The membrane topology of the amino-terminal domain of the red cell calcium pump

A systematic study of the membrane-associated regions in the plasma membrane Ca2+ pump of erythrocytes has been performed by hydrophobic photolabeling. Purified Ca2+ pump was labeled with 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)-diazirine ([125I]TID), a generic photoactivatable hydrophobic probe. These results were compared with the enzyme labeled with a strictly membrane-bound probe, [3H]bis-phosphatidylethanolamine (trifluoromethyl) phenyldiazirine. A significant light-dependent labeling of an M(r) 135,000-140,000 peptide, corresponding to the full Ca2+ pump, was observed with both probes. After proteolysis of the pump labeled with each probe and isolation of fragments by SDS-PAGE, a common pattern of labeled peptides was observed. Similarly, labeling of the Ca2+ pump with [125I]TID, either in isolated red blood cell membranes or after the enzyme was purified, yields a similar pattern of labeled peptides. Taken together, these results validate the use of either probe to study the lipid interface of the membrane-embedded region of this protein, and sustain the notion that the conformation of the pump is maintained throughout the procedures of solubilization, affinity purification, and reconstitution into proteoliposomes. In this work, we put special emphasis on a detailed analysis of the N-terminal domain of the Ca2+ pump. A labeled peptide of M(r) 40,000 belonging to this region was purified and further digested with V8 protease. The specific incorporation of [125I]TID to proteolytic fragments pertaining to the amino-terminal region indicates the existence of two transmembrane stretches in this domain. A theoretical analysis based on the amino acid sequence 1-322 predicts two segments with high probability of membrane insertion, in agreement with the experimental data. Each segment shows a periodicity pattern of hydrophobicity and variability compatible with alpha-helical structure. These results strongly suggest the existence of a transmembrane helical hairpin motif near the N-terminus of the Ca2+ pump.     

Interaction of the receptor binding domains of Pseudomonas aeruginosa pili strains PAK, PAO, KB7 and P1 to a cross-reactive antibody and receptor analog: implications for synthetic vaccine design

The four synthetic peptide antigens, PAK 128-144, PAO 128-144, KB7 128-144 and P1 126-148, correspond in amino acid sequence to the C-terminal receptor binding regions of four strains (PAK, PAO, KB7, P1) of Pseudomonas aeruginosa pilin. The NMR solution structures of the trans forms of the peptides show conserved beta-turns which have been implicated in antibody and receptor recognition. The interactions between these peptides and a cross-reactive monoclonal antibody, PAK-13, have been studied using two-dimensional (1)H NMR spectroscopy in order to map the antigenic determinants recognized by the antibody. Residues for which spectral changes were observed upon antibody binding differed from peptide to peptide but were mostly confined to one or both of the turn regions and to the hydrophobic pockets. Conformational changes in the beta-turns and hydrophobic pockets of these peptides upon antibody binding were also monitored by examination of the pattern of nuclear Overhauser effects (NOEs) versus transferred nuclear Overhauser effects (TRNOEs) for the free versus the bound peptides. Although TRNOEs developed strongly between side chain resonances in the hydrophobic pockets of the peptides, no additional backbone TRNOEs were observed in the presence of antibody, suggesting no major conformational changes in the secondary structures of the peptides upon binding. This implies a flexible antibody combining site, a feature which is discussed with respect to cross-reactivity, strain specificity, and the design of a synthetic peptide vaccine effective against a broad spectrum of P. aeruginosa strains. The binding of the PAK peptide to a disaccharide receptor analog, (beta GalNAc(1-4)beta Gal), was also studied using (1)H NMR in order to map the "adhesintope" recognized by the receptor. Spectral changes observed in the peptide spectrum with the binding of receptor were similar to those seen for the binding of antibody, suggesting that the epitope recognized by the antibody is structurally coincident with the adhesintope recognized by the receptor. The relevancy of this result is discussed with respect to immunogenicity versus pathogenicity, and the proper design of a vaccine which could prevent the mutational escape of the pathogen away from the host's defence systems.     

Substrate specificity of mammalian prenyl protein-specific endoprotease activity

We have previously identified proteolytic activity in rat liver microsomes that cleaves an intact tripeptide, VIS, from S-farnesylated-CVIS tetrapeptide. This enzymatic activity, termed prenyl protein-specific endoprotease (PPEP) activity, has been solubilized in CHAPS and purified 5-fold. To probe the peptide recognition features of PPEP activity, 64 tripeptides [N-acetyl-C(S-farnesyl)a1a2] were prepared and tested as competitive inhibitors of PPEP activity-catalyzed hydrolysis of N-acetyl-C(S-farnesyl)VI[3H]S. It was found that PPEP activity prefers large hydrophobic residues in the a1 and a2 positions. A subset of N-acetyl-C(S-farnesyl)a1a2 peptides were prepared in radiolabeled form, and it was found that PPEP activity preferences for these substrates correlated well in most cases with the inhibition data. The exception is that R in the a1 position does not prevent binding of peptide to PPEP activity, but such peptides are poor substrates. The anionic residue D in the a2 position is not tolerated by PPEP activity. Five farnesylated radiolabeled tetrapeptides, Ac-C(F)FM[3H]L, Ac-C(F)LI[3H]L, Ac-C(F)LL[3H]L, Ac-C(F)LM[3H]L, and Ac-C(F)VI[3H]L were prepared, and PPEP activity kinetic studies revealed that they are good substrates and show comparable KM values (2.2-13.5 microM). Ac-C(F)RL[3H]S is a poor substrate. The reported peptide binding preferences of PPEP activity should be useful in designing compounds that block the C-terminal proteolysis of prenylated proteins. Nonprenylated peptides do not bind to PPEP activity, and replacement of the farnesyl group with ann-pentadecyl group modestly reduces binding. Peptide-membrane partitioning studies were used together with theoretical arguments to fully understand the substrate specificity of PPEP activity toward these compounds.     

The MHC of a broiler chicken line: serology, B-G genotypes, and B-F/B-LB sequences

The tumor suppresser protein p53 has been called the "guardian of the genome." DNA damage induces p53 to either halt the cell cycle, allowing for repair, or initiate apoptosis. P53 is mutated in over 50% of human tumors and it has been proposed that many tumorigenic mutations are deleterious to p53 because they induce local unfolding. To explore this hypothesis, peptide models have been developed to study tumorigenic mutations in the H2 helix of the p53 core domain. This helix is rich with charged residues and is a key component of the DNA binding region. A 16-residue peptide corresponding to the H2 wild-type sequence extended with an Ala-rich C-terminus was synthesized and studied by 1H-nmr (500 MHz) and CD. The nmr studies demonstrate that this peptide adopts helical structure in solution. Six additional peptides corresponding to subtle tumorigenic mutations were synthesized and CD was used to assess the relative stability of these "mutant analogues." All six mutations studied are destabilizing relative to the wild type, with delta delta G values in the range of 0.26 to 1.35 kcal mol-1. Surprisingly, substitution of Asp 281 with Ala resulted in a peptide with the greatest destabilization even though Ala possesses the largest helix propensity of the common 20 amino acids. Because this helix appears to be stabilized mainly by local electrostatics, we conclude that its structure is susceptible to even the most conservative mutations. These results provide support for the hypothesis that tumorigenic mutations induce local unfolding of p53.     

High-resolution mono- and multidimensional magic angle spinning 1H nuclear magnetic resonance of membrane peptides in nondeuterated lipid membranes and H2O

High-speed (14 kHz) solid-state magic angle spinning (MAS) 1H NMR has been applied to several membrane peptides incorporated into nondeuterated dilauroyl or dimyristoylphosphatidylcholine membranes suspended in H2O. It is shown that solvent suppression methods derived from solution NMR, such as presaturation or jump-return, can be used to reduce water resonance, even at relatively high water content. In addition, regioselective excitation of 1H peptide resonances promotes an efficient suppression of lipid resonances, even in cases where these are initially two orders of magnitude more intense. As a consequence, 1H MAS spectra of the peptide low-field region are obtained without interference from water and lipid signals. These display resonances from amide and other exchangeable 1H as well as from aromatic nonexchangeable 1H. The spectral resolution depends on the specific types of resonance and membrane peptide. For small amphiphilic or hydrophobic oligopeptides, resolution of most individual amide resonance is achieved, whereas for the transmembrane peptide gramicidin A, an unresolved amide spectrum is obtained. Partial resolution of aromatic 1H occurs in all cases. Multidimensional 1H-MAS spectra of membrane peptides can also be obtained by using water suppression and regioselective excitation. For gramicidin A, F2-regioselective 2D nuclear Overhauser effect spectroscopy (NOESY) spectra are dominated by intermolecular through-space connectivities between peptide aromatic or formyl 1H and lipid 1H. These appear to be compatible with the known structure and topography of the gramicidin pore. On the other hand, for the amphiphilic peptide leucine-enkephalin, F2-regioselective NOESY spectra mostly display cross-peaks originating from though-space proximities of amide or aromatic 1H with themselves and with aliphatic 1H. F3-regioselective 3D NOESY-NOESY spectra can be used to obtain through-space correlations within aliphatic 1H. Such intrapeptide proximities should allow determination of the conformation of the peptide in membranes. It is suggested that high-speed MAS multidimensional 1H NMR of peptides in nondeuterated membranes and in H2O can be used for studies of both peptide structure and lipid-peptide interactions.     

Purification and characterization of a male-specific protein in the hemolymph of the wax moth, Galleria mellonella L

The aim of the current study was to determine whether immunization with synthetic peptides corresponding to the joining region segment of p210 bcr-abl chimeric protein can elicit CD8+ cytotoxic T lymphocytes (CTLs) capable of specifically lysing leukemia cells. BALB/c mice were immunized with peptides identical to the joining region segment of p210 bcr-abl protein. Class I major histocompatibility complex (MHC)-restricted bcr-abl peptide-specific CD8+ CTLs were elicited. The CTL clones were H-2 Kd restricted and specifically recognized a nonamer peptide of the combined sequence of bcr-abl amino acids but neither bcr nor abl amino acid sequence alone. Despite specificity and substantial lytic potential against syngeneic cell line incubated with exogenously supplied peptides, the bcr-abl peptide-specific CTLs failed to lyse syngeneic murine leukemia cells expressing human p210 bcr-abl protein containing the same bcr-abl joining region peptide sequence. Similarly, the bcr-abl peptide-specific CTLs did not lyse human bcr-abl-positive chronic myelogenous leukemia cells expressing murine class I MHC antigen (i.e., K562 cells infected with vaccinia virus expressing H-2 Kd). The appropriateness of the joining region segment of bcr-abl protein to serve as a T cell target depends upon whether that segment is presented by class I MHC in a concentration high enough to stimulate CTLs. The current experiments using murine peptide-specific CTLs could not establish that the joining region of bcr-abl protein is processed and presented by class I MHC antigen-processing pathway, but the possibility was not ruled out. Alternative models and/or strategies are necessary.     

Structure effects of double D-amino acid replacements: a nuclear magnetic resonance and circular dichroism study using amphipathic model helices

D-Amino acid replacements and the determination of resulting structural changes are a useful tool to recognize amphipathic helices in biologically active peptides such as neuropeptide Y and corticotropin-releasing factor. In this paper the secondary structures of one amphipathic alpha-helical peptide and its double D-amino acid analog have been determined by means of 1H NMR and CD spectroscopies under equivalent conditions. The chemical shifts (NH and C alpha H) and the analysis of nuclear Overhauser effects show a split of the continuous helix for the all-L peptide into two helices at the position of double D-amino acid replacement. Hydrogen exchange rates correlate with water accessibilities in the hydrophobic/hydrophilic face and confirm the amphipathic helical structure in the all-L peptide as well as in its double D-amino acid analog. A significantly accelerated hydrogen isotope exchange rate is observed for the D-Ala9 backbone proton, implying an increased flexibility at that position. These results show that the incorporation of an adjacent pair of D-amino acids only causes a local change in structure and flexibility, which makes the double D replacement interesting as a tool for specific helix-disturbing modifications to search for helical conformations in biologically active peptides.     

Peptide models of local and long-range interactions in the molten globule state of human alpha-lactalbumin

alpha-Lactalbumin, a small calcium-binding protein, forms an equilibrium molten globule state under a variety of conditions. A set of four peptides designed to probe the role of local interactions and the role of potential long-range interactions in stabilizing the molten globule of alpha-lactalbumin has been prepared. The first peptide consists of residues 20 through 36 of human alpha-lactalbumin and includes the entire B-helix. This peptide is unstructured in solution as judged by CD. The second peptide is derived from residues 101 through 120 and contains both the D and 310 helices. When this peptide is crosslinked via the native 28 to 111 disulfide to the B-helix peptide, a dramatic increase in helicity is observed. The crosslinked peptide is monomeric, as judged by analytical ultracentrifugation. The peptide binds 1-anilinonaphthalene-8-sulphonate (ANS) and the fluorescence emission maximum of the construct is consistent with partial solvent exposure of the tryptophan residues. The peptide corresponding to residues 101 to 120 adopts significant non-random structure in aqueous solution at low pH. Two hydrophobic clusters, one involving residues 101 through 104 and the other residues 115 through 119 have been identified and characterized by NMR. The hydrophobic cluster formed by residues 101 through 104 is still present in a smaller peptide containing only residues 101 to 111 of alpha-lactalbumin. The cluster also persists in 6 M urea. A non-native, pH-dependent interaction between the Y103 and H107 side-chains that was previously identified in the acid-denatured molten globule state was examined. This interaction was found to be more prevalent at low pH and may therefore be an example of a local interaction that stabilizes preferentially the acid-induced molten globule state.     

T cells specific for a polymorphic segment of CD45 induce graft-versus-host disease with predominant pulmonary vasculitis

To study the character of graft-vs-host disease (GVHD) induced by T cells specific for hemopoietic cells, T cells specific for a polymorphic segment of CD45 were transferred into CD45 congenic mice. C57BL/6 mice that express the CD45b allele were immunized with a 13 mer peptide representing the polymorphic segment (p257-268) of CD45a protein. Conversely, C57BL/6 mice congenic for CD45a were immunized with the CD45b peptide. CD4+ T cells specific for allelic CD45 peptides were elicited. Importantly, T cells specific for CD45 peptides proliferated specifically and vigorously in response to spleen cells expressing the appropriate polymorphic CD45 protein. T cells specific for CD45 induced a substantial graft-vs-host response (GVHR) with predominant early pulmonary vasculitis and later more widespread interstitial mononuclear cell infiltration and alveolitis. No GVHR was induced in bone marrow chimeras expressing only donor hemopoietic cells. Thus, donor T cell recognition of host hemopoietic cells is sufficient to elicit GVHR, but the classical skin, liver, and gut manifestations of GVHD were not observed. The CD45-specific T cells used secreted Th1 cytokines, but without detectable soluble IL-2. Studies using CD45-specific T cells with different effector functions might allow further dissection of donor cell requirements for GVHD syndromes.     

Modified phage peptide libraries as a tool to study specificity of phosphorylation and recognition of tyrosine containing peptides

Tyrosine phosphorylation and protein recognition, mediated by phosphotyrosine containing peptides, play an important role in determining the specific response of a cell, when stimulated by external signals. We have used peptide repertoires displayed by filamentous phage as a tool to study the substrate specificity of the protein tyrosine kinase (PTK) p55(fyn) (Fyn). Peptide libraries were incubated for a short time in the presence of Fyn and phages displaying efficiently phosphorylated peptides were selected by panning over anti-phosphotyrosine antibodies. The characterization of the peptides enriched after three phosphorylation/selection rounds allowed us to define a canonical substrate sequence for the kinase Fyn, E-(phi/T)YGx phi, where phi represents any hydrophobic residue. A peptide conforming to this sequence is a better substrate than a second peptide designed to be in accord with the consensus sequence recognised by the Fyn SH2 domain. When the library phosphorylation reaction is carried out in saturation conditions, practically all the tyrosine containing peptides are phosphorylated, irrespective of their context. These "fully modified" peptide libraries are a valuable tool to study the specificity of phosphotyrosine mediated protein recognition. We have used this new tool to identify a family of peptides that bind the PTB domain of the adapter protein Shc. Comparison of the peptide sequences permits us to confirm the essential role of N at position -3, while P often found at position -2 in natural targets is not absolutely required. Furthermore, our approach permits us to reveal an "extended" consensus indicating that residues that do not seem to influence binding in natural peptides can make productive contacts, at least in linear peptides.     

Structural studies on the effects of the deletion in the red cell anion exchanger (band 3, AE1) associated with South East Asian ovalocytosis

We have carried out a solution-state NMR study of synthetic peptides patterned on the first membrane span of normal human band 3, and the same region of the mutant band 3 present in Southeast Asian ovalocytosis (SAO) which has a nine amino acid deletion. In 1:1 (v/v) chloroform/methanol, the 42 residue normal peptide (R389-K430) consisted of three helical regions. The slow solvent exchange of backbone amide protons revealed the helix from P403 to A416 was more stable than the "cytoplasmic" N-terminal helix from P391 to A400. These helices were separated by a sharp bend at P403, which is probably located at the boundary between the cytoplasmic domain and the first transmembrane span. The SAO deletion (A400-A408) removed the bend at P403, to leave a stable helix from P391 to A416 containing the residuum of the normal first transmembrane helix and with a hydrophobic turn replaced by a polar turn in the SAO peptide. Insertion of fragments of normal band 3 and band 3 SAO into microsomal membranes was investigated using a cell free translation system. A fragment composed of the cytoplasmic domain and the putative first membrane domain of normal band 3 (B3(1)) inserted stably into the membrane. However, the corresponding fragment of band 3 SAO [SAO(1)] did not integrate stably into membranes. Our results suggest that in SAO band 3, the region of the first membrane span of normal band 3 does not integrate properly into the membrane because it lacks a sufficiently long hydrophobic segment, and the deletion also disrupts a conserved structural subdomain at the membrane surface.     

Contribution of the hydrophobicity gradient of an amphipathic peptide to its mode of association with lipids

A class of peptides that associate with lipids, known as oblique-orientated peptides, was recently described [Brasseur R., Pillot, T., Lins, L., Vandekerckhove, J. & Rosseneu, M. (1997) Trends Biochem. Sci. 22, 167-171]. Due to an asymmetric distribution of hydrophobic residues along the axis of the alpha-helix, such peptides adopt an oblique orientation which can destabilise membranes or lipid cores. Variants of these oblique peptides, designed to have an homogeneous distribution of hydrophobic and hydrophilic residues along the helical axis, are classified as regular amphipathic peptides. These peptides are expected to lie parallel to the polar/apolar interface with their hydrophobic residues directed towards the apolar and their hydrophilic residues towards the polar phase. An hydrophobic, oblique-orientated peptide was identified at residues 56-68 in the sequence of the lecithin-cholesterol acyltransferase (LCAT), enzyme. This peptide is predicted to penetrate a lipid bilayer at an angle of 40 degrees through its more hydrophobic C-terminal end and thereby induce the destabilisation of a membrane or a lipid core. The LCAT-(56-68) wild-type peptide was synthesised together with the LCAT-(56-68, 0 degrees) variant, in which the hydrophobicity gradient was abolished through residue permutations. In two other variants, designed to keep their oblique orientation, the W61 residue was shifted either towards the more hydrophilic N-terminal at residue 57, or to position 68 at the hydrophobic C-terminal end of the peptide. Peptide-induced vesicle fusion was demonstrated by fluorescence measurements using pyrene-labeled vesicles and by monitoring of vesicle size by gel filtration. The interaction between peptides and lipids was monitored by measurement of the intrinsic tryptophan fluorescence emission of the peptides. Fluorescence polarisation measurements, using diphenyl hexatriene, were carried out to follow changes in the lipid fluidity. The LCAT-(56-68) wild-type peptide and the two oblique variants, induced fusion of unilamellar dimyristoylglycerophosphocholine vesicles. Tryptophan fluorescence emission measurements showed a 12-14 nm blue shift upon addition of the wild-type peptide and of the W61-->68 variant to lipids, whereas the fluorescence of the W61-->57 variant did not change significantly. This observation supports the insertion of the more hydrophobic C-terminal residues into the lipid phase, as predicted by the theoretical calculations. In contrast, the 0 degrees variant peptide had no fusogenic activity, and it associated with lipids to form small discoidal lipid/peptide complexes. The phospholipid transition temperature was decreased after addition of the wild-type, the W61-->68 and W61-->57 fusogenic peptides, whereas the opposite effect was observed with the 0 degrees variant. The behaviour of the wild-type and variant LCAT-(56-68) peptides stresses the contribution of the hydrophobicity gradient along the axis of an amphipathic peptide to the mode of association of this peptide with lipids. This parameter consequently influences the structural modifications occurring to lipids upon association with amphipathic peptides.     

Secondary structure analysis of individual transmembrane segments of the nicotinic acetylcholine receptor by circular dichroism and Fourier transform infrared spectroscopy

Circular dichroism (CD) and attenuated total reflection Fourier transform infrared (ATR-FTIR) spectroscopy are used to establish the secondary structure of peptides containing one or more transmembrane segments (M1-M4) of the Torpedo californica nicotinic acetylcholine receptor (AChR). Peptides containing the M2-M3 and M1-M2-M3 transmembrane segments of the AChR beta-subunit and the M4 segment of the alpha- and gamma-subunits were isolated from proteolytic digests of receptor subunits, purified, and reconstituted into lipid vesicles. For each peptide, an amide I vibrational frequency centered between 1650 and 1656 cm-1 and negative CD absorption bands at 208 and 222 nm indicate that the peptide is largely alpha-helical. In addition, the CD spectrum of a tryptic peptide of the alpha-subunit containing the M1 segment is also consistent with a largely alpha-helical structure. However, secondary structure analysis of the alpha-M1 CD spectrum indicates the presence of other structures, suggesting that the M1 segment may represent either a distorted alpha-helix, likely the consequence of several proline residues, or may not be entirely alpha-helical. Overall, these findings are consistent with studies that indicate that the transmembrane region of the AChR comprises predominantly, if not exclusively, membrane-spanning alpha-helices.     

Peptide hydrophobicity controls the activity and selectivity of magainin 2 amide in interaction with membranes

The magainins are antibacterial peptides from the skin of Xenopus laevis. They show a broad range of activity against prokaryotic cells but lyse eukaryotic cells poorly. To elucidate the influence of peptide hydrophobicity on membrane activity and selectivity, we designed and synthesized analogs of magainin 2 amide with slightly varying hydrophobicities but retained hydrophobic moment, peptide charge, and angle subtended by the hydrophilic helix region. Circular dichroism investigations of the peptides revealed that all peptides investigated adopt an alpha-helical conformation when bound to phospholipid vesicles. Dye-releasing experiments from vesicles of phosphatidylglycerol (PG) showed that the membrane-permeabilizing activity of the analogs is not influenced by peptide hydrophobicity. In contrast, the permeability-enhancing activity on vesicles bearing high amounts of phosphatidylcholine (PC) increases drastically with enhanced peptide hydrophobicity, resulting in a reduced selectivity of more hydrophobic analogs for negatively charged membranes. Likewise, the peptide affinity to PC-rich membranes increases in the order of hydrophobicity. Correlation of peptide binding and membrane permeabilization of PC/PG (3:1) vesicles revealed that the observed differences in peptide activity on membranes of low negative surface charge are mainly caused by the different binding affinities. The antibacterial and hemolytic activity of the peptides increases with enhanced hydrophobicity. A strong correlation was found between the hemolytic effect and the bilayer-permeabilizing activity against PC-rich vesicles. Whereas the antibacterial specificity of the more hydrophobic analogs is retained for Escherichia coli, the specificity for Pseudomonas aeruginosa decreases with increasing hydrophobicity.     

Isolation and characterization of murine clonogenic osteoclast progenitors by cell surface phenotype analysis

MHC class I molecules bind short peptides for presentation to CD8+ T cells. The determination of the three-dimensional structure of various MHC class I complexes has revealed that both ends of the peptide binding site are composed of polar residues conserved among all human and murine MHC class I sequences, which act to lock the ends of the peptide into the groove. In the rat, however, differences in these important residues occur, suggesting the possibility that certain rat MHC class I molecules may be able to bind and present longer peptides. Here we have studied the peptide length preferences of two rat MHC class Ia molecules expressed in the TAP2-deficient mouse cell line RMA-S: RT1-A1c, which carries unusual key residues at both ends of the groove, and RT1.Aa which carries the canonical residues. Temperature-dependent peptide stabilization assays were performed using synthetic random peptide libraries of different lengths (7-15 amino acids) and successful stabilization was determined by FACS analysis. Results for two naturally expressed mouse MHC class I molecules revealed different length preferences (H2-Kb, 8-13-mer and H2-Db, 9-15-mer peptides). The rat MHC class Ia molecule, RT1-Aa, revealed a preference for 9-15-mer peptides, whereas RT1-A1c showed a more stringent preference for 9-12-mer peptides, thereby ruling out the hypothesis that unusual residues in rat MHC molecules allow binding of longer peptides.     

Spectroscopic studies of the interaction of Ca2+-ATPase-peptides with dodecyl maltoside and its brominated analog

The transmembrane sector of sarcoplasmic reticulum Ca2+-ATPase comprises ten putative transmembrane spans (M1-M10) in current topology models. We report here the structure and properties of three synthetic peptides with a single Trp representing the M6 and M7 regions implicated in Ca2+ binding: peptide M6 (amino acid residues 785-810), peptide M7-L (amino acid residues 808-847) corresponding to loop 6-7 and the majority of span M7, and peptide M7-S (amino acid residues 818-847) which contains a shorter version of loop 6-7 than M7-L. After uptake of the peptides in the hydrophobic environment of dodecyl maltoside micelles, the peptides gain a significant amount of secondary structure, as indicated by their CD spectra. However, the alpha-helical content of M6 is lower than would be expected for a classical transmembrane segment. For M7-L peptide, the L6-7 loop is subject to specific proteolytic cleavage by proteinase K, as in intact Ca2+-ATPase. The formation of the peptide-detergent complexes was followed from the resulting fluorescence intensity changes, either enhancement using n-dodecyl beta-D-maltoside or quenching using the recently introduced brominated analog of n-dodecyl beta-D-maltoside: 7,8-dibromododecyl beta-maltoside [de Foresta, B., Legros, N., Plusquellec, D., le Maire, M. & Champeil, P. (1996) Eur J. Biochem. 241, 343-354]. Our results indicate that M7-L and M7-S are completely taken up by the detergent micelles. In contrast, the M6 peptide, which is highly water soluble, is more loosely associated with the detergent, as is also demonstrated by size-exclusion chromatography. The location of Trp in micelles was evaluated from the quenching observed in mixed micelles of n-dodecyl beta-D-maltoside/7,8-dibromododecyl beta-maltoside, using tryptophan octyl ester and solubilized Ca2+-ATPase as reference compounds. We conclude that W832 in M7 appears to be located near the surface of the micelle, in agreement with its membrane interfacial localization predicted in most Ca2+-ATPase topology models. In contrast, our data suggest that W794 in M6 has a deeper insertion in the micelle although not to the extent predicted by current models of Ca2+-ATPase and the rather short alpha-helix span of M6 may lead to exposure of a significant part of the C-terminal of this peptide to the micelle surface. The results are discussed in relation to the proposed roles of these membrane segments in active transport of Ca2+ ions, in particular, the demonstration that M6 does not behave as a classical transmembrane helix may be correlated with the evidence, from site-directed mutagenesis, that this transmembrane segment should be essential in Ca2+ binding.     

Synthesis and conformational study of peptides possessing helically arranged delta ZPhe side chains

Z-Dehydrophenylalanine (delta ZPhe) possessing four oligopeptides, Boc-(L-Ala-delta ZPhe-Aib)n-OCH3 (n = 1-4: Boc, t-butoxycarbonyl; Aib, alpha-aminoisobutyric acid), were synthesized, and their solution conformations were investigated by 1H-nmr, ir, uv, and CD spectroscopy and theoretical CD calculation. 1H-nmr (the solvent accessibility of NH groups) and ir studies indicated that all the NH groups except for those belonging to the N-terminal L-Ala-delta ZPhe moiety participate in intramolecular hydrogen bonding in chloroform. This suggests that the peptides n = 2-4 have a 4-->1 hydrogen-bonding pattern characteristic of 3(10)-helical structures. The uv spectra of all these peptides recorded in chloroform and in trimethyl phosphate showed an intense maximum around 276 nm assigned to the delta ZPhe chromophores. The corresponding CD spectra of the peptides n = 2-4 showed exciton couplets with a negative peak at longer wavelengths, whereas that of the peptide n = 1 showed only weak signals. Theoretical CD spectra were calculated for the peptides n = 2-4 of several helical conformations, on the basis of exciton chirality method. This calculation indicated that the three peptides form a helical conformation deviating from the perfect 3(10)-helix that contains three residues per turn, and that their side chains of delta ZPhe residues are arranged regularly along the helix. The center-to-center distance between the nearest phenyl pair(s) was estimated to be approximately 5.5 A. The chemical shifts of the delta ZPhe side-chain protons (H beta and aromatic H) for the peptides n = 2-4 indicated anisotropic shielding effect of neighboring phenyl group (s); the effect also supports a regular arrangement of the delta ZPhe side chains along the helical axis.     

Global topology & stability and local structure & dynamics in a synthetic spin-labeled four-helix bundle protein

A maleimide nitroxide spin-label (MAL-6) linked to a cysteine in the hydrophobic core and a coproporphyrin I (CP) appended on the N-terminus of a synthetic helix-loop-helix peptide ([alpha2]) have been used to examine the designed self-association of a four-helix bundle ([alpha2]2), focusing on the bundle topology and stability and the rotational dynamics of the spin-label. Gel-permeation chromatography demonstrated that the [alpha2] peptide and the peptide modified with a spin-label ([MAL-6-alpha2]), a coproporphyrin ([CP-alpha2]) and a coproporphyrin plus a spin-label ([CP-MAL-6-alpha2]) self-associate into four helix bundles in solution as designed. Circular dichroism (CD) spectra prove that all these peptides are highly alpha-helical, confirmed for [alpha2]2 by Fourier transform infrared (FTIR) spectroscopic analysis. Electron spin resonance (ESR) spectra of the two attached maleimide spin-labels in [MAL-6-alpha2]2 shows their effective rotational correlation time (tau(c)) is 7.3 +/- 0.5 ns, consistent with that expected for the tumbling of the four helix bundle itself, indicating the labels are immobilized. The ESR spectra were also unaltered by aqueous-phase paramagnetic ions, Ni(II), demonstrating all of the spin-labels are buried within the hydrophobic core. The lack of spin-spin interaction between the buried, immobilized spin-labels indicates they are remote (> 15 A) from each other, indicating an antiparallel topology of the monomers in [MAL-6-alpha2]2. The parent [alpha2]2 and the modified [MAL-6-alpha2]2 and [CP-alpha2]2 peptides are highly stable (deltaG(H2O) approximately 25 kcal/mol) as investigated by guanidine hydrochloride denaturation curves monitored by ESR and CD spectroscopies. Guanidine hydrochloride denaturation leads to a shorter correlation time of the spin-label, tau(c) < 1 ns, approaching that of an unrestricted spin-label in solution. In contrast, trifluoroethanol caused dissociation of [MAL-6-alpha2]2 to yield two [MAL-6-alpha2] monomers with retention of secondary structure and changed the tau(c) to 2.5 +/- 0.5 ns, indicating that a significant degree of motional restriction is imposed on the spin-label by the secondary structure. The coproporphyrin probes covalently attached to the N-termini of [CP-alpha2]2 and [CP-MAL-6-alpha2]2 provided evidence that the helical monomers of both were in a parallel orientation, in contrast to the antiparallel orientation determined for [MAL-6-alpha2]2. Consequently, the ESR spectra of [MAL-6-alpha2]2 and [CP-MAL-6-alpha2]2 reveal major structural differences in the local vicinity of the spin-labels due to the topological difference between these two bundles. The ESR spectra of [CP-MAL-6-alpha2]2 contains two distinct nitroxide populations, indicating that one spin-label remains buried in the hydrophobic core and the other is excluded to solvent in this parallel topology. Alleviation of the steric interactions causing one spin-label in [CP-MAL-6-alpha2]2 to be solvent-exposed by addition of [CP-alpha2]2 results in formation of the heterodimeric [CP-alpha2]/[CP-MAL-6-alpha2], as evidenced by insertion of all the spin-labels into hydrophobic cores. The changes in global topology and local structure as evidenced by this pair of spectral probes have relatively minor effects on the course of guanidine denaturation of these bundles.     

Block of brain sodium channels by peptide mimetics of the isoleucine, phenylalanine, and methionine (IFM) motif from the inactivation gate

Inactivation of sodium channels is thought to be mediated by an inactivation gate formed by the intracellular loop connecting domains III and IV. A hydrophobic motif containing the amino acid sequence isoleucine, phenylalanine, and methionine (IFM) is required for the inactivation process. Peptides containing the IFM motif, when applied to the cytoplasmic side of these channels, produce two types of block: fast block, which resembles the inactivation process, and slow, use-dependent block stimulated by strong depolarizing pulses. Fast block by the peptide ac-KIFMK-NH2, measured on sodium channels whose inactivation was slowed by the alpha-scorpion toxin from Leiurus quinquestriatus (LqTx), was reversed with a time constant of 0.9 ms upon repolarization. In contrast, control and LqTx-modified sodium channels were slower to recover from use-dependent block. For fast block, linear peptides of three to six amino acid residues containing the IFM motif and two positive charges were more effective than peptides with one positive charge, whereas uncharged IFM peptides were ineffective. Substitution of the IFM residues in the peptide ac-KIFMK-NH2 with smaller, less hydrophobic residues prevented fast block. The positively charged tripeptide IFM-NH2 did not cause appreciable fast block, but the divalent cation IFM-NH(CH2)2NH2 was as effective as the pentapeptide ac-KIFMK-NH2. The constrained peptide cyclic KIFMK containing two positive charges did not cause fast block. These results indicate that the position of the positive charges is unimportant, but flexibility or conformation of the IFM-containing peptide is important to allow fast block. Slow, use-dependent block was observed with IFM-containing peptides of three to six residues having one or two positive charges, but not with dipeptides or phenylalanine-amide. In contrast to its lack of fast block, cyclic KIFMK was an effective use-dependent blocker. Substitutions of amino acid residues in the tripeptide IFM-NH2 showed that large hydrophobic residues are preferred in all three positions for slow, use-dependent block. However, substitution of the large hydrophobic residue diphenylalanine or the constrained residues phenylglycine or tetrahydroisoquinoline for phe decreased potency, suggesting that this phe residue must be able to enter a restricted hydrophobic pocket during the binding of IFM peptides. Together, the results on fast block and slow, use-dependent block indicate that IFM peptides form two distinct complexes of different stability and structural specificity with receptor site(s) on the sodium channel. It is proposed that fast block represents binding of these peptides to the inactivation gate receptor, while slow, use-dependent block represents deeper binding of the IFM peptides in the pore.