Conformational mapping of a viral fusion peptide in structure-promoting solvents using circular dichroism and electrospray mass spectrometry

The N-terminal domain of human immunodeficiency virus (HIV)-1 glycoprotein 41,000 (FP; residues 1–23; NH₂-AVGIGALFLGFLGAAGSTMGARS-CONH₂) is involved in the fusion and cytolytic processes underlying viral-cell infection. Here, we use circular dichroism (CD) spectroscopy, along with electrospray ionization (ESI) mass spectrometry and tandem (MS/MS) mass spectrometry during the course of hydrogen/deuterium exchange, to probe the local conformations of this synthetic peptide in two membrane mimics. Since amino acids that participate in defined secondary structure (i.e., α-helix or β-sheet) exchange amido hydrogens more slowly than residues in random structures, deuterium exchange was combined with CD spectroscopy to map conformations to specific residues. For FP suspended in the highly structure-promoting solvent hexafluoroisopropanol (HFIP), CD spectra indicated high α-helix and disordered structures, whereas ESI and MS/MS mass spectrometry indicated that residues 5–15 were α-helical and 16–23 were disordered. For FP suspended in the less structure-promoting solvent trifluoroethanol (TFE), CD spectra showed lower α-helix, with ESI and MS/MS mass spectrometry indicating that only residues 9–15 participated in the α-helix. These results compare favorably with previous two-dimensional nuclear magnetic resonance studies on the same peptide. Proteins Suppl. 2:38–49, 1998. © 1998 Wiley-Liss, Inc.     

Solution structure of the first and second transmembrane segments of the mitochondrial oxoglutarate carrier

The structures of the first and the second transmembrane segment of the bovine mitochondrial oxoglutarate carrier (OGC) were studied by circular dichroism (CD) and nuclear magnetic resonance (NMR) spectroscopies. Peptides 21–46 and 78–108 of its primary sequence were synthesized and structurally characterized in membrane-mimetic environments. CD data showed that at high concentrations of TFE (>50%) and SDS (>2%) both peptides assume α-helical structures, whereas in more hydrophilic environments only peptide 78–108 has a helical structure. ¹H-NMR spectra of the two peptides in TFE/water and SDS were fully assigned, and the secondary structures of the peptides were obtained from nuclear Overhauser effects, ³J_αH-NH coupling constants and αH chemical shifts. The three-dimensional solution structures of the peptides in TFE/water were generated by distance geometry calculations. A well-defined α-helix was found in the region K24-V39 of peptide 21–46 and in the region A86–F106 of peptide 78–108. We cannot exclude that in intact OGC the extension of these helices is longer. The helix of peptide 21–46 is essentially hydrophobic, whereas that of peptide 78–108 is predominantly hydrophilic.     

Helix formation by the phospholipase A2 38–59 fragment: Influence of chain shortening and dimerization monitored by nmr chemical shifts

The solution structure of a peptide fragment corresponding to the 38–59 region of porcine phospholipase A₂ has been investigated using CD, nmr chemical shifts, and nuclear over-hauser effects (NOEs). This isolated fragment of phospholipase forms an α-helix spanning residues 38–55, very similar to the one found in the native protein, except for residues 56–58, which were helical in the crystal but found random in solution. Addition of triflouro-ethanol (TFE) merely increased helix population but it did not redefine helix limits. To investigate how the folding information, in particular that concerning eventual helix start and stop signals, was coded in this particular amino acid sequence, the helices formed by synthetic peptides reproducing sections of this phospholipase 38–59 fragment, namely 40–59, 42–59, 38–50, and 45–57, were characterized using NOEs and helix populations quantitatively evaluated on different peptide chain segments using nmr chemical shifts in two solvents (H₂O and 30% TFE/H₂O). A set of nmr spectra was also recorded and assigned under denaturing conditions (6Murea) to obtain reliable values for the chemical shifts of each peptide in the random state. Based on chemical shift data, it was concluded that the helix formed by the phospholipase 38–59 fragment was not abruptly, but progressively, destabilized all along its length by successive elimination of residues at the N end, while the removal of residues at the C end affected helix stability more locally and to a lesser extent. These results are consistent with the idea that there are not single residues responsible for helix initiation or helix stability, and they also evidence an asymmetry for contributions to helix stability by residues located at the two chain ends. The restriction of molecular mobility caused by linking with a disulphide bridge at Cys 51 two identical 38–59 peptide chains did not increase helix stability. The helix formed by the covalently formed homodimer was very similar in length and population to that formed by the monomer. © 1994 John Wiley & Sons, Inc.     

Solution Structure of an Immunoactive Peptide fragment of Staphylococcal Protein-A

Abstract

Staphylococcal protein-A (SpA) is known to bind the Fc fragment of immunoglobin G in vitro and induce a myriad of immunogenic responses in vivo. The latter is ascribed to be due to the interaction of Fc and SpA. It has also been proposed that in vivo proteolytically cleaved fragments of SpA may be functioning in the same manner. One such fragment (EQQNAFYEILHLPNLNEEQR), fragment 8–27 of the B-domain (SpA-B), was recently shown to exhibit in vivo immunogenic response [Sinha, P., Sengupta, J., and Ray, P. K. (1999) Biochem. Biophys. Res. Commun. 258, 141–147]. As a first step towards understanding the mode of interaction of this peptide with the Fc fragment, we have studied the solution conformation of this isolated peptide by CD and NMR. The peptide, with 7 contact residues in the crystal structure of the SpA-B/Fc complex and comprising of mostly helixI and part of helixII of the 3-helix bundle of SpA-B, was found to be present predominantly in extended structure. However it showed nascent turn/helix like conformations around F14 & Y15. These two residues are known to play a vital role in SpA-B/Fc interaction as deciphered from crystal structure and NMR studies of SpA-B/Fc complex and mutational studies. The implications of our results, especially the nascent conformations found around F14 & Y15, in design of SpA-B mimetic small molecules are discussed.     

Conformational properties of the isolated 1–23 fragment of human hemoglobin α-chain

With the purpose of establishing whether, as a general rule, regions of a protein chain that are helical in the native structure maintain, at least partially, the same helical structure when isolated in solution, we have prepared the 1–23 fragment of human hemoglobin α-chain, and studied its conformational properties in aqueous solution by CD and¹H-NMR. From the analysis of CD and NMR spectral changes with temperature, salt and addition of trifluoroethanol (TFE) it can be concluded that the 1–23 peptide forms a measurable population (18% at 22°C (pH 5.6) TFE/H₂O, 30:70 (v/v)) of an α-helix structure that spans the same residues that are helical in the native protein (namely, 6 to 17). These results, taken together with similar ones obtained previously in the 1–19, 21–42 and 50–61 RNAase fragments, support the idea that no helices other than the native ones are actually formed in solution by protein fragments. This implies that the final helical structure of a protein is present from the very beginning of the folding process, and also that such elements of secondary structure can act as primary nucleation centers.     

Conformational aspects of HIV-1 integrase inhibition by a peptide derived from the enzyme central domain and by antibodies raised against this peptide.

Monospecific antibodies were raised against a synthetic peptide K159 (SQGVVESMNKELKKIIGQVRDQAEHLKTA) reproducing the segment 147-175 of HIV-1 integrase (IN). Synthesis of substituted and truncated analogs of K159 led us to identify the functional epitope reacting with antibodies within the C-terminal portion 163-175 of K159. Conformational studies combining secondary structure predictions, CD and NMR spectroscopy together with ELISA assays, showed that the greater is the propensity of the epitope for helix formation the higher is the recognition by anti-K159. Both the antibodies and the antigenic peptide K159 exhibited inhibitory activities against IN. In contrast, neither P159, a Pro-containing analog of K159 that presents a kink around proline but with intact epitope conformation, nor the truncated analogs encompassing the epitope, were inhibitors of IN. While the activity of antibodies is restricted to recognition of the sole epitope portion, that of the antigenic K159 likely requires interactions of the peptide with the whole 147-175 segment in the protein [Sourgen F., Maroun, R.G., Frère, V., Bouziane, A., Auclair, C., Troalen, F. & Fermandjian, S. (1996) Eur. J. Biochem. 240, 765-773]. Actually, of all tested peptides only K159 was found to fulfill condition of minimal number of helical heptads to achieve the formation of a stable coiled-coil structure with the IN 147-175 segment. The binding of antibodies and of the antigenic peptide to this segment of IN hampers the binding of IN to its DNA substrates in filter-binding assays. This appears to be the main effect leading to inhibition of integration. Quantitative analysis of filter-binding assay curves indicates that two antibody molecules react with IN implying that the enzyme is dimeric within these experimental conditions. Together, present data provide an insight into the structure-function relationship for the 147-175 peptide domain of the enzyme. They also strongly suggest that the functional enzyme is dimeric. Results could help to assess models for binding of peptide fragments to IN and to develop stronger inhibitors. Moreover, K159 antibodies when expressed in vivo might exhibit useful inhibitory properties.     

1H-nmr study of protected methionine homo-oligopeptides in helix-supporting environment

¹H-nmr spectra for a series of Boc-L -(Met)_n-OMe (n = 2–9) homo-oligopeptides have been observed in the helix-supporting solvent trifluoroethanol (TFE) at millimolar concentrations. Interfering solvent peaks were eliminated using two decoupling frequencies to selectively remove the methylene and hydroxyl protons of the solvent. Comparisons with specifically α-deuterated homo-oligopeptides gave complete assignments of the NH region of the Boc-Met_n-OMe oligomers up to the heptapeptide. Analysis of chemical shifts, coupling constants, and temperature dependence of chemical shifts suggests that up to the hexapeptide, similar structures exist in deuterochloroform and TFE. In contrast, nmr parameters at the heptapeptide for several internal residues differ in these solvents. These results suggest that a C₇ to α-helix transition may occur in TFE as the chain length of the methionine oligopeptides increases.     

Isolation of Taka-amylase A Peptides Required for Substrate Binding

An α-amylase from Aspergillus oryzae, Taka-amylase A (TAA), was cleaved into peptide fragments by an acid protease. Inactivation of TAA was greatly retarded by the addition of α-cyclodextrin or Ca²⁺. TAA peptide fragments were separated into two groups having no and high affinity to the substrate, soluble starch. This separation was done by the forced affinity chromatography method by a column of epichlorohydrin cross-linked soluble starch gel. Three peptides were isolated from the high-affinity fragments, purified by the ODS-120T column, and their amino acids were sequenced. Peptides I, II, and III originated from α2-helix, α3-helix, and β2-sheet, respectively, and all of these were located in the (β/α)₈ barrel of the main domain of TAA molecule. A stereo graphic view showed that Peptides I–III were at the cleft near the catalytic site. Occurrence of a Trp residue in all three peptides strongly suggested that Trp was very important in the binding of TAA to the substrate, soluble starch.     

Conformational properties of the proline region of porcine neuropeptide Y by CD and 1H-NMR spectroscopy

We synthesized porcine neuropeptide Y (pNPY) N-terminal fragments by solid-phase synthesis techniques and analyzed them for solution Conformational properties by CD and ¹H-nmr spectroscopy. The analogues pNPY_1–9 and pNPY_1–14 displayed CD spectra indicative of random structures and showed no evidence for induced α-helical structures in trifluoroethanol (TFE) up to 50%. However, the CD spectra of pNPY_1-9 suggested a Conformational shift in tetrahydrofuran. Although in aqueous solution the CD spectra of pNPY_1–21 indicated random structures with induction of only a small percentage of α-helix in aqueous TFE, pNPY_1-25 displayed 13% a-helical structure in aqueous solution that increased to 40 and 41% by the addition of TFE and methanol, respectively. The nmr spectra of pNPY_1-9 and the proline region of pNPY_1–25 indicated extended structures with all-trans conformers at Pro5 and Pro8 for pNPY_1–9 and at Pro5, Pro8, and Pro13 for pNPY_1–25; in each case the Tyrl-Pro2 amide bond was in both cis and trans conformations. However, observed nuclear Overhauser effect correlations and UN exchange experiments indicated an α-helical segment in pNPY_1–25 initiated by Pro 13 and extending from residues 14 to 25. Thus, the N-terminal polyproline region of NPY has no propensity to fold into a regular secondary structure, although Pro 13 is a helix initiator, a result consistent with the proposed role of this amino acid in the NPY structural model. © 1995 John Wiley & Sons, Inc.     

Trifluoroethanol‐containing RP‐HPLC mobile phases for the separation of transmembrane peptides human glycophorin‐A,integrin alpha‐1, and p24: analysis and prevention of potential side reactions due to formic acid

Reversed‐phase high‐pressure liquid chromatography analysis and purification of three hydrophobic, aggregation‐prone peptides, composed mainly of the transmembrane (TM) sequence, were performed using elution systems containing 2,2,2‐trifluoroethanol (TFE). The addition of 10–16% TFE to a common mobile phase, such as a water/acetonitrile/propanol (PrOH) or a water/PrOH/formic acid system, markedly improved the chromatographic separation of these peptides. The superior performance of TFE‐containing systems in separating peptides over water/PrOH/formic acid systems [Bollhagen R. et al., J. Chromatogr. A, 1995; 711 : 181–186.] clearly demonstrated that adding TFE to the mobile phase is one of best methods for TM‐peptide purification. Characterization of the potential side reactions using MALDI and ESI‐LIT/Orbitrap mass spectrometry indicated that prolonged incubation of peptides in a mixture of TFE–formic acid possibly induces O‐formylation of the Ser residue and N‐formylation of the N‐terminus of peptides. The conditions for selective removal of the formyl groups from TM peptides were also screened. We believe that these results will expand our ability to analyze and prepare hydrophobic, aggregation‐prone TM peptides and proteins. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.     

Solvent polarity-dependent structural refolding: A CD and NMR study of a 15 residue peptide

A close association between the HIV surface protein gp120 and the CD4 T cell receptor initiates the viral multiplication cycle. A 15 amino acid peptide (LAV) within the CD4 binding domain of gp 120 has been shown to retain receptor binding ability. The structural behavior of the LAV peptide has been studied by CD and NMR methods in aqueous solution and upon addition of trifluoroethanol (TFE) to emulate the relatively apolar conditions at the membrane bound receptor. Previous work has shown that the LAV peptide folds into a β-pleated structure in more polar buffer/TFE mixtures, while a concerted structural change can be observed at a concentration of 60% TFE (v/v). This abrupt, cooperative refolding from a regular β-sheet to a helical secondary structure is known as “switch” behavior. Former CD experiments with LAV sequence variants have supported the assumption that four amino acids at the N-terminus (LPCR) are indispensable for the “switch.” The tetrad has a strong β-turn forming potential. The suggestion has been formulated that the tetrad can act as a nucleation site governing the refolding. The present NMR study of the LAV peptide in TFE gives evidence for a 3₁₀-helix suggesting that the tetrad adopts a type III β-turn and promotes the formation of a similar bend in the next overlapping tetrad until the sequence is restructured into a 3₁₀-helix at a critical polarity favoring intrachain hydrogen bonds. © 1995 Wiley-Liss, Inc.     

Serial expression of the truncated fragments of the nucleocapsid protein of CCHFV and identification of the epitope region

The Crimean-congo hemorrhagic fever virus (CCHFV) is a geographically widespread fatal pathogen. Identification of the epitope regions of the virus is important for the diagnosis and epidemiological studies of CCHFV infections. In this study, expression vectors carrying series truncated fragments of the NP (nucleocapsid protein) gene from the S fragment of CCHFV strain YL04057 were constructed. The recombinant proteins were expressed in E.coli and purified for detection. The antigenic of the truncated fragments of NP was detected with a polyclonal serum (rabbit) and 2 monoclonal (mAbs) (14B7 and 43E5) against CCHFV by Western-blot analyses. The results showed that the three expressed constructs, which all contained the region 235AA to 305AA could be detected by mAbs polyclonal serum. The results suggest that region 235-305 aa of NP is a highly antigenic region and is highly conserved in the NP protein.     

Cytochrome c chimerae from natural and synthetic fragments: significance of the biological properties

Analogs of natural proteins have application in basic research, in medicine, and increasingly, in industry. Of the many methods developed for the fabrication of modified proteins, semisynthesis has so far been the most productive [R. E. Offord (1983) Proc. Eur. Peptide Symp., 17 31–42]. The technique of fragment-condensation semisynthesis takes as its basic raw material the native protein; fragments derived from it are manipulated by sequential degradation and resynthesis before recombination. While gene manipulation may overtake protein manipulation in general usefulness, certain types of analogs will remain accessible only by semisynthesis. Fragment condensation semisynthesis, as described above, has been used in preparing cytochrome c analogs [C. J. A. Wallace (1979) Proc. Am. Peptide Symp. 6 , 609–612]. To overcome the difficulty of replacing amino acids far from convenient cleavage sites, a number of variants of the method have also been used. These include fragment-specific chemical modification [C. J. A. Wallace & K. Rose (1983) Biochem. J. 215 , 651–658] and solid-phase synthesis of small [P. J. Boon, G. I. Tesser, H. H. K. Brinkhof & R. J. F. Nivard (1981) Proc. Eur. Peptide Symp. 16 , 127–130] or large fragments [L. E. Barstow, R. S. Young, E. Yakali, J. J. Sharp, J. C. O'Brien, P. W. Berman & H. A. Harbury (1977) Proc. Natl. Acad. Sci. USA 74 , 4148–4250]. The latter study gave low final recoveries, so we have prepared large peptides (38–42 residues) by classical solution methods. We have examined both their use in the reformation of the complete protein, and the physical and biochemical properties of the product analogs compared with those of the native proteins.     

Circular dichroism investigation of Escherichia coli adenylate kinase

We examined by circular dichroism (CD) spectroscopy in far- and near-ultraviolet three different molecular forms of Escherichia coli adenylate kinase: the wild type protein, the enzyme carboxymethylated at a single cysteine residue (Cys-77), and the thermosensitive adenylate kinase. The thermosensitive enzyme differs from the wild type protein in that a serine is substituted for a proline residue at position 87 (Gilles, A.-M., Saint Girons, I., Monnot, M., Fermandjian, S., Michelson, S., and Barzu, O. (1986) Proc. Natl. Acad. Sci. U. S. A., 83, 5798-5802). We also examined the CD spectra of isolated peptides resulting from chemical cleavage of adenylate kinase at Cys-77 (C1, residues 1-76; C2, residues 77-214). The secondary structure composition of wild type bacterial adenylate kinase (50% alpha-helix and 15% beta-sheet) was close to that derived from x-ray analysis of pig muscle enzyme (Schulz, G.E., Elzinga, M., Marx, F., and Schirmer, R. H. (1974) Nature 250, 120-123). Carboxymethylation of wild type protein did not greatly affect the CD spectrum. The secondary structure of the thermosensitive adenylate kinase was observed to be significantly different from that of the wild type enzyme (reduction in alpha-helix content to 39%). Changes in ellipticities at 222 nm as a function of temperature indicated that the melting temperature for thermosensitive adenylate kinase was 38 degrees C and that for the wild type enzyme was 54 degrees C. Isolated C1 and C2 peptides had a large proportion of unordered structures. When mixed, C1 and C2 fragments reassociated into structures resembling native, uncleaved adenylate kinase. The recovery of ordered structures, indicated by CD spectroscopy, paralleled the recovery of catalytic activity.     

Synthesis and conformation of a polyoxyethylene-bound undecapeptide of the alamethicin helix and (2-methylalanyl-L-alanine)1–7

The stepwise synthesis and conformational studies of the N-terminal helical partial sequence of the membrane-modifying polypeptide antibiotic alamethicin are described. The polyoxyethylen esters of the fragments N-t-Boc-L -Pro-Aib-Ala-Gln-Aib-Val-Aib-Gly-OH and N-Ac-Aib-L -Pro-Aib-Ala-Aib-Ala-Gln-Aib-Val-Aib-Gly-OH are synthesized using polyoxyethylene (molecular mass 10,000) as solubilizing support. CD spectra of each intermediate in ethanol show α-helix formation of the N-protected peptide polymers beginning with the nonapeptide and of the N-protonated sequences beginning with the decapeptide. Compared to the helix of alamethicin, temperature- and solvent-dependent CD measurements indicate analogous conformational behavior. The results suggest that in lipophilic media the alamethicin helix can extend the full length of the partial sequence between the two proline residues and that aqueous media favor an increase of random-coil conformation. For model studies of the particular lipid interaction of alamethicin, the stepwise synthesis of peptides with the alternating (Aib-L -Ala)_n sequence (n = 1–7) was carried out on a polyoxyethylene support (molecular mass 6000). CD and ORD studies in ethanol showed a change from the random coil to a right-handed α-helix with increasing peptide length. This change is observed for the N-protected peptides at a chain length of 8 residues and for the N-protonated peptides at a length of 9 residues. The comparison of the CD data of free and polyoxyethylene-bound peptides revealed that the solubilizing polymeric support cannot induce conformational changes. The intensities of the CD bands of t-Boc-(Aib-L -Ala)_n-OPOE (n ≥ 6) are higher than those of alamethicin, and these model peptides show similar temperature and solvent inducible changes of their helix contents.     

A CD and an nmr study of multiple bradykinin conformations in aqueous trifluoroethanol solutions

CD and nmr studies have been carried out on aqueous trifluoroethanol (TFE) solutions of bradykinin (BK) and a bradykinin antagonist. The CD results exhibit a striking effect of TFE on the spectra of BK, with sequence Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg, and the BK antagonist, with sequence D -Arg-Arg-Pro-Hyp-Gly-Thi-D -Ser-D -Cpg-Cpg-Arg [where Hyp is 4-hydroxy-L -proline; Thi refers to β-(2-thienyl)-L -alanine and Cpg refers to α-cyclopentylglycine]. The effect of increasing concentration of TFE in water on the difference ellipticity at 222 nm was examined and showed that BK may be a mixture of at least two different conformers, one of which largely forms when the TFE concentration is increased beyond 80%. The linear extrapolation of 100% of the difference ellipticity of BK at low TFE concentrations yields a value in agreement with that shown by the BK antagonist, indicating that the conformation of BK at the lower TFE concentrations is similar to that of the BK antagonist. The conformational analysis was carried out using both one-dimensional and two-dimensional ¹H-nmr techniques. The total correlation spectroscopy (TOCSY) spectrum of BK in a 60/40% (v/v) TFE/H₂O solution at 10°C and a nuclear Overhauser effect spectroscopy (NOESY) spectrum that shows only sequential H_α(i) – NH(i + 1) or the H_α(i) – H_δδ′(i + 1) NOEs indicate that the majority of the molecules adopt an all-trans extended conformation. The TOCSY for BK in the 95/5% (v/v) TFE/H₂O solution shows that there are two major conformations in the solution with about equal population. The NOESY experiment shows two new important cross peaks for one conformation, namely Pro²(α)-Pro³ (α) and the Pro²(α)-Gly⁴(NH), indicating a cis Pro²-Pro³ bond and a type VI β-turn between residues Arg¹ and Gly⁴ involving cis proline at position 3, respectively. The low temperature coefficient of Gly⁴ for this conformation suggests the presence of an intramolecular hydrogen bond, therefore a type VIa β-turn is present. The other conformation is all trans and extended. The BK antafonist shows difference CD spectra in TFE solutions referred to H₂O that are superficially indicative of a β-bend. However, nmr speaks against this possibility, as only one set of peaks were observed in the TOCSY and NOESY experiments, indicating an all-trans extended confirmation over the range of TFE concentrations. The BK-antagonist CD data suggest that solvent perturbation of the CD of an extended confirmation perturbation of the optical activity of the thienyl moiety of the peptide since the CD spectrum of N-acetyl-β-thienyl-L -alanine N-methylamide is strongly perturbed by TFE. The present results again demonstrate the complementary relationship between CD and nmr. © 1994 John Wiley & Sons, Inc.     

Induction of Helical Conformation in all β-sheet Proteins by Trifluoroethanol

Abstract

The effect of 2,2,2-Trifluoroethanol (TFE) on the structure of five all β-sheet proteins, isolated from the venom of the Taiwan cobra (Naja naja atra), is studied. In all the toxins used, it is observed that significant amount of α-helix is induced at higher concentrations of TFE. In all these proteins, the induction of helical conformation and disruption of the tertiary structure seem to occur simultaneously. The structural transitions induced by TFE in reduced and denatured protein appear to be different from those observed in the native protein(s). In our opinion, the findings reported herein could have significant implications on research in the area of protein folding.     

Far ultraviolet optical rotatory properties of poly-L-tryptophan. I

A block copolymer [γ-Et-DL -Glu]_m [L -Trp]_n was prepared using N-carboxy anhydrides (NCA) of L -tryptohan and γ-ethyl DL -glutamate. The block copolymer, dissolved in trifluoroethanol (TFE)–dichloroacetic acid (DCA) mixtures, exhibited a sharp change in the specific rotation at 546 mμ when the solvent composition reached 70–75% DCA content. Optical rotatory dispersion (ORD) and circular dichroism (CD) measurement were carried out in TFE solution in the spectral range 180–350 mμ. Indole side-chain chromophores were found to be optically active in the polymer. On the other hand, these groups exhibit very small optical activity in the model compound C₆H₃? CH₂? O? CO? (L -Trp)₂? O? CH₃. Indole groups therefore appear to be in a dissymmetric environment only in the polymer. From these data it was concluded that poly-L -Trp is in some type of helical conformation in TFE. Strong overlapping of CD bands from side-chain chromophores and peptides chromophores in the wavelength range 185–240 mμ does not allow definite conclusions to be drawn about the type of helical conformation which exists in poly-L -Trp in TFE solution.     

Evidence for an alpha-helix --> pi-bulge helicity modulation for the neu/erbB-2 membrane-spanning segment. A 1H NMR and circular dichroism study

The 35-residue peptide corresponding to the very hydrophobic transmembrane region of the tyrosine kinase receptor neu, Neu(TM35), has been synthesized. The peptide can be solubilized in millimolar concentrations in TFE or incorporated into an SDS-water micellar solution or into well-hydrated DMPC/DCPC bicelles. In all these media, circular dichroism demonstrated that the peptide adopts a helical structure for about 80% of its amino acids. The peptide is monomeric below 2 mM in TFE, as also determined by variable concentration experiments. The three-dimensional solution structure in TFE has been obtained by homonuclear proton NMR and shows a well-defined alpha-helix from residues 4 to 21, then a pi-bulge from Ile(22) to Gly(28), and a final short alpha-helix from positions 29 to 32. This experimental finding is in agreement with structures predicted recently by molecular dynamics calculations in a vacuum [Sajot, N., and Genest, M. (2000) Eur. Biophys. J. 28, 648-662]. The biological implications of a possible retention of this structure in a membrane environment are finally discussed.     

Conformational mapping of the N-terminal peptide of HIV-1 gp41 in membrane environments using C-enhanced Fourier transform infrared spectroscopy

The N-terminal domain of HIV-1 glycoprotein 41?000 (FP; residues 1-23; AVGIGALFLGFLGAAGSTMGARSCONH₂) participates in fusion processes underlying virus-cell infection. Here, we use physical techniques to study the secondary conformation of synthetic FP in aqueous, structure-promoting, lipid and biomembrane environments. Circular dichroism and conventional, ¹²C-Fourier transform infrared (FTIR) spectroscopy indicated the following α-helical levels for FP in 1-palmitoyl-2-oleoylphosphatidylglycerol (POPG) liposomes∼hexafluoroisopropanol (HFIP)>trifluoroethanol (TFE)>phosphate-buffered saline (PBS). ¹²C-FTIR spectra also showed disordered FP structures in these environments, along with substantial β-structures for FP in TFE or PBS. In further experiments designed to map secondary conformations to specific residues, isotope-enhanced FTIR spectroscopy was performed using a suite of FP peptides labeled with ¹³C-carbonyl at multiple sites. Combining these ¹³C-enhanced FTIR results with molecular simulations indicated the following model for FP in HFIP: α-helix (residues 3-16) and random and β-structures (residues 1-2 and residues 17-23). Additional ¹³C-FTIR analysis indicated a similar conformation for FP in POPG at low peptide loading, except that the α-helix extends over residues 1-16. At low peptide loading in either human erythrocyte ghosts or lipid extracts from ghosts, ¹³C-FTIR spectroscopy showed α-helical conformations for the central core of FP (residues 5-15); on the other hand, at high peptide loading in ghosts or lipid extracts, the central core of FP assumed an antiparallel β-structure. FP at low loading in ghosts probably inserts deeply as an α-helix into the hydrophobic membrane bilayer, while at higher loading FP primarily associates with ghosts as an aqueous-accessible, β-sheet. In future studies, ¹³C-FTIR spectroscopy may yield residue-specific conformations for other membrane-bound proteins or peptides, which have been difficult to analyze with more standard methodologies.