segments, whereas the individual α and γ subunits are bitopic proteins each containing one transmembrane domain in their monomeric form. In the proposed topographical model (Blank et al., 1989), the four trans-membrane α helices of the β subunit are connected by three loop sequences.

To study the individual subunits and intact receptor, this membrane protein was divided into domains such as its loop peptides, cytoplasmic peptides and transmembrane helices according to Blank et al., 1989. The 3D structure of the synthesized loop peptides and cytoplasmic peptides were calculated; CD and/or NMR data were used as appropriate to generate the resultant structures which were then used as data basis for the higher level calculations.

The four individual transmembrane helices of the β subunit were characterised, first of all, by mapping the relative lipophilicity of their surfaces using lipophilic probes. A second procedure, docking of the individual helices in pairs, was used to predict helix–helix interactions.

The data on the relative lipophilicity of the surfaces as well as the surfaces that favoured helix–helix interactions were used in combination with the spectroscopy-based structures of the loops and cytoplasmic domains to calculate via molecular dynamics, the helix arrangement and 3D structure of the β subunit of the high affinity IgE receptor. In the final analysis, the molecular simulations yielded two structures of the β subunit, which should form a basis for the modelling of the whole high affinity IgE receptor.     

Design of stable α‐helices using global sequence optimization

The rational design of peptide and protein helices is not only of practical importance for protein engineering but also is a useful approach in attempts to improve our understanding of protein folding. Recent modifications of theoretical models of helix‐coil transitions allow accurate predictions of the helix stability of monomeric peptides in water and provide new possibilities for protein design. We report here a new method for the design of α‐helices in peptides and proteins using AGADIR, the statistical mechanical theory for helix‐coil transitions in monomeric peptides and the tunneling algorithm of global optimization of multidimensional functions for optimization of amino acid sequences. CD measurements of helical content of peptides with optimized sequences indicate that the helical potential of protein amino acids is high enough to allow formation of stable α‐helices in peptides as short as of 10 residues in length. The results show the maximum achievable helix content (HC) of short peptides with fully optimized sequences at 5 °C is expected to be ～70–75%. Under certain conditions the method can be a powerful practical tool for protein engineering. Unlike traditional approaches that are often used to increase protein stability by adding a few favorable interactions to the protein structure, this method deals with all possible sequences of protein helices and selects the best one from them. Copyright © 2009 European Peptide Society and John Wiley & Sons, Ltd.     

Effect of sequence hydrophobicity and bilayer width upon the minimum length required for the formation of transmembrane helices in membranes

The minimum hydrophobic length necessary to form a transmembrane (TM) helix in membranes was investigated using model membrane-inserted hydrophobic helices. The fluorescence of a Trp at the center of the sequence and its sensitivity to quenching were used to ascertain helix position within the membrane. Peptides with hydrophobic cores composed of poly(Leu) were compared to sequences containing a poly 1:1 Leu:Ala core (which have a hydrophobicity typical of natural TM helices). Studies varying bilayer width revealed that the poly(Leu) core peptides predominately formed a TM state when the bilayer width exceeded hydrophobic sequence length by (i.e. when negative mismatch was) up to ∼ 11-12 Å (e.g. the case of a 11-12 residue hydrophobic sequence in bilayers with a biologically relevant width, i.e. dioleoylphosphatidylcholine (DOPC) bilayers), while poly(LeuAla) core peptides formed predominantly TM state with negative mismatch of up to 9 Å (a 13 residue hydrophobic sequence in DOPC bilayers). This indicates that minimum length necessary to form a predominating amount of a TM state (minimum TM length) is only modestly hydrophobicity-dependent for the sequences studied here, and a formula that defines the minimum TM length as a function of hydrophobicity for moderately-to-highly hydrophobic sequences was derived. The minimum length able to form a stable TM helix for alternating LeuAla sequences, and that for sequences with a Leu block followed by an Ala block, was similar, suggesting that a hydrophobicity gradient along the sequence may not be an important factor in TM stability. TM stability was also similar for sequences flanked by different charged ionizable residues (Lys, His, Asp). However, ionizable flanking residues destabilized the TM configuration much more when charged than when uncharged. The ability of short hydrophobic sequences to form TM helices in membranes in the presence of substantial negative mismatch implies that lipid bilayers have a considerable ability to adjust to negative mismatch, and that short TM helices may be more common than generally believed. Factors that modulate the ability of bilayers to adjust to mismatch may strongly affect the configuration of short hydrophobic helices.     

Folding propensities of synthetic peptide fragments covering the entire sequence of phage 434 Cro protein.

The phage 434 Cro protein, the N-terminal domain of its repressor (R1-69) and that of phage lambda (lambda6-85) constitute a group of small, monomeric, single-domain folding units consisting of five helices with striking structural similarity. The intrinsic helix stabilities in lambda6-85 have been correlated to its rapid folding behavior, and a residual hydrophobic cluster found in R1-69 in 7 M urea has been proposed as a folding initiation site. To understand the early events in the folding of 434 Cro, and for comparison with R1-69 and lambda6-85, we examined the conformational behavior of five peptides covering the entire 434 Cro sequence in water, 40% (by volume) TFE/water, and 7 M urea solutions using CD and NMR. Each peptide corresponds to a helix and adjacent residues as identified in the native 434 Cro NMR and crystal structures. All are soluble and monomeric in the solution conditions examined except for the peptide corresponding to the 434 Cro helix 4, which has low water solubility. Helix formation is observed for the 434 Cro helix 1 and helix 2 peptides in water, for all the peptides in 40% TFE and for none in 7 M urea. NMR data indicate that the helix limits in the peptides are similar to those in the native protein helices. The number of side-chain NOEs in water and TFE correlates with the helix content, and essentially none are observed in 7 M urea for any peptide, except that for helix 5, where a hydrophobic cluster may be present. The low intrinsic folding propensities of the five helices could account for the observed stability and folding behavior of 434 Cro and is, at least qualitatively, in accord with the results of the recently described diffusion-collision model incorporating intrinsic helix propensities.     

Flexibility in HIV-1 assembly subunits: solution structure of the monomeric C-terminal domain of the capsid protein

The protein CA forms the mature capsid of human immunodeficiency virus. Hexamerization of the N-terminal domain and dimerization of the C-terminal domain, CAC, occur during capsid assembly, and both domains constitute potential targets for anti-HIV inhibitors. CAC homodimerization occurs mainly through its second helix, and is abolished when its sole tryptophan is mutated to alanine. Previous thermodynamic data obtained with the dimeric and monomeric forms of CAC indicate that the structure of the mutant resembles that of a monomeric intermediate found in the folding and association reactions of CAC. We have solved the three-dimensional structure in aqueous solution of the monomeric mutant. The structure is similar to that of the subunits in the dimeric, nonmutated CAC, except the segment corresponding to the second helix, which is highly dynamic. At the end of this region, the polypeptide chain is bent to bury several hydrophobic residues and, as a consequence, the last two helices are rotated 90 degrees when compared to their position in dimeric CAC. The previously obtained thermodynamic data are consistent with the determined structure of the monomeric mutant. This extraordinary ability of CAC to change its structure may contribute to the different modes of association of CA during HIV assembly, and should be taken into account in the design of new drugs against this virus.     

High-resolution structure of a partially folded insulin aggregation intermediate

Insulin has long been served as a model for protein aggregation, both due to the importance of aggregation in the manufacture of insulin and because the structural biology of insulin has been extensively characterized. Despite intensive study, details about the initial triggers for aggregation have remained elusive at the molecular level. We show here that at acidic pH, the aggregation of insulin is likely initiated by a partially folded monomeric intermediate. High-resolution structures of the partially folded intermediate show that it is coarsely similar to the initial monomeric structure but differs in subtle details—the A chain helices on the receptor interface are more disordered and the B chain helix is displaced from the C-terminal A chain helix when compared to the stable monomer. The result of these movements is the creation of a hydrophobic cavity in the center of the protein that may serve as nucleation site for oligomer formation. Knowledge of this transition may aid in the engineering of insulin variants that retain the favorable pharamacokinetic properties of monomeric insulin but are more resistant to aggregation.     

Conformational analysis of lipid-associating proteins in a lipid environment

Two major types of helical structures have been identified in lipid-associating proteins, being either amphipathic or transmembrane domains. A conformational analysis was carried out to characterize some of the properties of these helices. These calculations were performed both on isolated helices and in a lipid environment. According to the results of this analysis, the orientation of the line joining the hydrophobic and hydrophilic centers of the helix seems to determine the orientation of the helix at the lipid/water interface. The calculation of this parameter should be useful to discriminate between an amphipathic helix, parallel to the interface and a transmembrane helix orientated perpendicularly. The membrane-spanning helices are completely immersed in the phospholipid bilayer and their length corresponds to about the thickness of the hydrophobic core of the DPPC bilayer. The energy of interaction, expressed per phospholipid is significantly higher for the transmembrane compared to the amphipathic helices. For the membrane-spanning helices the mean energy of interaction is higher than the interaction energy between two phospholipids, while it is lower for most amphipathic helices. This might account for the stability of these protein-anchoring domains. This computer modeling approach should usefully complement the statistical analysis carried out on these helices, based on their hydrophobicity and hydrophobic moment. It represents a more refined analysis of the domains identified by the prediction techniques and stress the functional character of lipid-associating domains in membrane proteins as well as in soluble plasma lipoproteins.     

Structural and energetic requirements for a second binding site at the dimeric β-lactoglobulin interface

Through experimental and theoretical approaches, it has been shown that bovine β-lactoglobulin (βlg) uses its hydrophobic cavity or calyx as the primary binding site for hydrophobic molecules, whereas the existence of a second ligand binding site at the dimeric interface has only been structurally identified for vitamin D3 (VD3). This binding exists even in the thermally denatured state, suggesting the prevalence of this secondary site. Although crystallographic experiments have suggested that VD3 can bind to both monomeric and dimeric states without significant structural differences, theoretical and experimental reports have proposed some structural requirements. Thus, in this study, based on known experimental data, the dynamic interaction of VD3 with the monomeric or dimeric forms of βlg was investigated through a protocol combining blind docking and 2 microsecond molecular dynamics simulations coupled with binding free energy and per-residue binding free energy decomposition analyses using the Molecular Mechanics Generalized Born Surface Area approach. Binding free energy calculations allowed us to estimate the energetic differences of coupling VD3 at the calyx and the dimeric interface for the monomeric or dimeric state, revealing that the dimeric structure is required to form a stable complex with VD3 at the dimeric interface. This also has an important impact on the dimerization process, whereas although the monomeric state also forms a stable complex with VD3 at the dimeric interface, the incorporation of the entropy component contributed to producing a marginally favorable binding free energy. Finally, the per-residue decomposition analysis provided energetic information about the most relevant residues in stabilizing the different systems.     

A polymetamorphic protein

Arc repressor is a homodimeric protein with a ribbon‐helix–helix fold. A single polar‐to‐hydrophobic substitution (N11L) at a solvent‐exposed position leads to population of an alternate dimeric fold in which 3₁₀ helices replace a β‐sheet. Here we find that the variant Q9V/N11L/R13V (S‐VLV), with two additional polar‐to‐hydrophobic surface mutations in the same β‐sheet, forms a highly stable, reversibly folded octamer with approximately half the?α‐helical content of wild‐type Arc. At low protein concentration and low ionic strength, S‐VLV also populates both dimeric topologies previously observed for N11L, as judged by NMR chemical shift comparisons. Thus, accumulation of simple hydrophobic mutations in Arc progressively reduces fold specificity, leading first to a sequence with two folds and then to a manifold bridge sequence with at least three different topologies. Residues 9–14 of S‐VLV form a highly hydrophobic stretch that is predicted to be amyloidogenic, but we do not observe aggregates of higher order than octamer. Increases in sequence hydrophobicity can promote amyloid aggregation but also exert broader and more complex effects on fold specificity. Altered native folds, changes in fold coupled to oligomerization, toxic pre‐amyloid oligomers, and amyloid fibrils may represent a near continuum of accessible alternatives in protein structure space.     

Unraveling the Role of the C-terminal Helix Turn Helix of the Coat-binding Domain of Bacteriophage P22 Scaffolding Protein

Many viruses encode scaffolding and coat proteins that co-assemble to form procapsids, which are transient precursor structures leading to progeny virions. In bacteriophage P22, the association of scaffolding and coat proteins is mediated mainly by ionic interactions. The coat protein-binding domain of scaffolding protein is a helix turn helix structure near the C terminus with a high number of charged surface residues. Residues Arg-293 and Lys-296 are particularly important for coat protein binding. The two helices contact each other through hydrophobic side chains. In this study, substitution of the residues of the interface between the helices, and the residues in the β-turn, by aspartic acid was used examine the importance of the conformation of the domain in coat binding. These replacements strongly affected the ability of the scaffolding protein to interact with coat protein. The severity of the defect in the association of scaffolding protein to coat protein was dependent on location, with substitutions at residues in the turn and helix 2 causing the most significant effects. Substituting aspartic acid for hydrophobic interface residues dramatically perturbs the stability of the structure, but similar substitutions in the turn had much less effect on the integrity of this domain, as determined by circular dichroism. We propose that the binding of scaffolding protein to coat protein is dependent on angle of the β-turn and the orientation of the charged surface on helix 2. Surprisingly, formation of the highly complex procapsid structure depends on a relatively simple interaction.     

Monomeric state of S100P protein: Experimental and molecular dynamics study

S100 proteins constitute a large subfamily of the EF-hand superfamily of calcium binding proteins. They possess one classical EF-hand Ca²⁺-binding domain and an atypical EF-hand domain. Most of the S100 proteins form stable symmetric homodimers. An analysis of literature data on S100 proteins showed that their physiological concentrations could be much lower than dissociation constants of their dimeric forms. It means that just monomeric forms of these proteins are important for their functioning. In the present work, thermal denaturation of apo-S100P protein monitored by intrinsic tyrosine fluorescence has been studied at various protein concentrations within the region from 0.04–10 μM. A transition from the dimeric to monomeric form results in a decrease in protein thermal stability shifting the mid-transition temperature from 85 to 75 °C. Monomeric S100P immobilized on the surface of a sensor chip of a surface plasmon resonance instrument forms calcium dependent 1 to 1 complexes with human interleukin-11 (equilibrium dissociation constant 1.2 nM). In contrast, immobilized interleukin-11 binds two molecules of dimeric S100P with dissociation constants of 32 nM and 288 nM. Since effective dissociation constant of dimeric S100P protein is very low (0.5 μM as evaluated from our data) the sensitivity of the existing physical methods does not allow carrying out a detailed study of S100P monomer properties. For this reason, we have used molecular dynamics methods to evaluate structural changes in S100P upon its transition from the dimeric to monomeric state. 80-ns molecular dynamics simulations of kinetics of formation of S100P, S100B and S100A11 monomers from the corresponding dimers have been carried out. It was found that during the transition from the homo-dimer to monomer form, the three S100 monomer structures undergo the following changes: (1) the helices in the four-helix bundles within each monomer rotate in order to shield the exposed non-polar residues; (2) almost all lost contacts at the dimer interface are substituted with equivalent and newly formed interactions inside each monomer, and new stabilizing interactions are formed; and (3) all monomers recreate functional hydrophobic cores. The results of the present study show that both dimeric and monomeric forms of S100 proteins can be functional.     

Cryo-electron Microscopic Structure of SecA Protein Bound to the 70S Ribosome

SecA is an ATP-dependent molecular motor pumping secretory and outer membrane proteins across the cytoplasmic membrane in bacteria. SecA associates with the protein-conducting channel, the heterotrimeric SecYEG complex, in a so-called posttranslational manner. A recent study further showed binding of a monomeric state of SecA to the ribosome. However, the true oligomeric state of SecA remains controversial because SecA can also form functional dimers, and high-resolution crystal structures exist for both the monomer and the dimer. Here we present the cryo-electron microscopy structures of Escherichia coli SecA bound to the ribosome. We show that not only a monomeric SecA binds to the ribosome but also that two copies of SecA can be observed that form an elongated dimer. Two copies of SecA completely surround the tunnel exit, providing a unique environment to the nascent polypeptides emerging from the ribosome. We identified the N-terminal helix of SecA required for a stable association with the ribosome. The structures indicate a possible function of the dimeric form of SecA at the ribosome.     

Structure stability of lytic peptides during their interactions with lipid bilayers.

In this work, molecular dynamics simulations were used to examine the consequences of a variety of analogs of cecropin A on lipid bilayers. Analog sequences were constructed by replacing either the N- or C-terminal helix with the other helix in native or reverse sequence order, by making palindromic peptides based on both the N- and C-terminal helices, and by deleting the hinge region. The structure of the peptides was monitored throughout the simulation. The hinge region appeared not to assist in maintaining helical structure but help in motion flexibility. In general, the N-terminal helix of peptides was less stable than the C-terminal one during the interaction with anionic lipid bilayers. Sequences with hydrophobic helices tended to regain helical structure after an initial loss while sequences with amphipathic helices were less able to do this. The results suggests that hydrophobic design peptides have a high structural stability in an anionic membrane and are the candidates for experimental investigation.     

Structure prediction of the dimeric neu/ErbB-2 transmembrane domain from multi-nanosecond molecular dynamics simulations

Dimerization of the neu/ErbB-2 receptor tyrosine kinase is a necessary but not a sufficient step for signaling. Despite the efforts expended to identify the molecular interactions responsible for receptor-receptor contacts and particularly those involving the transmembrane domain, structural details are still unknown. In this work, molecular dynamics simulations of the helical transmembrane domain (TM) of neu and ErbB-2 receptors are used to predict their dimer structure both in the wild and oncogenic forms. A global conformational search method, applied to define the best orientations of parallel helices, showed an energetically favorable configuration with the specific mutation site within the interface, common for both the nontransforming and the transforming neu/ErbB-2 TM dimers. Starting from this configuration, a total of 10 simulations, about 1.4 ns each, performed in vacuum, without any constraints, show that the two helices preferentially wrap in left-handed interactions with a packing angle at about 20°. The resulting structures are nonsymmetric and the hydrogen bond network analysis shows that helices experience π local distortions that facilitate inter-helix hydrogen bond interactions and may result in a change in the helix packing, leading to a symmetric interface. For the mutated sequences, we show that the Glu side chain interacts directly with its cognate or with carbonyl groups of the facing backbone. We show that the connectivity between interfacial residues conforms to the knobs-into-holes packing mode of transmembrane helices. The dimeric interface described in our models is discussed with respect to mutagenesis studies. Received: 12 March 1999 / Revised version: 23 August 1999 / Accepted: 23 August 1999     

Topography of helices 5-7 in membrane-inserted diphtheria toxin T domain: identification and insertion boundaries of two hydrophobic sequences that do not form a stable transmembrane hairpin

The T domain of diphtheria toxin undergoes a low pH-induced conformational change that allows it to penetrate cell membranes. T domain hydrophobic helices 8 and 9 can adopt two conformations, one close to the membrane surface (P state) and a second in which they apparently form a transmembrane hairpin (TM state). We have now studied T domain helices 5-7, a second cluster of hydrophobic helices, using Cys-scanning mutagenesis. After fluorescently labeling a series of Cys residues, penetration into a non-polar environment, accessibility to externally added antibodies, and relative depth in the bilayer were monitored. It was found that helices 5-7 insert shallowly in the P state and deeply in the TM state. Thus, the conformational changes in helices 5-7 are both similar and somehow linked to those in helices 8 and 9. The boundaries of deeply inserting sequences were also identified. One deeply inserted segment was found to span residues 270 to 290, which overlaps helix 5, and a second spanned residues 300 to 320, which includes most of helix 6 and all of helix 7. This indicates that helices 6 and 7 form a continuous hydrophobic segment despite their separation by a Pro-containing kink. Additionally, it is found that in the TM state some residues in the hydrophilic loop between helices 5 and 6 become more highly exposed than they are in the P state. Their exposure to external solution in the TM state indicates that helices 5-7 do not form a stable transmembrane hairpin. However, helix 5 and/or helices 6 plus 7 could form transmembrane structures that are in equilibrium with non-transmembrane states, or be kinetically prevented from forming a transmembrane structure. How helices 5-7 might influence the mechanism by which the T domain aids translocation of the diphtheria toxin A chain across membranes is discussed.     

Position-dependence of stabilizing polar interactions of asparagine in transmembrane helical bundles

Recent studies with model peptides and statistical analyses of the crystal structures of membrane proteins have shown that buried polar interactions contribute significantly to the stabilization of the three-dimensional structures of membrane proteins. Here, we probe how the location of these polar groups along the transmembrane helices affect their free energies of interaction. Asn residues were placed singly and in pairs at three positions within a model transmembrane helix, which had previously been shown to support the formation of trimers in micelles. The model helix was designed to form a transmembrane coiled coil, with Val side chains at the "a" positions of the heptad repeat. Variants of this peptide were prepared in which an Asn residue was introduced at one or more of the "a" positions, and their free energies of association were determined by analytical ultracentrifugation. When placed near the middle of the transmembrane helix, the formation of trimers was stabilized by at least -2.0 kcal/mol per Asn side chain. When the Asn was placed at the interface between the hydrophobic and polar regions of the peptide, the substitution was neither stabilizing nor destabilizing (0.0 +/- 0.5 kcal/mol of monomer). Finally, it has previously been shown that a Val-for-Asn mutation in a water-soluble coiled coil destabilizes the structure by approximately 1.5 kcal/mol of monomer [Acharya, A., et al. (2002) Biochemistry 41, 14122-14131]. Thus, the headgroup region of a micelle appears to have a conformational impact intermediate between that of bulk water and the apolar region of micelle. A similarly large dependence on the location of the polar residues was found in a statistical survey of helical transmembrane proteins. The tendency of different types of residues to be buried in the interiors versus being exposed to lipids was analyzed. Asn and Gln show a very strong tendency to be buried when they are located near the middle of a transmembrane helix. However, when placed near the ends of transmembrane helices, they show little preference for the surface versus the interior of the protein. These data show that Asn side chains within the apolar region of the transmembrane helix provide a significantly larger driving force for association than Asn residues near the apolar/polar interface. Thus, although polar interactions are able to strongly stabilize the folding of membrane proteins, the energetics of association depend on their location within the hydrophobic region of a transmembrane helix.