Amphiphilic secondary structure: design of peptide hormones

Metal binding and folding properties of a minimalist Cys2His2 zinc finger peptide

A minimalist Cys2His2 zinc finger peptide, Lys-Tyr-Ala-Cys-Ala-Ala-Cys-Ala-Ala-Ala-Phe-Ala-Ala-Lys-Ala-Ala-Leu-Ala- Ala-His-Ala-Ala-Ala-His-Ala-Lys, has been synthesized. Metal binding studies using Co2+ as a probe indicated that this peptide forms a 1:1 peptide/metal complex with a dissociation constant comparable to that observed for other zinc finger peptides. At high peptide concentrations, a 2:1 peptide/metal complex also forms, with four cysteinates coordinated to Co2+. Additional studies with sequence variants in which the canonical hydrophobic residues were changed to alanine, or in which one of the residues between the cysteines and the histidines was deleted, revealed an even more pronounced formation of the 2:1 complex over the 1:1 complex. In addition, the absorption spectra of the 1:1 peptide/Co2+ complexes of the variant peptides are significantly different from those seen for complexes of the parent peptide or those of more typical zinc finger peptides. NMR studies revealed that the parent peptide folds in the presence of Zn2+ to a structure very similar to that observed for other zinc finger peptides of this class. Taken together, these results suggest that the metal-binding and canonical hydrophobic residues are necessary and sufficient to determine the structure of this class of zinc finger peptides.

Making sense from antisense: a review of experimental data and developing ideas on sense--antisense peptide recognition

Peptides encoded in the antisense strand of DNA have been predicted and found experimentally to bind to sense peptides and proteins with significant selectivity and affinity. Such sense--antisense peptide recognition has been observed in many systems, most often by detecting binding between immobilized and soluble interaction partners. Data obtained so far on sequence and solvent dependence of interaction support a hydrophobic-hydrophilic (amphipathic) model of peptide recognition. Nonetheless, the mechanistic understanding of this type of molecular recognition remains incomplete. Improving this understanding likely will require expanding the types of characteristics measured for sense--antisense peptide complexes and hence the types of analytical methods applied to such interactions. Understanding the mechanism of sense--antisense peptide recognition also may provide insights into mechanisms of native (sense) peptide and protein interactions and protein folding. Such insight may be helpful to learn how to design macromolecular recognition agents in technology for separation, diagnostics and therapeutics.

The influence of peptide structure on transport across Caco-2 cells. II. Peptide bond modification which results in improved permeability

In order to study the influence of hydrogen bonding in the amide backbone of a peptide on permeability across a cell membrane, a series of tetrapeptide analogues was prepared from D-phenylalanine. The amide nitrogens in the parent oligomer were sequentially methylated to give a series containing from one to four methyl groups. The transport of these peptides was examined across confluent monolayers of Caco-2 cells as a model of the intestinal mucosa. The results of these studies showed a substantial increase in transport with each methyl group added. Only slight difference in the octanol-water partition coefficient accompanied this alkylation, suggesting that the increase in permeability is not due to lipophilicity considerations. These observations are, however, consistent with a model in which hydrogen bonding in the backbone is a principal determinant of transport. Methylation is seen to reduce the overall hydrogen bond potential of the peptide and increases flux by this mechanism. These results suggest that alkylation of the amides in the peptide chain is an effective way to improve the passive absorption potential for this class of compounds.

Biophysical mechanism of the scavenger site near T cell-presented epitopes

We seek to identify consensus sequences in digested fragments of antigenic proteins regulating selection and major histocompatibility complex (MHC)-restricted presentation to T cells of epitopes within those fragments. One such pattern, of recurrent, hydrophobic sidechains forming a longitudinal hydrophobic strip when a sequence is coiled as an alpha-helix, is found in or near most T cell-presented epitopes. Such recurrent hydrophobicity may lead to protease-protected coiling of the fragment against endosomal membranes and transfer to MHC molecules. This concept leads to better identification of T cell-presented sequences and possible to engineering of T cell-presented vaccines to affect their potency and MHC restriction.

A comparative study on interactions of alpha-aminoisobutyric acid containing antibiotic peptides, trichopolyn I and hypelcin A with phosphatidylcholine bilayers

Interactions of alpha-aminoisobutyric acid containing antibiotic peptides, trichopolyn I and hypelcin A with phosphatidylcholine bilayers were investigated to obtain some basic information on their bioactive mechanisms. Trichopolyn I as well as hypelcin A induced the leakage of a fluorescent dye, calcein, entrapped in sonicated egg yolk L-alpha-phosphatidylcholine vesicles. A quantitative analysis revealed that both the binding affinity and the 'membrane-perturbing activity' of trichopolyn I to the vesicles are about one-third of those of hypelcin A. The conformations and the orientations of the peptide and lipid molecules in the membranes were studied using polarized Fourier transform infrared-attenuated total reflection spectroscopy, circular dichroism, and differential scanning calorimetry. In phosphatidylcholine bilayers, both peptides mainly conformed to helical structures irrespective of the membrane physical state (gel or liquid-crystalline). The helix axes, penetrating the hydrophobic region of the bilayers, were oriented neither parallel nor perpendicular to the membrane normal. The disruption in the lipid packing induced by the peptide insertion seems to be responsible for the leakage by these peptides.

Dynamical search for bis-penicillamine enkephalin conformations

Quenched molecular dynamics is used as a conformational search technique for the constrained cyclic analog [D-Pen2,D-Pen5]enkephalin (DPDPE) in a continuum solvent. The results show a Gaussianlike distribution of conformations as a function of energy, unlike the distributions found for simple liquids which have sharp bands for different crystal forms and broad glasslike states are found. The lowest energy conformers have structural features in common with those obtained from constrained searches based on energy minimization. (Hruby, V. J., L-.F. Kao, B. M. Pettitt, and M. Karplus. 1988. J. Am. Chem. Soc. 110:3351-3359). Many of the low energy configurations are amphiphilic with the carbonyl groups on one surface and the hydrophobic groups on the other. This supports the conclusions from the previous modeling study, which yielded amphiphilic structures as the most probable conformations of DPDPE when NOE data were included.

Magainins affect respiratory control, membrane potential and motility of hamster spermatozoa

The hypothesis was tested that the magainin peptides, known to compromise bacterial and mitochondrial energetics, are highly active against spermatozoa. A mixture of magainin A and PGLa (1:1) caused a 50% reduction in motility of hamster spermatozoa at 4 micrograms/ml total peptide concentration. All motility was lost at 8 micrograms/ml. At this concentration, respiratory control was released and respiration in the presence of uncoupler was inhibited. Uptake of the lipophilic cation tetraphenyl phosphonium was largely abolished by addition of magainin A and PGLa showed synergism with respect to release of respiratory control.

Examination of the peptide sequence requirements for lipid-binding. Alternative pathways for promoting the interaction of amphipathic alpha-helical peptides with phosphatidylcholine

To examine the relationship between peptide sequence and the interaction of amphipathic alpha-helical peptides with phosphatidylcholines, various methods of mixing the peptide and lipid were explored. A series of amphipathic alpha-helical peptides containing from 10 to 18 residues were synthesized by solid-phase techniques. An 18-residue peptide and two relatively hydrophobic 10-residue peptides did not disrupt dimyristoylphosphatidylcholine liposomes when added to the lipid in buffer. However, when the peptides were premixed with lipid in a suitable organic solvent and then reconstituted with aqueous buffer, clear micelles were formed, indicating association of the amphipathic alpha-helical peptide with lipid. In general, the best solvent for this purpose was trifluoroethanol. The circular dichroic and fluorescence spectra of peptides which readily formed clear mixtures when mixed in buffer with dimyristoylphosphatidylcholine liposomes were similar when prepared either by the alternative pathway technique using trifluoroethanol or by a cholate removal technique. For the peptides which did not clear liposomes in buffer, first mixing with dimyristoylphosphatidylcholine in trifluoroethanol resulted in an increase in the alpha-helicity of the peptides as judged by circular dichroic spectra and a blue-shift in the fluorescence emission maxima of the single tryptophan residue in each peptide. These data are consistent with formation of an amphipathic alpha-helix in lipid by peptides which based on mixing experiments with dimyristoylphosphatidylcholine liposomes in buffer at the phase transition temperature of the lipid would be considered ineffective in lipid binding. Thus, simple mixing of peptides with liposomes may give misleading results concerning the intrinsic affinity of a particular peptide sequence for lipid. In addition, the data demonstrate that relatively hydrophobic amphipathic alpha-helical peptides which do not form small micelles with dimyristoylphosphatidylcholine spontaneously in aqueous solution may interact with lipid as typical amphipathic alpha-helices when mixed by an alternative pathway.

T-helper-cell determinants in protein antigens are preferentially located in cysteine-rich antigen segments resistant to proteolytic cleavage by cathepsin B, L, and D

We report on a computer algorithm capable of predicting the location of T-helper-cell epitopes in protein antigen (Ag) by analysing the Ag amino acid sequence. The algorithm was constructed with the aim of identifying segments in Ag which are resistant to proteolytic degradation by the enzymes cathepsin B, L, and D. These are prominent enzymes in the endocytic pathway through which soluble protein Ag enter APC, and resistant segments in Ag may, therefore, be expected to contain more T-cell determinants than susceptible segments. From information available in the literature on the substrate specificity of the three enzymes, it is clear that a cysteine is not accepted in any of the S2, S1, S1', and S2' subsites of cathepsin B and L, and not in the S1 and S1' subsites of cathepsin D. Moreover, we have noticed that cysteine-containing T-cell determinants in a number of protein Ag are particularly rich in the amino acids alanine, glycine, lysine, leucine, serine, threonine, and valine. By searching protein Ag for clusters of amino acids containing cysteine and two of the other amino acids we were able to predict 17 out of 23 empirically known T-cell determinants in the Ag with a relatively low number of false (positive) predictions. Furthermore, we present a new principle for searching Ag for potential amphipatic alpha-helical protein segments. Such segments accord well with empirically known T-cell determinants and our algorithm produces a lower number of false positive predictions than the principle based on discrete Fourier transformations previously described.

Asymmetric inclusion by de novo designed proteins: fluorescence probe studies on amphiphilic alpha-helix bundles

The inclusion feature and supersecondary structure of the de novo designed proteins which are constructed with several amphiphilic alpha-helices and flexible linkage parts were investigated with fluorescence probes. Five types of small proteins (or peptides) have been designed, which are composed of 2, 3, 4, 4, and 6 helices, respectively, and are linked with only linear junctions except for one of 4-helix proteins. All of these proteins have inclusion ability for hydrophobic fluorophores. Further, by the analysis of fluorescence polarization anisotropy, it was suggested that these proteins include guest molecules in compact helix bundles constructed with about 4 helices. Asymmetric inclusion of both monomer and stacked dimer of acridine orange derivatives was found by means of induced circular dichroism except for the 4-helix protein with cross-junction. The chirality of the included dimer proved to be in accordance with the chiral sense of alpha-helical coiled-coil. The 6-helix protein has especially high efficiency in inclusion for any fluorophores examined in this study and brings about a significant blue-shift of maximal emission for 8-anilino-1-naphthalenesulfonate.

The effect of a membrane potential on the interaction of mastoparan X, a mitochondrial presequence, and several regulatory peptides with phospholipid vesicles

Recently the pH gradient evoked by a K+ diffusion potential was shown to translocate a synthetic monobasic amphipathic hexapeptide across the bilayer of lipid vesicles (De Kroon, A.I.P.M., Vogt, B., Van 't Hof, R., De Kruijff, B. and De Gier, J. (1991) Biophys. J. 60, in press). Here this observation is extended by studying the effect of a membrane potential on a set of bioactive peptides. The panel of peptides comprises the toxin mastoparan X, a tryptophan-containing analogue of the presequence of the mitochondrial protein cytochrome oxidase subunit IV (preCoxIV(1-25)W18), and the regulatory peptides ACTH(1-24), alpha-MSH, ACTH(1-10), dynorphin A, bombesin, and LHRH. The interaction of these peptides with phospholipid vesicles has been measured using the intrinsic tryptophan residue as fluorescent probe. In the absence of a K+ diffusion potential only mastoparan X and the presequence show considerable binding to vesicles consisting of phosphatidylcholine (PC). In contrast, under these conditions all peptides display affinity for vesicles consisting of the acidic phospholipid cardiolipin (CL), the extent of which depends on the net positive charge of the peptide. Application of a K+ diffusion potential to large unilamellar vesicles (LUV) consisting of PC results in a time dependent tryptophan fluorescence increase for mastoparan X, which is accelerated upon incorporating increasing amounts of CL into the LUV. A similar fluorescence increase in response to a K+ diffusion potential was observed for the above model peptide. Yet the mechanism resulting in the fluorescence increase of mastoparan X is completely different from that of the hexapeptide. Binding experiments indicate that a membrane potential-induced enhanced binding of the peptide to the outer surface of the vesicles contributes to the fluorescence increase. PreCoxIV(1-25)W18, dynorphin A, and ACTH(1-24) show fluorescence responses upon applying a membrane potential that are consistent with that of mastoparan X, whereas the other peptides tested do not respond up to a LUV CL content of 50%. The results tentatively suggest that the membrane potential only affects a peptide when it has the ability to adopt a stable membrane bound conformation.

Mass-weighted molecular dynamics simulation and conformational analysis of polypeptide

Atomic motions in protein molecules have been studied by molecular dynamics (MD) simulations; dynamics simulation methods have also been employed in conformational studies of polypeptide molecules. It was found that when atomic masses are weighted, the molecular dynamics method can significantly increase the sampling of dihedral conformation space in such studies, compared to a conventional MD simulation of the same total simulation time length. Herein the theoretical study of molecular conformation sampling by the molecular dynamics-based simulation method in which atomic masses are weighted is reported in detail; moreover, a numerical scheme for analyzing the extensive conformational sampling in the simulation of a tetrapeptide amide molecule is presented. From numerical analyses of the mass-weighted molecular dynamics trajectories of backbone dihedral angles, low-resolution structures covering the entire backbone dihedral conformation space of the molecule were determined, and the distribution of rotationally stable conformations in this space were analyzed quantitatively. The theoretical analyses based on the computer simulation and numerical analytical methods suggest that distinctive regimes in the conformational space of the peptide molecule can be identified.

Syntheses, structures and anorectic effects of human and rat amylin

Amylin, a 37-residue polypeptide with a single disulfide bond originally isolated from the pancreas of type-II diabetic patients, has been shown to cause peripheral insulin resistance and to attenuate the inhibition of hepatic glucose output by insulin. We have also shown that amylin is present in the rat hypothalamus and that it inhibits food intake by rats. In order to further investigate the anorectic properties we synthesized both human and rat amylin by the solid phase method and purified to homogeneity in an overall yield of 10-20%. Structural analyses indicated that human amylin exhibited predominantly a beta-sheet structure at both acidic and alkaline pH, whereas no ordered structure was evident in the case of rat amylin. Intrahypothalamic injection of rat amylin resulted in a potent dose-dependent inhibitory effect on the food intake by rats adapted to eat their daily ration of food in an eight-hour period. Human amylin was less effective as an anorectic agent. Furthermore, rat amylin completely blocked the potent orexigenic effect of neuropeptide Y (NPY). These investigations show that there is a fundamental difference in the secondary structures of human and rat amylin and that rat amylin is a potent inhibitor of both basal and NPY-induced feeding by rats.

Designing peptide and protein ligands for biological receptors

A clearer understanding of structure-function relationships of protein hormone-receptor systems is emerging from the increased use of molecular biology approaches. On the other hand, the introduction of rationally designed conformation constraints into peptide hormones and neurotransmitters is leading to the development of highly receptor-selective ligands that allow further investigations into the topographic modulation of their bioactivities and rational design principles for peptide antagonists.

Crystal structure of [Leu1]zervamicin, a membrane ion-channel peptide: implications for gating mechanisms

Structures in four different crystal forms of [Leu1]zervamicin (zervamicin Z-L, Ac-Leu-Ile-Gln-Iva-Ile5-Thr-Aib-Leu-Aib-Hyp10-Gln-Aib-Hyp-Aib-P ro15-Phol, where Iva is isovaline, Aib is alpha-amino isobutyric acid, Hyp is 4-hydroxyproline, and Phol is phenylalaninol), a membrane channel-forming polypeptide from Emericellopsis salmosynnemata, have been determined by x-ray diffraction. The helical structure is amphiphilic with all the polar moieties on the convex side of the bent helix. Helices are bent at Hyp10 from approximately 30 degrees to approximately 45 degrees in the different crystal forms. In all crystal forms, the peptide helices aggregate in a similar fashion to form water channels that are interrupted by hydrogen bonds between N epsilon H(Gln11) and O delta (Hyp10) of adjacent helices. The Gln11 side chain is folded in an unusual fashion in order to close the channel. Space is available for an extended conformation for Gln11, in which case the channel would be open, suggesting a gating mechanism for cation transport. Structural details are presented for one crystal form derived from methanol/water solution: C85H140N18O22. 10H2O, space group P21, a = 23.068(6) A, b = 9.162(3) A, c = 26.727(9) A, beta = 108.69(2) degrees (standard deviation of last digit is given in parentheses); overall agreement factor R = 10.1% for 5322 observed relfections [magnitude of Fo greater than 3 sigma (F)]; resolution, 0.93 A.

GRF analogs and fragments: correlation between receptor binding, activity and structure

GH-releasing activity in vitro was directly correlated with GRF receptor binding affinity for all hGRF analogs examined. hGRF(1-29)-NH2 analogs with Ala15-substitution (for Gly15) displayed 4-5 times higher affinity for the GRF receptor relative to hGRF(1-44)-NH2. Replacement of Gly15 with Sar15 resulted in a dramatic loss of activity and receptor binding. The present data supports the proposal that Ala15-substitution increases receptor affinity, and hence potency, due to increased amphiphilic alpha-helical interactions. Fragments of hGRF, representative of DPP-IV and trypsin-like cleavage, are inactive as a consequence of greatly diminished GRF receptor binding. These results provide a comprehensive analysis of the structural features required for both GRF receptor binding and activation.

Mechanisms of T cell recognition with application to vaccine design

Both helper and cytotoxic T lymphocytes generally recognize protein antigens not in their intact form, as antibodies do, but on the surface of another cell, after "processing" by that cell to unfold or cleave the protein into fragments and after association of the processed antigen with major histocompatibility complex (MHC) molecules on that cell. This complex process leads to immunodominance of certain segments from the protein, which depends not only on structural features intrinsic to the antigenic segment itself, but also on antigen processing and on the structure of the MHC molecules of the responding individual. We have explored all three of these factors, including the enzymes involved in processing, the way peptides bind to MHC molecules, and structural features such as helical amphipathicity that seem to favour T cell recognition. We have used this information to locate and characterize antigenic sites of proteins of interest for vaccine development, including proteins from the malaria parasite and the AIDS virus, HIV. For HIV, we have identified both helper and cytotoxic T cell sites, coupled a helper site to a B cell site to produce a synthetic immunogen that elicits neutralizing antibodies, and studied the effect of viral sequence variation on cytotoxic T cell recognition and binding of the immunodominant peptide to MHC molecules. This information suggests strategies for the rational design of synthetic or recombinant vaccines.

Antisense sequences of antigenic peptides are found in MHC class II molecules

The sequence of the well known antigenic peptide OVA 323-339 as well as other peptides containing reiterative motifs of the core region essential for binding to Class II MHC molecules was compared for homology with the DNA derived antisense peptide sequences corresponding to the alpha chain of the mouse IAd molecule. Homology was obtained within the sequence found in the transmembrane region of the molecule. Increased binding of the peptides containing the reiterative motifs based on the OVA 323-339 sequence may be due to the increased number of contact sites on IAd molecules which were identified as being complementary in a sense-antisense manner.

Design and synthesis of the pseudo-EF hand in calbindin D9K: effect of amino acid substitutions in the alpha-helical regions

A series of 37-residue analogues of the pseudo-EF hand in bovine calbindin D9K has been synthesized by the solid phase method. In the presence of calcium an alpha-helical induction of up to 44% was observed for the peptide with the native sequence with a Kd for calcium binding of 0.35 mM. A number of amino acid substitutions have been carried out to study the packing of the two alpha-helices based on the crystal structure of the entire protein. Three strategies were employed: (1) replacement of the Leu residues, which in the crystal structure do not contribute to the hydrophobic interaction between the two helices, by Gln or Ala in order to control the orientation of the helix packing, (2) stabilization of the individual helix by introducing a Glu-...Lys+ salt bridge or by changing the N-terminal charge to compensate for the helix dipole moment, and (3) introduction of a disulfide bond between the two helices to help the packing of the helices. The mutants with the substitution of (Leu-30, Leu-32) to (Gln-30, Gln-32), (Gln-30, Ala-32), and (Ala-30,Ala-32) designed based on the strategy 1 do not show any affinity for calcium and have low alpha-helicity. The Leu-30 to Lys-30 mutant designed to form a salt bridge between the side chains of Glu-26 and Lys-30 has an apparent Kd for calcium of 6.8 mM. Kd of the N-terminal acetylated and succinylated mutants are 0.41 and 0.45 mM, respectively, and no increase in the alpha-helix content relative to that of the natural sequence peptide is observed. The disulfide containing mutants, namely Tyr-13, Leu-31 to Cys-13, Cys-31 and Tyr-13, Leu-31 to Cys-13, hCys-31, show apparent Kd values of 0.93 and 2.1 mM, respectively. The former mutant shows the highest alpha-helix content among the peptides studied in the presence and absence of calcium. While it is difficult to construct an isolated and rigid helix-loop-helix motif with peptides of this size, introduction of a disulfide bond proved to be effective for this purpose.

Molecular design and modeling of protein-heparin interactions

The methods and approaches taken to investigate heparin-apoE peptide interactions have involved a series of steps, including (1) identification of the heparin-binding domains of apoE, (2) determination of the minimal amino acid sequence regions involved in heparin binding, heparin-induced conformational changes, and stability of apoE peptide structures in solution, (3) modeling of these peptide and oligosaccharide structures, and (4) examination of their behavior during molecular dynamics calculations to determine if the modeled complexes simulate the results of the solution study. The heparin-binding regions of apoE were determined by fragmentation of the protein and identification of the heparin-binding fragments by ligand-blotting procedures using 125I-labeled heparin. Studies with synthetic peptide fragments of various lengths and dot-blot procedures with 125I-labeled heparin identified the minimal residues critical for heparin-binding and CD studies established the prominent secondary structures of these domains. These studies also showed that heparin binds to the apoE(211-243) and apoE(129-169) regions to induce and stabilize beta-strand and alpha-helical peptide conformations. Secondary structure algorithms were used to identify the specific residues with the highest probabilities of forming alpha-helix and beta-strand structures. Based on the predictive algorithms, the apoE(211-234) and apoE(129-159) structures were built using the Insight program and their molecular interactions with various heparin oligosaccharide models were investigated by molecular dynamics. In agreement with the solution studies in the presence of salt, the molecular dynamics studies showed that the oligosaccharides stabilized the beta-strand and alpha-helical peptide configurations against simulated thermal denaturations. Further modeling studies are in progress to examine the mechanism of the heparin-induced increase in ordered structure of these peptides.

A novel 1745-dalton pyroglutamyl peptide derived from chromogranin B is in the bovine adrenomedullary chromaffin vesicle

1. Following the recent demonstration of a glutaminyl cyclase activity localized in adrenomedullary chromaffin vesicles, an assay was developed to isolate and characterize posttranslationally modified peptides from this tissue which contain pyroglutamate. This assay consisted of spectrometric identification of peptides before and after enzymatic removal of pyroglutamyl residues. 2. Using this procedure, a pyroglutamyl peptide (BAM-1745) was isolated and sequenced and was shown to be a significant component of adrenomedullary secretory vesicles. 3. A computer search through the Swiss-Prot protein sequence database revealed a 93% identity of BAM-1745 and a fragment of human chromogranin B (Gln580-Tyr593).

Steroidogenic activity of a peptide specified by the reversed sequence of corticotropin mRNA

The molecular recognition theory predicts that a reversed (3'----5') reading of an mRNA should yield a peptide that is structurally and functionally similar to that specified in the 5'----3' direction. We tested this idea by synthesizing a corticotropin (ACTH) analogue using a reverse reading of bovine mRNA for ACTH-(1-24). This peptide, designated ACTH-3'----5', had a similar hydropathic profile to native ACTH-5'----3' but had only 30% sequence homology and eight different charge substitutions. ACTH-3'----5' specifically bound to the surface of mouse Y-1 adrenal cells and to polyclonal anti-ACTH antibody. Additionally, ACTH-3'----5' stimulated cAMP synthesis and steroidogenesis in adrenal cells. These findings show that ACTH-3'----5' mimics the corticotropic properties of native ACTH, thereby further validating the molecular recognition theory.

All-D-magainin: chirality, antimicrobial activity and proteolytic resistance

All-D-magainin-2 was synthesized to corroborate experimentally the notion that the biological function of a surface-active peptide stems primarily from its unique amphiphilic alpha-helical structure. Indeed, the peptide exhibited antibacterial potency nearly identical to that of the all-L-enantiomer. Being highly resistant to proteolysis and non-hemolytic all-D-magainin might have considerable therapeutic importance.

Synthetic peptide model of an essential region of an aminoacyl-tRNA synthetase

A 40 amino acid sequence of the unsolved structure of Escherichia coli alanine-tRNA synthetase is essential for tRNA binding and encodes an immunological determinant that cross-reacts with antibodies raised against a eukaryote (insect Bombyx mori) alanine enzyme. The secondary structure of this sequence is predicted to be an amphiphilic alpha-helix that includes one aspartyl and eight glutamyl side chain carboxyl groups. The antibody reactivity and the conformation of a synthetic peptide model of this region (Glu346 to Ser385) were investigated. In addition, double Arg----Gln and Leu----Ala substitutions were separately placed in the enzyme on the hydrophilic and hydrophobic face, respectively, of the predicted helix. These mutations conserve the polar/nonpolar character of each face and retain the potential for helix formation. Circular dichroism spectra of the synthetic peptide model demonstrate the potential for amphiphilic helix formation for the segment from Glu346 to Ser385. The behavior of the mutations in the enzyme, together with earlier data and immunological assays presented here, suggests that one face of the putative helix is an antigenic region of the surface of the enzyme where it contributes to the interaction with alanine tRNA and that the specific sequence of the helix is an important determinant of enzyme stability.

Haemopoietic receptors and helical cytokines

A bewitching interplay of proteins, variously clothed as chemical messengers and cellular receptors, control the pace of growth and the course of progressive differentiation in blood cell types. The messengers are lymphokines, interleukins, colony-stimulating factors, growth hormones and interferons: generically, the cytokines. The second components of the regulatory pairs are membrane-spanning receptor proteins: these molecules transduce the specific binding of cognate cytokines into a mitogenic cellular response. In this article, Fernando Bazan discusses a provocative structural model for cytokine-receptor interactions which, if correct, will alter perceptions of the evolutionary design of the haemopoietic system.

Association of a pH-sensitive peptide with membrane vesicles: role of amino acid sequence

The solution properties and bilayer association of two synthetic 30 amino acid peptides, GALA and LAGA, have been investigated at pH 5 and 7.5. These peptides have the same amino acid composition and differ only in the positioning of glutamic acid and leucine residues which together compose 47% of each peptide. Both peptides undergo a similar coil to helix transition as the pH is lowered from 7.5 to 5.0. However, GALA forms an amphipathic alpha-helix whereas LAGA does not. As a result, GALA partitions into membranes to a greater extent than LAGA and can initiate leakage of vesicle contents and membrane fusion which LAGA cannot (Subbarao et al., 1987; Parente et al., 1988). Membrane association of the peptides has been studied in detail with large phosphatidylcholine vesicles. Direct binding measurements show a strong association of the peptide GALA to vesicles at pH 5 with an apparent Ka around 10(6). The single tryptophan residue in each peptide can be exploited to probe peptide motion and positioning within lipid bilayers. Anisotropy changes and the quenching of tryptophan fluorescence by brominated lipids in the presence of vesicles also indicate that GALA can interact with uncharged vesicles in a pH-dependent manner. By comparison to the peptide LAGA, the membrane association of GALA is shown to be due to the amphipathic nature of its alpha-helical conformation at pH 5.

Design of DNA-binding peptides based on the leucine zipper motif

A class of transcriptional regulator proteins bind to DNA at dyad-symmetric sites through a motif consisting of (i) a "leucine zipper" sequence that associates into noncovalent, parallel, alpha-helical dimers and (ii) a covalently connected basic region necessary for binding DNA. The basic regions are predicted to be disordered in the absence of DNA and to form alpha helices when bound to DNA. These helices bind in the major groove forming multiple hydrogen-bonded and van der Waals contacts with the nucleotide bases. To test this model, two peptides were designed that were identical to natural leucine zipper proteins only at positions hypothesized to be critical for dimerization and DNA recognition. The peptides form dimers that bind specifically to DNA with their basic regions in alpha-helical conformations.

Binding of brush border myosin I to phospholipid vesicles

The actin filament core within each microvillus of the intestinal epithelial cell is attached laterally to the plasma membrane by brush border (BB) myosin I, a protein-calmodulin complex belonging to the myosin I class of actin-based mechanoenzymes. In this report, the binding of BB myosin I to pure phospholipid vesicles was examined and characterized. BB myosin I demonstrated saturable binding to liposomes composed of anionic phospholipids, but did not associate with liposomes composed of only neutral phospholipids. The binding of BB myosin I to phosphatidylserine and phosphatidylglycerol vesicles reached saturation at 4-5 x 10(-3) nmol protein/nmol phospholipid, while the apparent dissociation constant was determined to be 1-3 x 10(-7) M. Similar to the free protein, membrane-associated BB myosin I bound F-actin in an ATP-sensitive manner and demonstrated actin-activated Mg-ATPase activity. Immunoblot analysis of peptides generated from controlled proteolysis of vesicle-bound BB myosin I provided structural information concerning the site responsible for the membrane interaction. Immunoblot staining with domain-specific mAbs revealed a series of COOH-terminal, liposome-associated peptides that were protected from digestion, suggesting that the membrane-binding domain is within the carboxy-terminal "tail" of the BB myosin I heavy chain.

Binding and pharmacologic properties of peptides derived from human and rat angiotensin II (AII) mRNA

We investigated the binding and pharmacologic properties of peptides encoded by complementary mRNA derived from the human and rat angiotensinogen gene (human and rat IIA, respectively). Human IIA (identical with AII in 4 amino acids) inhibited binding of [125I]AII to rat adrenal glomerulosa particles (Ki = 0.62 +/- 0.09 microM) and competitively blocked, with similar potency, the ability of three AII receptor agonists to contract rabbit aorta. Rat IIA affected neither [125I]AII binding to glomerulosa particles nor the contractile response of AII. We conclude that rat IIA does not interact with AII or its receptors and that human IIA acts as a competitive inhibitor of AII at the receptor level.

Expression of a mutated bovine growth hormone gene suppresses growth of transgenic mice

To determine the importance of the third alpha-helix in bovine growth hormone (bGH) relative to growth-related biological activities, the following experimental approach was used: (i) mutagenesis of helix III of bGH to generate an idealized amphiphilic helix; (ii) in vitro expression analyses of the mutated bGH gene in cultured mouse L cells; (iii) mouse liver membrane binding studies of wild-type and mutated bGH; and (iv) expression of the mutated gene in the transgenic mouse. An altered bGH gene (pBGH10 delta 6-M8) was generated that encodes the following changes: glutamate-117 to leucine, glycine-119 to arginine, and alanine-122 to aspartate. The plasmid pBGH10 delta 6-M8 was shown to be expressed in, and its protein product secreted by, mouse L cells. The altered hormone possessed the same binding affinity to mouse liver membrane preparations as wild-type bGH. Transgenic mice containing the mutated bGH gene, however, showed a significant growth-suppressed phenotype. The degree of suppression was directly related to serum levels of the altered bGH molecule.

Stabilization of helical structure in two 17-residue amphipathic analogues of the C-terminal peptide of cytochrome C

The conformations of two 17-residue peptide analogues derived from the C-terminal sequence of pigeon cytochrome c (native sequence = KAERADLIAYLKQATAK) were examined in aqueous and lipid environments by CD spectroscopy. The two analogues, KKLLKKLIAYLKQATAK (K peptide) and EELLEELIAYLKQATAK (E peptide), were made amphipathic with respect to helical segregation by substituting a 6-residue sequence at the N-terminus of the native peptide. Their structures were compared to the native peptide under aqueous conditions of varying pH and temperature, and in the presence of liposomes composed of phosphatidylcholine and phosphatidylserine in the ratio of 9:1. The results indicated that the native peptide remains unstructured under all the conditions examined even though this region of the native molecule is surface exposed and helical. The E peptide, however, was helical under aqueous conditions at 25 degrees C from pH 2-10 with a maximum helicity at pH 4 (54% helix from analysis of CD data). The ellipticity of the E peptide at pH 4 and 8 was concentration dependent, indicating an aggregation phenomenon. In studies in which the CD spectrum was measured at different temperatures, the E peptide became more helical at lower temperatures at pH 4 but not at pH 8. Upon interaction with a lipid membrane in the form of liposomes, there appeared to be a slight destabilization in the structure of the E peptide. The K peptide in an aqueous environment behaved like the native peptide in that it was structureless at all pHs and temperatures examined. In the presence of liposomes, however, this peptide had a high helical content (75% helix from analysis of CD data). These findings suggest that while stabilization of the helix dipole with negative charges at the N-terminus are important in inducing helical conformation in the E peptide, hydrophobic interactions created during aggregation appear to provide the principal stabilizing force. The results with the K peptide demonstrate that the positive N-terminal sequence of this peptide is able to interact with the negatively charged head groups in the phospholipid membrane in such a fashion as to stabilize a helical structure that is not apparent in an aqueous environment alone.

Interaction of gramicidin S analogs with lipid bilayer membrane

One of the side chains of Orn residues in gramicidin S (GS) was connected with alanine (AGS), sarcosine (SGS), or histidine (HGS) residue, aiming at developing membrane-active artificial enzymes by virtue of the membrane-associating property of GS. The conformation of the GS analogs was similar to that of GS. However, the affinity of GS and its analogs for dipalmitoylphosphatidylcholine (DPPC) vesicles decreased in the order of GS greater than SGS greater than HGS congruent to AGS. The addition of GS analogs at 10 microM to DPPC vesicles decreased the membrane fluidity, indicating that GS analogs did not disrupt the vesicular structure of DPPC vesicles. On the other hand, GS analogs enhanced carboxyfluorescein-leakage from DPPC vesicles. It was therefore considered that the GS analogs induced the phase-separation of the lipid bilayer membrane. Hydrolytic reactions of HGS in the presence of DPPC vesicles were studied using N-methylindoxyl alkanoate as substrate. HGS reacted only with N-methylindoxyl hexanoate below the phase-transition temperature of the membrane. The substrate specificity of HGS was ascribed to the condensation of HGS in the neighbourhood of the substrate in the lipid bilayer membrane due to the phase-separation below the phase-transition temperature of the membrane.

Identification of cellular proteins binding to the scrapie prion protein

The scrapie prion protein (PrPSc) is an abnormal isoform of the cellular protein PrPc. PrPSc is found only in animals with scrapie or other prion diseases. The invariable association of PrPSc with infectivity suggests that PrPSc is a component of the infectious particle. In this study, we report the identification of two proteins from hamster brain of 45 and 110 kDa (denoted PrP ligands Pli 45 and Pli 110) which were able to bind to PrP 27-30, the protease-resistant core of PrPSc on ligand blots. Pli 45 and Pli 110 also bound PrPC. Both Pli's had isoelectric points of approximately 5. The dissociation rate constant of the Pli 45/PrP 27-30 complex was 3 x 10(-6) s-1. Amino acid and protein sequence analyses were performed on purified Pli 45. Both the composition and the sequence were almost identical with those predicted for mouse glial fibrillary acidic protein (GFAP). Furthermore, antibodies to Pli 45 reacted with recombinant GFAP. The identification of proteins which interact with the PrP isoforms in normal and diseased brain may provide new insights into the function of PrPC and into the molecular mechanisms underlying prion diseases.

Peptide models of dynorphin A(1-17) incorporating minimally homologous substitutes for the potential amphiphilic beta strand in residues 7-15

Two peptide models of dynorphin A(1-17) have been synthesized. These peptides incorporate a minimally homologous substitute sequence for residues 6-17, including alternating lysine and valine residues substituting for the potential amphiphilic beta-strand structure in positions 7-15. Model 1 retains Pro10 from the native sequence, but model 2 does not. Compression isotherms of peptide monolayers at the air-water interface and CD spectra of peptide films adsorbed from aqueous solution onto siliconized quartz slides were evaluated by comparison to those of idealized amphiphilic alpha-helical, beta-sheet, and disordered peptides. Dynorphin A(1-17) was mostly disordered, whereas beta-endorphin was alpha helical. Dynorphin model 1 had properties similar to those of dynorphin A(1-17) at these interfaces, but model 2 formed strongly amphiphilic beta sheets. In binding assays to mu-, delta-, and kappa-opioid receptors in guinea pig brain membranes, model 1 reproduced the high potency and selectivity of dynorphin A(1-17) for kappa receptors, and model 2 was only 3 times less potent and less selective for these receptors. Both peptide models retained the high, kappa-selective agonist activity of dynorphin A(1-17) in guinea pig ileum assays, and like dynorphin A(1-17), model 1 had little activity in the rat vas deferens assay. In view of the minimal homology of the modeled dynorphin structures, these studies support current models of membrane-catalyzed opioid ligand-receptor interactions and suggest a role for the amphiphilic alpha-helical and beta-strand structures in beta-endorphin and dynorphin A(1-17), respectively, in this process.