Control of Transmembrane Helix Dynamics by Interfacial Tryptophan Residues

Transmembrane protein domains often contain interfacial aromatic residues, which may play a role in the insertion and stability of membrane helices. Residues such as Trp or Tyr, therefore, are often found situated at the lipid-water interface. We have examined the extent to which the precise radial locations of interfacial Trp residues may influence peptide helix orientation and dynamics. To address these questions, we have modified the GW^5,19ALP23 (acetyl-GGALW⁵(LA)₆LW¹⁹LAGA-[ethanol]amide) model peptide framework to relocate the Trp residues. Peptide orientation and dynamics were analyzed by means of solid-state nuclear magnetic resonance (NMR) spectroscopy to monitor specific ²H- and ¹⁵N-labeled residues. GW^5,19ALP23 adopts a defined, tilted orientation within lipid bilayer membranes with minimal evidence of motional averaging of NMR observables, such as ²H quadrupolar or ¹⁵N-¹H dipolar splittings. Here, we examine how peptide dynamics are impacted by relocating the interfacial Trp (W) residues on both ends and opposing faces of the helix, for example by a 100° rotation on the helical wheel for positions 4 and 20. In contrast to GW^5,19ALP23, the modified GW^4,20ALP23 helix experiences more extensive motional averaging of the NMR observables in several lipid bilayers of different thickness. Individual and combined Gaussian analyses of the ²H and ¹⁵N NMR signals confirm that the extent of dynamic averaging, particularly rotational “slippage” about the helix axis, is strongly coupled to the radial distribution of the interfacial Trp residues as well as the bilayer thickness. Additional ²H labels on alanines A3 and A21 reveal partial fraying of the helix ends. Even within the context of partial unwinding, the locations of particular Trp residues around the helix axis are prominent factors for determining transmembrane helix orientation and dynamics within the lipid membrane environment.     

Mutations in the major gas vesicle protein GvpA and impacts on gas vesicle formation in Haloferax volcanii

Gas vesicles are proteinaceous, gas‐filled nanostructures produced by some bacteria and archaea. The hydrophobic major structural protein GvpA forms the ribbed gas vesicle wall. An in‐silico 3D‐model of GvpA of the predicted coil‐α1‐β1‐β2‐α2‐coil structure is available and implies that the two β‐chains constitute the hydrophobic interior surface of the gas vesicle wall. To test the importance of individual amino acids in GvpA we performed 85 single substitutions and analyzed these variants in Haloferax volcanii ΔA + A_mut transformants for their ability to form gas vesicles (Vac⁺ phenotype). In most cases, an alanine substitution of a non‐polar residue did not abolish gas vesicle formation, but the replacement of single non‐polar by charged residues in β1 or β2 resulted in Vac^– transformants. A replacement of residues near the β‐turn altered the spindle‐shape to a cylindrical morphology of the gas vesicles. Vac^– transformants were also obtained with alanine substitutions of charged residues of helix α1 suggesting that these amino acids form salt‐bridges with another GvpA monomer. In helix α2, only the alanine substitution of His53 or Tyr54, led to Vac^– transformants, whereas most other substitutions had no effect. We discuss our results in respect to the GvpA structure and data available from solid‐state NMR.     

Tryptophan-mediated Dimerization of the TssL Transmembrane Anchor Is Required for Type VI Secretion System Activity

The type VI secretion system (T6SS) is a multiprotein complex used by bacteria to deliver effectors into target cells. The T6SS comprises a bacteriophage-like contractile tail structure anchored to the cell envelope by a membrane complex constituted of the TssJ outer-membrane lipoprotein and the TssL and TssM inner-membrane proteins. TssJ establishes contact with the periplasmic domain of TssM whereas the transmembrane segments of TssM and its cytoplasmic domain interact with TssL. TssL protrudes in the cytoplasm but is anchored by a C-terminal transmembrane helix (TMH). Here, we show that TssL TMH dimerization is required for the stability of the protein and for T6SS function. Using the TOXCAT assay and point mutations of the 23 residues of the TssL TMH, we identified Thr194 and Trp199 as necessary for TssL TMH dimerization. NMR hydrogen–deuterium exchange experiments demonstrated the existence of a dimer with the presence of Trp185 and Trp199 at the interface. A structural model based on molecular dynamic simulations shows that TssL TMH dimer formation involves π–π interactions resulting from the packing of the two Trp199 rings at the C-terminus and of the six aromatic rings of Tyr184, Trp185 and Trp188 at the N-terminus of the TMH.     

Structural and positional studies of the antimicrobial peptide brevinin‐1BYa in membrane‐mimetic environments

Brevinin‐1BYa (FLPILASLAAKFGPKLFCLVTKKC), first isolated from skin secretions of the foothill yellow‐legged frog Rana boylii, shows broad‐spectrum activity, being particularly effective against opportunistic yeast pathogens. The structure of brevinin‐1BYa was investigated in various solution and membrane‐mimicking environments by proton nuclear magnetic resonance (¹H‐NMR) spectroscopy and molecular modelling. The peptide does not possess a secondary structure in aqueous solution. In a 33% 2,2,2‐trifluoroethanol (TFE‐d₃)‐H₂O solvent mixture, as well as in membrane‐mimicking sodium dodecyl sulfate and dodecylphosphocholine micelles, the peptide's structure is characterised by a flexible helix‐hinge‐helix motif, with the hinge located at the Gly¹³/Pro¹⁴ residues, and the two α‐helices extending from Pro³ to Phe¹² and from Pro¹⁴ to Thr²¹. Positional studies involving the peptide in sodium dodecyl sulfate and dodecylphosphocholine micelles using 5‐doxyl‐labelled stearic acid and manganese chloride paramagnetic probes show that the peptide's helical segments lie parallel to the micellar surface, with the residues on the hydrophobic face of the amphipathic helices facing towards the micelle core and the hydrophilic residues pointing outwards, suggesting that the peptide exerts its biological activity by a non–pore‐forming mechanism.     

Conformational studies of parathyroid hormone (PTH)/PTH‐related protein (PTHrP) point‐mutated hybrids

The N‐terminal 1–34 segments of both parathyroid hormone (PTH) and parathyroid hormone‐related protein (PTHrP) bind and activate the same membrane receptor in spite of major differences between the two hormones in their amino acid sequence. Recently, it was shown that in (1–34)PTH/PTHrP segmental hybrid peptides, the N‐terminal 1–14 segment of PTHrP is incompatible with the C‐terminal 15–34 region of PTH leading to substantial reduction in potency. The sites of incompatibility were identified as positions 5 in PTH and 19 in PTHrP. In the present paper we describe the synthesis, biological evaluation, and conformational characterization of two point‐mutated PTH/PTHrP 1–34 hybrids in which the arginine residues at positions 19 and 21 of the native sequence of PTHrP have been replaced by valine (hybrid V²¹) and glutamic acid (hybrid E¹⁹), respectively, taken from the PTH sequence. Hybrid V²¹ exhibits both high receptor affinity and biological potency, while hybrid E¹⁹ binds weakly and is poorly active. The conformational properties of the two hybrids were studied in aqueous solution containing dodecylphosphocholine (DPC) micelles and in water/2,2,2‐trifluoroethanol (TFE) mixtures. Upon addition of TFE or DPC micelles to the aqueous solution, both hybrids undergo a coil‐helix transition. The maximum helix content in 1 : 1 water/TFE, obtained by CD data for both hybrids, is ∼ 80%. In the presence of DPC micelles, the maximum helix content is ∼ 40%. The conformational properties of the two hybrids in the micellar system were further investigated by combined 2D‐nmr, distance geometry (DG), and molecular dynamics (MD) calculations. The common structural motif, consisting of two helical segments located at N‐ and C‐termini, was observed in both hybrids. However, the biologically potent hybrid V²¹ exhibits two flexible sites, centered at residues 12 and 19 and connecting helical segments, while the flexibility sites in the weakly active hybrid E¹⁹ are located at position 11 and in the sequence 20–26. Our findings support the hypothesis that the presence and location of flexibility points between helical segments are essential for enabling the active analogs to fold into the bioactive conformation upon interaction with the receptor. © 1999 John Wiley & Sons, Inc. Biopoly 50: 525–535, 1999     

E. COLI RNASE HI AND THE PHOSPHONATE-DNA/RNA HYBRID: MOLECULAR DYNAMICS SIMULATIONS

A model for the complex between E. coli RNase HI and the DNA/RNA hybrid (previously refined by molecular dynamics simulations) was used to determine the impact of the internucleotide linkage modifications (either 3′–O–CH₂–P–O–5′ or 3′–O–P–CH₂–O–5′) on the ability of the modified-DNA/RNA hybrid to create a complex with the protein. Modified internucleotide linkages were incorporated systematically at different positions close to the 3′-end of the DNA strand to interfere with the DNA binding site of RNase H. Altogether, six trajectories were produced (length 1.5). Mutual hydrogen bonds connecting both strands of the nucleic acids hybrid, DNA with RNase H, RNA with RNase H, and the scissile bond with the Mg⁺⁺ · 4H₂O chelate complex (bound in the active site) were analyzed in detail. Many residues were involved in binding of the DNA (Arg88, Asn84, Trp85, Trp104, Tyr73, Lys99, Asn100, Thr43, and Asn16) and RNA (Gln76, Gln72, Tyr73, Lys122, Glu48, Asn44, and Cys13) strand to the substrate-binding site of the RNase H enzyme. The most remarkable disturbance of the hydrogen bonding net was observed for structures with modified internucleotide linkages positioned in a way to interact with the Trp104, Tyr73, Lys99, and Asn100 residues (situated in the middle of the DNA binding site, where a cluster of Trp residues forms a rigid core of the protein structure).     

3(10)-Helix adjoining alpha-helix and beta-strand: sequence and structural features and their conservation

Does the amino acid use at the terminal positions of an α‐helix become altered depending on the context—more specifically, when there is an adjoining 3₁₀‐helix, and can a single helical cylinder encompass the resultant composite helix? An analysis of 138 and 107 cases of 3₁₀–α and α–3₁₀ composite helices, respectively, found in known protein structures indicate that the secondary structural element occurring first imposes its characteristics on the sequence of the structural element coming next. Thus, when preceded by a 3₁₀‐helix, the preference of proline to occur at the N1 position of an α‐helix is shifted to the N2 position, a typical characteristic of the C‐terminal capping of the 3₁₀‐helix. When an α‐ or a 3₁₀‐helix leads into a helix of the other type, there is a bend at the junction, especially for the 3₁₀–α composite, with the two junction residues facing inward and buried within the structure. Thus a single helical cylinder may not properly represent a composite helix, the bend providing a means for the tertiary structure to assume a globular shape, very much akin to what a proline‐induced kink does to an α‐helix. The tertiary structural context in which β–3₁₀ and 3₁₀–β composites occurs can be different, causing the angle between the secondary structural elements in the two cases to be different. Composites of 3₁₀‐helices and β‐strands are much more conserved among members in families of homologous structures than those between two types of helices; in many of the former instances, the 3₁₀‐helix constitutes the loops in β‐hairpin or β–β‐corner motifs. The overall fold of the chain may be more conserved than the actual identify of the secondary structure elements in a composite. © 2005 Wiley Periodicals, Inc. Biopolymers 78: 147–162, 2005 This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Intrinsic fluorescence of globular actin. Features of localization of tryptophan residues

The contribution of individual Trp residues to alpha-actin fluorescence was evaluated by means of an analysis of their microenvironment, which was done on the basis of PIR-International protein sequence database information. The contribution of Trp79 and Trp86 was shown to be low due to an effective nonradiating energy transfer according to the inductive resonance mechanism between the Trp residues and the fluorescence quenching of Trp86 by S gamma of Cys10, an efficient fluorescence quencher. The intrinsic fluorescence of actin was found to be determined mainly by Trp340 and Trp356, which are internal, inaccessible to solvent, and have a high density microenvironment formed mainly by nonpolar groups of protein. It is possible that the side chain conformation of Trp340 (t-isomer; chi 1 190 degrees, chi 2 89 degrees), aromatic rings of Tyr and Phe residues, and Pro residues in the microenvironment of Trp340 and Trp356 substantially contribute to the short-wavelength fluorescence spectrum of actin.     

Conformational preferences of a short Aib/Ala‐based water‐soluble peptide as a function of temperature

The amino acid Aib predisposes a peptide to be helical with context‐dependent preference for either 3₁₀‐ or α‐ or a mixed helical conformation. Short peptides also show an inherent tendency to be unfolded. To characterize helical and unfolded states adopted by water‐soluble Aib‐containing peptides, the conformational preference of Ac‐Ala‐Aib‐Ala‐Lys‐Ala‐Aib‐Lys‐Ala‐Lys‐Ala‐Aib‐Tyr‐NH₂ was determined by CD, NMR and MD simulations as a function of temperature. Temperature‐dependent CD data indicated the contribution of two major components, each an admixture of helical and extended/polyproline II structures. Both right‐ and left‐handed helical conformations were detected from deconvolution of CD data and ¹³C NMR experiments. The presence of a helical backbone, more pronounced at the N‐terminal, and a temperature‐induced shift in α‐helix/3₁₀‐helix equilibrium, more pronounced at the C‐terminal, emerged from NMR data. Starting from polyproline II, the N‐terminal of the peptide folded into a helical backbone in MD simulations within 5 ns at 60°C. Longer simulations showed a mixed‐helical backbone to be stable over the entire peptide at 5°C while at 60°C the mixed‐helix was either stable at the N‐terminus or occurred in short stretches through out the peptide, along with a significant population of polyproline II. Our results point towards conformational heterogeneity of water‐soluble Aib‐based peptide helices and the associated subtleties. The problem of analyzing CD and NMR data of both left‐ and right‐handed helices are discussed, especially the validity of the ellipticity ratio [θ]₂₂₂/[θ]₂₀₇, as a reporter of α‐/3₁₀‐ population ratio, in right‐ and left‐handed helical mixtures. Proteins 2009. © 2008 Wiley‐Liss, Inc.     

A general method for preparation of N‐Boc‐protected or N‐Fmoc‐protected α,β‐didehydropeptide building blocks and their use in the solid‐phase peptide synthesis

N‐(tert‐butyloxycarbonyl) or N‐(9‐fluorenylmethoxycarbonyl) dipeptides with C‐terminal (Z)‐α,β‐didehydrophenylalanine (?^ZPhe), (Z)‐α,β‐didehydrotyrosine (?^ZTyr), (Z)‐α,β‐didehydrotryptophan (?^ZTrp), (Z)‐α,β‐didehydromethionine (?^ZMet), (Z)‐α,β‐didehydroleucine (?^ZLeu), and (Z/E)‐α,β‐didehydroisoleucine (?^Z/EIle) were synthesised from their saturated analogues via oxidation of intermediate 2,5‐disubstituted‐oxazol‐5‐(4H)‐ones (also known as azlactones) with pyridinium tribromide followed by opening of the produced unsaturated oxazol‐5‐(4H)‐one derivatives in organic‐aqueous solution with a catalytic amount of trifluoroacetic acid or by a basic hydrolysis. In all cases, a very strong preference for Z isomers of α,β‐didehydro‐α‐amino acid residues was observed except of the ΔIle, which was obtained as the equimolar mixture of Z and E isomers. Reasons for the (Z)‐stereoselectivity and the increased stability of the aromatic α,β‐didehydro‐α‐amino acid residue oxazol‐5‐(4H)‐ones over the corresponding aliphatic ones are also discussed. It is the first use of such a procedure to synthesise peptides with the C‐terminal unsaturated residues and a peptide with 2 consecutive ΔPhe residues. This approach is very effective especially in the synthesis of peptides with aliphatic α,β‐didehydro‐α‐amino acid residues that are difficult to obtain by other methods. It allowed the first synthesis of the ?Met residue. It is also more cost‐effective and less laborious than other synthesis protocols. The dipeptide building blocks obtained were used in the solid‐phase synthesis of model peptides on a polystyrene‐based solid support. Peptides containing aromatic α,β‐didehydro‐α‐amino acid residues were obtained with PyBOP or TBTU as a coupling agent with good yields and purities. In the case of aliphatic α,β‐didehydro‐α‐amino acid residues, a good efficiency was achieved only with DPPA as a coupling agent.     

Cholesterol‐β1AR interaction versus cholesterol‐β2AR interaction

Two 8‐µs all‐atom molecular dynamics simulations have been performed on the two highly homologous G protein‐coupled receptor (GPCR) subtypes, β₁‐ and β₂‐adrenergic receptors, which were embedded in a lipid bilayer with randomly dispersed cholesterol molecules. During the simulations, cholesterol molecules accumulate to different surface regions of the two receptors, suggesting the subtype specificity of cholesterol–β‐adrenergic receptor interaction and providing some clues to the physiological difference of the two subtypes. Meanwhile, comparison between the two receptors in interacting with cholesterols shed some new light on general determinants of cholesterol binding to GPCRs. Our results indicate that although the concave surface, charged residues and aromatic residues are important, neither of these stabilizing factors is indispensable for a cholesterol interaction site. Different combinations of these factors lead to the diversified binding modes of cholesterol binding to the receptors. Our long‐time simulations, for the first time, revealed the pathway of a cholesterol molecule entering the consensus cholesterol motif (CCM) site, and the binding process of cholesterol to CCM is accompanied by a side chain flipping of the conserved Trp4.50. Moreover, the simulation results suggest that the I‐/V‐/L‐rich region on the extracellular parts of helix 6 might be an alternatively conserved cholesterol‐binding site for the class‐A GPCRs. Proteins 2014; 82:760–770. © 2013 Wiley Periodicals, Inc.     

Recent developments in isotope-aided NMR methods for supramolecular protein complexes –SAIL aromatic TROSY

BackgroundThe structure-function relationships for large protein complexes at the atomic level would be comprehensively understood, if hitherto unexplored aromatic ring NMR signals became accessible in addition to the currently used backbone amide and side-chain methyl signals.MethodsThe 82 kDa malate synthase G (MSG) proteins, selectively labeled with Trp and Phe bearing relaxation optimized isotope-labeled rings, were prepared to investigate the optimal conditions for obtaining the aromatic TROSY spectra.ResultsThe MSG proteins, selectively labeled with either [δ₁,ε₁,ε₃,η₂]-SAIL Trp or ζ-SAIL Phe, provided well-separated, narrow TROSY signals for the 12 Trp and 19 Phe residues in MSG. The signals were assigned sequence-specifically, using the set of single amino acid substitution mutants. The site-specific substitution of each Phe with Tyr or Leu induced substantial chemical shifts for the other aromatic ring signals, allowing us to identify the aromatic clusters in MSG, which were comparable to the structural domains proposed previously.ConclusionsWe demonstrated that the aromatic ring ¹³CH pairs without directly bonded ¹³C and adjacent ¹H spins provide surprisingly narrow TROSY signals, if the rings are surrounded by fully deuterated amino acids. The observed signals can be readily assigned by either the single amino acid substitution or the NOEs between the aromatic and methyl protons, if the methyl assignments are available.General significanceThe method described here should be generally applicable for difficult targets, such as proteins in lipid bilayers or possibly in living cells, thus providing unprecedented opportunities to use these new probes in structural biology.     

Structure–Critical Distribution of Aromatic Residues in the Fibronectin Type III Protein Family

Over a thousand individual Fibronectin type III (FnIII) domain sequences, extracted from more than 60 different FnIII-dependent protein super-structures, were downloaded from curated database resources. Three regions of extreme sequence conservation within the well-characterized FnIII β-sandwich structure were respectively defined by near absolute conservation of a tryptophan (Trp) in β-strand-B, tyrosines (Tyr) in both β-strand-C and β-strand-F, and a leucine (Leu) residue in the unstructured region immediately preceding β-strand-F. Employing these four conserved landmarks, the entire FnIII sequence dataset was vertically registered to align the three conserved regions, and the cumulative distribution of all other amino acid functionality was determined and plotted relative to these landmark residues. Conserved aromatic sites were each found to be flanked by aliphatic residues that assure localization of these sites to the inaccessible hydrophobic interface between major sheet structures. Mapping the location of conserved aromatic sites in numerous PDB structures demonstrated the consistent pair-wise co-localization of the indole side-chain of the conserved strand-B Trp site to within 0.35 nm of the phenolic side-chain of the strand-C Tyr site located 8–14 amino acids distal. Likewise, the side-chain of the strand-F Tyr site co-localized to within 0.45 nm of the aliphatic side-chain of the conserved Leu that uniformly precedes it by six residues. While classic hydropathy-based theories would deem the “burying” of Tyr and Trp side-chains and/or their association with hydrophobic FnIII core residues thermodynamically unnecessary, alternative contributions of conserved Trp and Tyr residues, and particularly the role of the absolutely conserved tyrosine phenolic –OH in native FnIII structure–function are considered. A more global role for conserved FnIII aromaticity is also discussed in light of the aromatic conservation observed in other well-established protein families.     

Conformational stability of CopC and roles of residues Tyr79 and Trp83

CopC is a periplasmic copper Chaperone protein that has a β‐barrel fold and two metal‐binding sites distinct for Cu(II) and Cu(I). In the article, four mutants (Y79F, Y79W, Y79WW83L, Y79WW83F) were obtained by site‐directed mutagenesis. The far‐UV CD spectra of the proteins were similar, suggesting that mutations did not bring any significant changes in secondary structures. Meanwhile the effects of mutations on the protein's function were manifested by Cu(II) binding. Fluorescence lifetime measurement and quenching of tryptophan fluorescence by acrylamide and KI showed that the microenvironment around Trp83 was more hydrophobic than that around Tyr79 in apoCopC. Unfolding experiments induced by guanidinium chloride (GdnHCl), urea provided the conformational stability of each protein. The Δ<ΔG⁰_element> obtained using the model of structural elements was used to show the role of Tyr79 and Trp83. On the one hand, the <ΔG⁰_element> induced by urea for Y79F, Y79W have a loss of 6.51, 2.03 kJ/mol, respectively, compared with apoCopC, proving that replacement of Tyr79 by Phe or Trp all decreased the protein stability, meaning that the hydrogen bonds interactions between Tyr79 and Thr75 played an important role in stabilizing apoCopC. On the other hand, the <ΔG⁰_element> induced by urea for Y79WW83L have a loss of 11.44 kJ/mol, but for Y79WW83F did a raise of 1.82 kJ/mol compared with Y79W. The replacement of Trp83 by Phe and Leu yields opposite effects on protein stability, which suggested that the aromatic ring of Trp83 was important in maintaining the hydrophobic core of apoCopC.     

Evaluation of lipid‐binding properties of the N‐terminal helical segments in human apolipoprotein A‐I using fragment peptides

Although the N‐terminal region in human apolipoprotein (apo) A‐I is thought to stabilize the lipid‐free structure of the protein, its role in lipid binding is unknown. Using synthetic fragment peptides, we examined the lipid‐binding properties of the first 43 residues (1–43) of apoA‐I in comparison with residues 44–65 and 220–241, which have strong lipid affinity in the molecule. Circular dichroism measurements demonstrated that peptides corresponding to each segment have potential propensity to form α‐helical structure in trifluoroethanol. Spectroscopic and thermodynamic measurements revealed that apoA‐I (1–43) peptide has the strong ability to bind to lipid vesicles and to form α‐helical structure comparable to apoA‐I (220–241) peptide. Substitution of Tyr‐18 located at the center of the most hydrophobic region in residues 1–43 with a helix‐breaking proline resulted in the impaired lipid binding, indicating that the α‐helical structure in this region is required to trigger the lipid binding. In contrast, apoA‐I (44–65) peptide exhibited a lower propensity to form α‐helical structure upon binding to lipid, and apoA‐I (44–65/S55P) peptide exhibited diminished, but not completely impaired, lipid binding, suggesting that the central region of residues 44–65 is not pivotally involved in the formation of the α‐helical structure and lipid binding. These results indicate that the most N‐terminal region of apoA‐I molecule, residues 1–43, contributes to the lipid interaction of apoA‐I through the hydrophobic helical residues. Copyright © 2008 European Peptide Society and John Wiley & Sons, Ltd.     

Reversible trifluoroacetic acid-induced conformational changes in glycophorin as detected by proton nuclear magnetic resonance spectroscopy

High-field (270 MHz) ¹H-NMR has been employed to study the solution conformation of glycophorin A, a sialoglycoprotein which spans the human erythrocyte membrane. Glycophorin A is one of the most fully characterized integral membrane proteins known, making it an excellent model for the study of membrane-bound proteins. This protein consists of three distinct domains: a glycosylated extracellular N-terminus, a hydrophobic intramembranous segment, and a polar cytoplasmic C-terminus. These domains contain aromatic residues which serve as convenient ¹H-NMR conformational probes. The aromatic region of the NMR spectrum of glycophorin A in ²H₂O shows single, well-resolved His and Tyr resonances. No resonances are observed, however, for the Phe residues which are located in or near the hydrophobic domain. These observations suggest that considerable heterogeneity with respect to segmental motions exists within the protein. This is consistent with circular dichroism data showing the intramembranous segment to be completely helical with the extremities of the protein being predominantly random coils. The helix of the hydrophrobic domain is remarkably resistant to conventional denaturing conditions including variations in pH, and temperature, and treatment with guanidine hydrochloride. However, in trifluoroacetic acid, which strongly solvates peptide backbones, there is extensive reversible unfolding of the helical structure as evidenced by the appearance of Phe resonances. Solvent titration experiments indicate that approximately a 1 : 1 volume ratio of trifluoroacetic acid to ²H₂O is required to initiate unfolding of the helix.     

Structures of human host defense cathelicidin LL-37 and its smallest antimicrobial peptide KR-12 in lipid micelles

As a key component of the innate immunity system, human cathelicidin LL-37 plays an essential role in protecting humans against infectious diseases. To elucidate the structural basis for its targeting bacterial membrane, we have determined the high quality structure of (13)C,(15)N-labeled LL-37 by three-dimensional triple-resonance NMR spectroscopy, because two-dimensional (1)H NMR did not provide sufficient spectral resolution. The structure of LL-37 in SDS micelles is composed of a curved amphipathic helix-bend-helix motif spanning residues 2-31 followed by a disordered C-terminal tail. The helical bend is located between residues Gly-14 and Glu-16. Similar chemical shifts and (15)N nuclear Overhauser effect (NOE) patterns of the peptide in complex with dioctanoylphosphatidylglycerol (D8PG) micelles indicate a similar structure. The aromatic rings of Phe-5, Phe-6, Phe-17, and Phe-27 of LL-37, as well as arginines, showed intermolecular NOE cross-peaks with D8PG, providing direct evidence for the association of the entire amphipathic helix with anionic lipid micelles. The structure of LL-37 serves as a model for understanding the structure and function relationship of homologous primate cathelicidins. Using synthetic peptides, we also identified the smallest antibacterial peptide KR-12 corresponding to residues 18-29 of LL-37. Importantly, KR-12 displayed a selective toxic effect on bacteria but not human cells. NMR structural analysis revealed a short three-turn amphipathic helix rich in positively charged side chains, allowing for effective competition for anionic phosphatidylglycerols in bacterial membranes. KR-12 may be a useful peptide template for developing novel antimicrobial agents of therapeutic use.     

Inter-chain Proline: Proline Contacts Contribute to the Stability of the Triple Helical Conformation

Abstract

The triple helical conformation observed in the collagen group of proteins is related to the presence of large numbers of imino residues and is derived from the stereochemical properties of these residues. The triple helix is stabilized by increasing numbers of these residues. Hydrogen bonds are usually considered to be a major factor in the formation and stability of protein conformation, however, imino residues are not hydrogen bond donors. We have evaluated the role of these residues in stabilizing the triple helix by re-examining two X-ray based structures of the triple helical polypeptide (Pro-Pro- Gly)₁₀ using molecular mechanics calculations. The two minimized structures are comparable in energy and have helical parameters close to the starting values for each starting structure. Our studies suggest that clusters of close van der Waals contacts between proline residues in adjacent chains contribute significantly to the stability of the triple helix. Preliminary NMR studies support this concept. We propose that non-bonded interactions between proline residues may be a significant stabilizing force in the triple helix generated by (Pro-Pro-Gly)₁₀.