Amantadine blocks channel activity of the transmembrane segment of the NB protein from influenza B.

NB is short auxiliary protein with ca. 100 amino acids, encoded in the viral genome of influenza B. It is believed to be similar to M2 from influenza A and Vpu from HIV-1 in that it demonstrates ion channel activity. Channels formed by the protein can be blocked by amantadine. We have synthesized the putative transmembrane segment of NB (IRG S20 IIITICVSL I30 VILIVFGCI A40 KIFI (NB, Lee)). Reconstituted in a lipid bilayer, the peptide shows channel activity. The addition of amantadine leads to dose-dependent loss of channel activity. Channel blocking is reversible. Channel behaviour of the peptide in the presence of amantadine is in accordance with findings for the intact channel. Thus, the synthetic transmembrane peptide captures the ion channel activity of the intact NB protein.

Transmembrane peptide NB of influenza B: a simulation, structure, and conductance study.

The putative transmembrane segment of the ion channel forming peptide NB from influenza B was synthesized by standard solid-phase peptide synthesis. Insertion into the planar lipid bilayer revealed ion channel activity with conductance levels of 20, 61, 107, and 142 pS in a 0.5 M KCl buffer solution. In addition, levels at -100 mV show conductances of 251 and 413 pS. A linear current-voltage relation reveals a voltage-independent channel formation. In methanol and in vesicles the peptide appears to adopt an alpha-helical-like structure. Computational models of alpha-helix bundles using N = 4, 5, and 6 NB peptides per bundle revealed water-filled pores after 1 ns of MD simulation in a solvated lipid bilayer. Calculated conductance values [using HOLE (Smart et al. (1997) Biophys. J. 72, 1109-1126)] of ca. 20, 60, and 90 pS, respectively, suggested that the multiple conductance levels seen experimentally must correspond to different degrees of oligomerization of the peptide to form channels.

Formation and seeding of amyloid fibrils from wild-type hen lysozyme and a peptide fragment from the beta-domain.

Wild-type hen lysozyme has been converted from its soluble native state into highly organized amyloid fibrils. In order to achieve this conversion, conditions were chosen to promote partial unfolding of the native globular fold and included heating of low-pH solutions and addition of organic solvents. Two peptides derived from the beta-sheet region of hen lysozyme were also found to form fibrils very readily. The properties and morphologies of the amyloid fibrils formed by incubation either of the protein or the peptides are similar to those produced from the group of proteins associated with clinical amyloidoses. Fibril formation by hen lysozyme was substantially accelerated when aliquots of solutions in which fibrils of either one of the peptides or the full-length protein had previously formed were added to fresh solutions of the protein, revealing the importance of seeding in the kinetics of fibril formation. These findings support the proposition that the beta-domain is of particular significance in the formation of fibrils from the full-length protein and suggest similarities between the species giving rise to fibril formation and the intermediates formed during protein folding.

Probing the nature of interactions in SH2 binding interfaces--evidence from electrospray ionization mass spectrometry.

We have adopted nanoflow electrospray ionization mass spectrometry (ESI-MS) and isothermal titration calorimetry (ITC) to probe the mechanism of peptide recognition by the SH2 domain from the Src family tyrosine kinase protein, Fyn. This domain is involved in the mediation of intracellular signal transduction pathways by interaction with proteins containing phosphorylated tyrosine (Y*) residues. The binding of tyrosyl phosphopeptides can mimic these interactions. Specificity in these interactions has been attributed to the interaction of the Y* and residues proximal and C-terminal to it. Previous studies have established that for specific binding with Fyn, the recognition sequence consists of pTyr-Glu-Glu-Ile. The specific interactions involve the binding of Y* with the ionic, and the Y* + 3 Ile residue with the hydrophobic binding pockets on the surface of the Fyn SH2 domain. In this work, a variation in the Y* + 3 residue of this high-affinity sequence was observed to result in changes in the relative binding affinities as determined in solution (ITC) and in the gas phase (nanoflow ESI-MS). X-ray analysis shows that a feature of the Src family SH2 domains is the involvement of water molecules in the peptide binding site. Under the nanoflow ESI conditions, water molecules appear to be maintained in the Fyn SH2-ligand complex. Compelling evidence for these molecules being incorporated in the SH2-peptide interface is provided by the prevalence of the peaks assigned to water-bound over the water-free complex at high-energy conditions. Thus, the stability of water protein-ligand complex appears to be intimately linked to the presence of water.

Formation of amyloid fibrils by peptides derived from the bacterial cold shock protein CspB.

Three peptides covering the sequence regions corresponding to the first two (CspB-1), the first three (CspB-2), and the last two (CspB-3) beta-strands of CspB, the major cold shock protein of Bacillus subtilis, have been synthesized and analyzed for their conformations in solution and for their precipitation behavior. The peptides are nearly insoluble in water, but highly soluble in aqueous solutions containing 50% acetonitrile (pH 4.0). Upon shifts of the solvent condition toward lower or higher acetonitrile concentrations, the peptides all form fibrils resembling those observed in amyloid associated diseases. These fibrils have been identified and characterized by electron microscopy, binding of the dye congo red, and X-ray fiber diffraction. Characterization of the peptides in solution by circular dichroism and NMR spectroscopy shows that the formation of these fibrils does not require specific preformed secondary structure in the solution state species. While the majority of the soluble fraction of each peptide is monomeric and unstructured, different types of structures including alpha-helical, beta-sheet, and random coil conformations are observed under conditions that eventually lead to fibril formation. We conclude that the absence of tertiary contacts under solution conditions where binding interactions between peptide units are still favorable is a crucial requirement for amyloid formation. Thus, fragmentation of a sequence, like partial chemical denaturation or mutation, can enhance the capacity of specific protein sequences to form such fibrils.

The folding kinetics and thermodynamics of the Fyn-SH3 domain.

The equilibrium unfolding and the kinetic folding and unfolding of the 67 residue Fyn-SH3 domain have been investigated. Equilibrium unfolding experiments indicate that, despite the lack of both disulfide bonds and prosthetic groups, Fyn-SH3 is relatively stable with a free energy of folding of -6.0 +/- 0.6 kcal mol-1 at 20 degrees C. Kinetic experiments indicate that the domain refolds in a rapid two-state manner without significant population of intermediates (k = 94.3 s-1 in H2O at 20 degrees C). Despite the presence of two proline residues, the refolding of the domain is monophasic, and no significant proline isomerization-like refolding phase is observed. This can be attributed to an extremely low level of the incorrect (cis) isomer of the structurally important Pro134 residue in the protein denatured in 8 M guanidine hydrochloride. Analysis of the temperature and guanidine hydrochloride dependence of the folding rate suggests that the folding transition state of this protein is relatively well organized. A comparison with the refolding kinetics and thermodynamics of other homologous SH3 domains indicates that these exhibit an equivalent degree of transition state organization. This potentially arises from conservation of key features of the transition state conformation despite sometimes relatively low overall sequence identity. Such a comparison further suggests that relative thermodynamic stability is an important factor in determining the relative folding rates of natural proteins with a common fold, but that specific details of the amino acid sequence can also play a significant role in individual cases.

Responsive gels formed by the spontaneous self-assembly of peptides into polymeric beta-sheet tapes.

Molecular self-assembly is becoming an increasingly popular route to new supramolecular structures and molecular materials. The inspiration for such structures is commonly derived from self-assembling systems in biology. Here we show that a biological motif, the peptide beta-sheet, can be exploited in designed oligopeptides that self-assemble into polymeric tapes and with potentially useful mechanical properties. We describe the construction of oligopeptides, rationally designed or based on segments of native proteins, that aggregate in suitable solvents into long, semi-flexible beta-sheet tapes. These become entangled even at low volume fractions to form gels whose viscoelastic properties can be controlled by chemical (pH) or physical (shear) influences. We suggest that it should be possible to engineer a wide range of properties in these gels by appropriate choice of the peptide primary structure.

The effects of guanidine hydrochloride on the 'random coil' conformations and NMR chemical shifts of the peptide series GGXGG.

The effects of the commonly used denaturant guanidine hydrochloride(GuHCl) on the random coil conformations and NMR chemical shifts of theproteogenic amino acids have been characterized using the peptide seriesAc-Gly-Gly-X-Gly-Gly-NH(2). The phi angle-sensitive couplingconstants, ROESY cross peak intensities and proline cis-trans isomerratios of a representative subset of these peptides are unaffected by GuHCl,which suggests that the denaturant does not significantly perturb intrinsicbackbone conformational preferences. A set of(3)J(HNHalpha) values is presented which agreewell with predictions of recently developed models of the random coil. Wehave also measured the chemical shifts of all 20 proteogenic amino acids inthese peptides over a range of GuHCl concentrations. The shifts exhibit alinear dependence on denaturant concentration and we report here correctionfactors for the calculation of 'random coil' (1)H chemicalshifts at any arbitrary denaturant concentration. Studies of arepresentative subset of peptides indicate that (13)C and(15)N chemical shifts are also perturbed by the denaturant.These results should facilitate the application of chemical shift-basedanalytical techniques to the study of polypeptides in solution with GuHCl.The effects of the denaturant on the quality of NMR spectra and on chemicalshift referencing are also addressed.

Insight into a random coil conformation and an isolated helix: structural and dynamical characterisation of the C-helix peptide from hen lysozyme.

A 17 residue peptide corresponding to the C-helix of hen lysozyme (residues 86 to 102) has been investigated in detail to assess the factors that determine its conformation in both aqueous and trifluoroethanol (TFE) solutions. A thorough characterisation of the peptide by CD and NMR techniques under both conditions has been performed including the determination of complete NMR proton sequential assignments, and measurement of NOE effects, 3JHN alpha coupling constants, temperature coefficients and residue-specific hydrogen-exchange rates. In water, the peptide adopts a largely unstructured conformation and NMR data, particularly coupling constants and chemical shift deviations, have been shown to agree closely with predictions from a model for a random coil based on the phi, psi distributions in a protein database. This indicates that under these conditions the intrinsic conformational preferences of the individual amino acid residues are the dominating factors that determine the population of conformers adopted. With increasing concentrations of TFE a cooperative transition to an extensively helical conformation occurs and the resultant changes in C alpha H chemical shifts have been shown to correlate with the changes in phi, psi populations. Using NOE and coupling constant data for this state, an ensemble of structures has been calculated and provides a model for a helix in the absence of tertiary interactions. In this model fluctuations, which increase in amplitude towards the termini, occur about the average helical phi, psi angles and are responsible for increasing the values of 3JHN alpha coupling constants above those anticipated for a static helix. The residue-specific rates of hydrogen exchange for the peptide in 50% TFE-d, are consistent with such a model, the maximum protection from exchange being observed for residues in the centre of the helix.

Solution studies of the SH2 domain from the fyn tyrosine kinase: secondary structure, backbone dynamics and protein association.

The SH2 domain from Fyn tyrosine kinase, corresponding to residues 155-270 of the human enzyme, was expressed as a GST-fusion protein in a pGEX-E. coli system. After thrombin cleavage and removal of GST, the protein was studied by heteronuclear NMR. Two different phosphotyrosyl-peptides were synthesized and added to the SH2 domain. One peptide corresponded to the regulatory C-terminal tail region of Fyn. Sequence-specific assignment of NMR spectra was achieved using a combination of 1H-15N-correlated 2D HSQC, 15N-edited 3D TOCSY-HMQC, and 15N-edited 3D NOESY-HMQC spectra. By analysis of the alpha-proton chemical shifts and NOE intensities, the positions of secondary structural elements were determined and found to correspond closely to that seen in the crystal structure of the, homologous, Src-SH2 domain. To investigate the internal dynamics of the protein backbone, T1 and T2 relaxation parameters were measured on the free protein, as well as on both peptide complexes. Analytical ultracentrifugation and dynamic light scattering were employed to measure the effect of concentration and peptide-binding on self-association. The results suggest that, at NMR-sample concentrations, the free protein is present in at least dimeric form. Phosphopeptide binding and lower concentration significantly, but not completely, shift the equilibrium towards monomers. The possible role of this protein association in the regulation of the Src-family tyrosine kinases is discussed.

Native-like secondary structure in a peptide from the alpha-domain of hen lysozyme.

BACKGROUND: To gain insight into the local and nonlocal interactions that contribute to the stability of hen lysozyme, we have synthesized two peptides that together comprise the entire alpha-domain of the protein. One peptide (peptide 1-40) corresponds to the sequence that forms two alpha-helices, a loop region, and a small beta-sheet in the N-terminal region of the native protein. The other (peptide 84-129) makes up the C-terminal part of the alpha-domain and encompasses two alpha-helices and a 3(10) helix in the native protein. RESULTS: As judged by CD and a range of NMR parameters, peptide 1-40 has little secondary structure in aqueous solution and only a small number of local hydrophobic interactions, largely in the loop region. Peptide 84-129, by contrast, contains significant helical structure and is partially hydrophobically collapsed. More specifically, the region corresponding to helix C in native lysozyme is disordered, whereas regions corresponding to the D and 3(10) helices in the native protein are helical in this peptide. The structure in peptide 84-129 is at least partly stabilized by interactions between residues in the two helical regions, as suggested by further NMR analysis of three short peptides corresponding to the individual helices in this region of the native protein. CONCLUSIONS: Stabilization of structure in the sequence 1-40 appears to be facilitated predominantly by long-range interactions between this region and the sequence 84-129. In native lysozyme, the existence of two disulphide bonds between the N- and C-terminal halves of the alpha-domain is likely to be a major factor in their stabilization. The data show, however, that native-like secondary structure can be generated in the C-terminal portion of the alpha-domain by nonspecific and nonnative interactions within a partially collapsed state.

Conformational properties of four peptides spanning the sequence of hen lysozyme.

Four peptides encompassing the entire amino acid sequence of hen lysozyme were examined in aqueous solution and in 50% (v/v) 2,2,2-trifluoroethanol (TFE) by far-UV CD. Two peptides, 1-40 and 84-129, correspond to regions which are helical in the native protein, and together represent the alpha-domain. The beta-domain of the native enzyme was also synthesized as two peptides, one (41-60) containing the residues in the triple stranded antiparallel beta-sheet and the other (61-82) corresponding to a region lacking regular secondary structure. In water at pH 2.0 and 25 degrees C, the monomeric peptides 1-40, 41-60 and 61-82 appear to be predominantly unstructured. By contrast, the peptide 84-129 has considerable, presumably helical structure, corresponding to approximately 19%, or nine residues, on average, which can be unfolded by the addition of 8 M urea or 6 M guanidine hydrochloride. In 50% TFE the conformational properties of the four peptides are again distinct. Although little helical structure is induced in the peptides 41-60 and 61-82, and a native-like extent of helical structure is induced in the peptide 1-40, the peptide 84-29 converts almost entirely to helical structure in 50% TFE. The far-UV CD spectrum of a stoichiometric mixture of the four peptides in water resembles closely that of a denatured state of the intact protein formed by reductive methylation of its four disulphide bonds, but differs significantly from that of the native protein. The far-UV CD spectrum of the peptide mixture in TFE is indistinguishable from that of the intact protein in this solvent, both in the presence and in the absence of its four disulphide bonds. The conformational preferences of the peptides are not predicted using standard assessments of helical propensity or hydrophobicity, but correlate instead with the number of local contacts made in the native protein. On the basis of these results, we suggest that the region 84-129 could play an important role in determining the nature of the early folding events in the folding pathway of the intact polypeptide chain.

Solution structure of a peptide fragment of human alpha-lactalbumin in trifluoroethanol: a model for local structure in the molten globule.

BACKGROUND: At low pH, human alpha-lactalbumin forms a partly folded molten globule state that contains a non-native clustering of the side chains of Tyr103, Trp104 and His107. In order to understand the conformation of this region of the protein in the molten globule state, we investigated the structure of a peptide corresponding to residues 101-110 of human alpha-lactalbumin in trifluoroethanol. RESULTS: We determined the structure of the 101-110 peptide from an NMR data set of 145 nuclear Overhauser effects and nine 3JHN alpha coupling constants, using an ensemble calculation approach to take into account the possibilities of conformational averaging of the data. The backbone of residues 3-10 in the peptide adopts a series of turns, that involving residues 5-8 being the best defined, while the side chains of residues 1, 3, 4, 5, 6 and 7 form a hydrophobic cluster. CONCLUSIONS: The peptide conformation differs from that previously determined for residues 101-110 in crystal structures of native alpha-lactalbumin determined at both high and low pH, particularly in the relative orientations of the side chains. The series of turns seen in the peptide could, however, be related to the alpha-helical structure seen for residues 104-111 in crystals at high pH, and may be important in the molten globule state for bringing the peptide chain into a compact conformation where favourable interactions between the side chains can occur.

Structure and dynamics of the acid-denatured molten globule state of alpha-lactalbumin: a two-dimensional NMR study.

Two-dimensional 1H-NMR spectroscopy has been used to study the acid-denatured molten globule (A-state) of alpha-lactalbumin. The NMR spectra show that chemical shift dispersion is limited but significantly greater than that expected for a random coil conformation. The small chemical shift dispersion of side-chain resonances in the A-state together with line broadening associated with conformational averaging indicates that most of the long-range tertiary structure in the A-state is likely to be nonspecific. Side-chain resonances in the A-state are generally shifted somewhat upfield of random coil values; this and the observation of a large number of interresidue NOEs, however, indicate that some side-chain interactions, at least at the level of hydrophobic clustering, exist in the A-state. Analysis of NOESY spectra shows no evidence for an ordered structure for either of the two major clusters of aromatic residues which in the native structure make up part of the hydrophobic core of the helical domain of the native protein. A new aromatic cluster in the A-state which results from rearrangement of the side chains of Tyr103, Trp104, and His107 from their native state positions was, however, detected by a number of well-defined interresidue NOE effects. Similar NOE patterns are observed in a peptide corresponding to residues 101-110 of alpha-lactalbumin in trifluoroethanol, suggesting that the non-native structure in the 101-110 region of the A-state is not dependent on specific interactions with the rest of the chain. Trapping experiments indicate that amide protons from regions of the sequence which in the native state are helical are among those strongly protected from solvent exchange in the A-state; those from one of the helices (the C helix) were specifically identified. Taken together, these results reinforce a model of the A-state which has stable regions of localized secondary structure but a largely disordered tertiary structure.

A peptide model for proline isomerism in the unfolded state of staphylococcal nuclease.

Nuclear magnetic resonance spectroscopy has been used to investigate a synthetic peptide (YVYKPNNTHE) corresponding to residues 113 to 122 of staphylococcal nuclease. In the major folded state of the protein this region forms a type VIa beta-turn containing a cis Lys116-Pro117 peptide bond. There is, however, no evidence for any significant population of such a turn in the peptide in aqueous solution and the X-Pro bond is predominantly in the trans configuration. The peptide exhibits several well-resolved minor resonances due to the presence of a small fraction (4 +/- 2%) of the cis-proline isomer. The ratio of cis to trans isomer populations was found to be independent of temperature between 5 degrees C and 70 degrees C, indicating that delta H for the isomerism is close to zero. Using magnetization transfer techniques the rate of trans to cis interconversion was found to be 0.025(+/- 0.013) s-1 at 50 degrees C. The thermodynamics and kinetics of isomerism in the peptide are very similar to those estimated for the Lys116-Pro117 peptide bond in unfolded nuclease, suggesting that the cis-trans equilibrium in the unfolded protein is largely determined by the residues adjacent to Pro117 in the sequence. These results are consistent with previous suggestions that the cis-proline bond is stabilized late in the folding process and that the predominance of the cis form in folded nuclease is due to stabilizing interactions within the protein that give rise to a favorable enthalpy term.