Inhibition of beta-amyloid toxicity by short peptides containing N-methyl amino acids.

Single N-methyl amino acid-containing peptides related to the central hydrophobic region beta16-20 (Lys-Leu-Val-Phe-Phe) of the beta-amyloid protein are able to reduce the cytotoxicity of natural beta1-42 in PC12 cell cultures. N-methyl phenylalanine analogs yield statistically significant increments in cell viability (Student's t-test < 0.01%) and are nontoxic in the same assay. These promising results indicate that these peptide molecules could be a starting point for the development of potential therapeutic compounds for the treatment of Alzheimer's disease.

Proof of principle in a de novo designed protein maquette: an allosterically regulated, charge-activated conformational switch in a tetra-alpha-helix bundle.

New understanding of the engineering and allosteric regulation of natural protein conformational switches (such as those that couple chemical and ionic signals, mechanical force, and electro/chemical free energy for biochemical activation, catalysis, and motion) can be derived from simple de novo designed synthetic protein models (maquettes). We demonstrate proof of principle of both reversible switch action and allosteric regulation in a tetra-alpha-helical bundle protein composed of two identical di-helical subunits containing heme coordinated at a specific position close to the disulfide loop region. Individual bundles assume one of two switch states related by large-scale mechanical changes: a syn-topology (helices of the different subunits parallel) or anti-topology (helices antiparallel). Both the spectral properties of a coproporphyrin probe appended to the loop region and the distance-dependent redox interaction between the hemes identify the topologies. Beginning from a syn-topology, introduction of ferric heme in each subunit (either binding or redox change) shifts the topological balance by 25-50-fold (1.9-2.3 kcal/mol) to an anti-dominance. Charge repulsion between the two internal cationic ferric hemes drives the syn- to anti-switch, as demonstrated in two ways. When fixed in the syn-topology, the second ferric heme binding is 25-80-fold (1.9-2.6 kcal/mol) weaker than the first, and adjacent heme redox potentials are split by 80 mV (1.85 kcal/mol), values that energetically match the shift in topological balance. Allosteric and cooperative regulation of the switch by ionic strength exploits the shielded charge interactions between the two hemes and the exposed, cooperative interactions between the coproporphyrin carboxylates.

Self-assembly of heme A and heme B in a designed four-helix bundle: implications for a cytochrome c oxidase maquette.

Heme A, a prosthetic group of cytochrome c oxidase [EC 1.9.3.1], has been introduced into two de novo designed four helix bundle proteins, [H10A24](2) and [H10H24](2), known to bind 2-4 equiv of heme B, respectively [Robertson, D. E., Farid, R. S., Moser, C. C., Mulholland, S. E., Pidikiti, R., Lear, J. D., Wand, A., J., DeGrado, W. F., and Dutton, P. L. (1994) Nature 368, 425-432]. [H10A24](2), [Ac-CGGGELWKL x HEELLKK x FEELLKL x AEERLKK x L-CONH(2)](2)(2), binds two heme A molecules per four-helix unit via bis-histidine ligation at the 10,10' positions with measured K(d) values of <0.1 and 5 nM, values much lower than those measured for heme B (K(d) values of 50 and 800 nM). The heme A-protein complex, [heme A-H10A24](2), exhibits well-defined absorption spectra in both the ferric and ferrous states, and an electron paramagnetic resonance spectrum characteristic of a low spin heme in the ferric form. A single midpoint redox potential (E(m8)) was determined for [heme A-H10A24](2) at -45 mV (vs SHE), which is significantly higher than that of the protein bound heme B (-130 and -200 mV). The observation of a single midpoint redox potential for [heme A-H10A24](2) and a pair of midpoints for [heme B-H10A24](2) indicates that the di-alpha-helical monomers are oriented in an anti topology (disulfides on opposite sides of bundle) in the former (lacking heme-heme electrostatic interaction) and syn in the latter. A mixture of global topologies was indicated by the potentiometric titration of the related [heme A-H10H24](2) which possess two distinct reduction potentials of +41 (31%) and -65 mV (69%). Self-assembly of the mixed cofactor heme A-heme B-[H10A24](2) was accomplished by addition of a single equivalent of each heme A and heme B to [H10A24](2). The single midpoint redox potential of heme B, E(m8) = -200 mV, together with the split midpoint redox potential of heme A in heme A-heme B-[H10A24](2), E(m8) = +28 mV (33%) and -65 mV (67%), indicated the existence of both syn and anti topologies of the two di-alpha-helical monomers in this four helix bundle. Synthesis of the mixed cofactor [heme A-heme B-H10H24](2) was accomplished by addition of a 2 equiv of each heme A and heme B to [H10H24](2) and potentiometry indicated the pair of hemes B resided in the 10,10' sites and heme A occupied the 24,24' sites. The results indicate that heme peripheral structure controls the orientation of the di-alpha-helical monomers in the four-helix bundle which are interchangeable between syn and anti topologies. In the reduced form, [heme A-H10A24](2), reacts quantitatively to form [carbonmonoxy-heme A-H10A24](2) as evidenced by optical spectroscopy. The synthetic [heme A-H10A24](2) can be enzymatically reduced by NAD(P)H with natural reductases under anaerobic conditions, and reversibly oxidized by dioxygen to the ferric form.

Determination of nonligand amino acids critical to [4Fe-4S]2+/+ assembly in ferredoxin maquettes.

The prototype ferredoxin maquette, FdM, is a 16-amino acid peptide which efficiently incorporates a single [4Fe-4S]2+/+ cluster with spectroscopic and electrochemical properties that are typical of natural bacterial ferredoxins. Using this synthetic protein scaffold, we have investigated the role of the nonliganding amino acids in the assembly of the iron-sulfur cluster. In a stepwise fashion, we truncated FdM to a seven-amino acid peptide, FdM-7, which incorporates a cluster spectroscopically identical to FdM but in lower yield, 29% relative to FdM. FdM-7 consists solely of the. CIACGAC. consensus ferredoxin core motif observed in natural protein sequences. Initially, all of the nonliganding amino acids were substituted for either glycine, FdM-7-PolyGly (.CGGCGGC.), or alanine, FdM-7-PolyAla (.CAACAAC.), on the basis of analysis of natural ferredoxin sequences. Both FdM-7-PolyGly and FdM-7-PolyAla incorporated little [4Fe-4S]2+/+ cluster, 6 and 7%, respectively. A systematic study of the incorporation of a single isoleucine into each of the four nonliganding positions indicated that placement either in the second or in the sixth core motif positions,.CIGCGGC. or.CGGCGIC., restored the iron-sulfur cluster binding capacity of the peptides to the level of FdM-7. Incorporation of an isoleucine into the fifth position,.CGGCIGC., which in natural ferredoxins is predominantly occupied by a glycine, resulted in a loss of [4Fe-4S] affinity. The substitution of leucine, tryptophan, and arginine into the second core motif position illustrated the stabilization of the [4Fe-4S] cluster by bulky hydrophobic amino acids. Furthermore, the incorporation of a single isoleucine into the second core motif position in a 16-amino acid ferredoxin maquette resulted in a 5-fold increase in the level of [4Fe-4S] cluster binding relative to that of the glycine variant. The protein design rules derived from this study are fully consistent with those derived from natural ferredoxin sequence analysis, suggesting they are applicable to both the de novo design and structure-based redesign of natural proteins.

Design, synthesis, and characterization of a photoactivatable flavocytochrome molecular maquette.

We report the construction of a synthetic flavo-heme protein that incorporates two major physiological activities of flavoproteins: light activation of flavin analogous to DNA photolyase and rapid intramolecular electron transfer between the flavin and heme cofactors as in several oxidoreductases. The functional tetra-alpha-helix protein comprises two 62-aa helix-loop-helix subunits. Each subunit contains a single cysteine to which flavin (7-acetyl-10-methylisoalloxazine) is covalently attached and two histidines appropriately positioned for bis-his coordination of heme cofactors. Both flavins and hemes are situated within the hydrophobic core of the protein. Intramolecular electron transfer from flavosemiquinone generated by photoreduction from a sacrificial electron donor in solution was examined between protoporphyrin IX and 1-methyl-2-oxomesoheme XIII. Laser pulse-activated electron transfer from flavin to meso heme occurs on a 100-ns time scale, with a favorable free energy of approximately -100 meV. Electron transfer from flavin to the lower potential protoporphyrin IX, with an unfavorable free energy, can be induced after a lag phase under continuous light illumination. Thus, the supporting peptide matrix provides an excellent framework for the positioning of closely juxtaposed redox groups capable of facilitating intramolecular electron transfer and begins to clarify in a simplified and malleable system the natural engineering of flavoproteins.

Effect of four helix bundle topology on heme binding and redox properties.

We have designed two alternative four helix bundle protein scaffold topologies for maquette construction to examine the effect of helix orientation on the heme binding and redox properties of our prototype heme protein maquette, (alpha-SS-alpha)2, previously described as H10H24 [Robertson, D. E., Farid, R. S., Moser, C. C., Mulholland, S. E., Pidikiti, R., Lear, J. D., Wand, A. J., DeGrado, W. F., and Dutton, P. L. (1994) Nature 368, 425]. Conversion of the disulfide-bridged di-alpha-helical monomer of (alpha-SS-alpha)2 into a single polypeptide chain results in topological reorientation of the helix dipoles and side chains within a 62 amino acid helix-loop-helix monomer, (alpha-l-alpha), which self-associates to form (alpha-l-alpha)2. Addition of an N-terminal cysteine residue to (alpha-l-alpha) with subsequent oxidation yields a 126 amino acid single molecule four helix bundle, (alpha-l-alpha-SS-alpha-l-alpha). Gel permeation chromatography demonstrated that (alpha-SS-alpha)2 and (alpha'-SS-alpha')2, a uniquely structured variant of the prototype, as well as (alpha-l-alpha)2 and (alpha'-l-alpha')2 assemble into distinct four helix bundles as designed, whereas (alpha-l-alpha-SS-alpha-l-alpha) elutes as a monomeric four alpha-helix bundle. Circular dichroism (CD) spectroscopy proves that these peptides are highly alpha-helical, and incorporation of four hemes has little effect on the helical content of the secondary structure. Four heme dissociation constants were evaluated by UV-visible spectroscopy and ranged from the 15 nM to 25 microM range for each of the peptides. The presence of Cotton effects in the visible CD illustrated that the hemes reside within the protein architecture. The equilibrium redox midpoint potentials (Em8) of the four bound hemes in each peptide are between -100 and -280 mV, as determined by redox potentiometry. The heme affinity and spectroelectrochemical properties of the hemes bound to (alpha-l-alpha)2 and (alpha-l-alpha-SS-alpha-l-alpha) are similar to those of the prototype, (alpha-SS-alpha)2, and to bis-histidine ligated b-type cytochromes, regardless of the global architectural changes imposed by these topological rearrangements. The hydrophobic cores of these peptides support local electrostatic fields which result in nativelike heme chromophore properties (spectroscopy, elevated reduction potentials, heme-heme charge interaction, and reactivity with exogenous diatomics) illustrating the utility of these non-native peptides in the study of metalloproteins.

A designed cavity in the hydrophobic core of a four-alpha-helix bundle improves volatile anesthetic binding affinity.

The structural features of protein binding sites for volatile anesthetics are being explored using a defined model system consisting of a four-alpha-helix bundle scaffold with a hydrophobic core. Earlier work has demonstrated that a prototype hydrophobic core is capable of binding the volatile anesthetic halothane. Exploratory work on the design of an improved affinity anesthetic binding site is presented, based upon the introduction of a simple cavity into a prototype (alpha 2)2 four-alpha-helix bundle by replacing six core leucines with smaller alanines. The presence of such a cavity increases the affinity (Kd = 0.71 +/- 0.04 mM) of volatile anesthetic binding to the designed bundle core by a factor of 4.4 as compared to an analogous bundle core lacking such a cavity (Kd = 3.1 +/- 0.4 mM). This suggests that such packing defects present on natural proteins are likely to be occupied by volatile general anesthetics in vivo. Replacing six hydrophobic core leucine residues with alanines results in a destabilization of the folded bundle by 1.7-2.7 kcal/mol alanine, although the alanine-substituted bundle still exhibits a high degree of thermodynamic stability with an overall folded conformational delta GH2O = 14.3 +/- 0.8 kcal/mol. Covalent attachment of the spin label MTSSL to cysteine residues in the alanine-substituted four-alpha-helix bundle indicates that the di-alpha-helical peptides dimerize in an anti orientation. The rotational correlation time of the four-alpha-helix bundle is 8.1 +/- 0.5 ns, in line with earlier work on similar peptides. Fluorescence, far-UV circular dichroism, and Fourier transform infrared spectroscopies verified the hydrophobic core location of the tryptophan and cysteine residues, showing good agreement between experiment and design. These small synthetic proteins may prove useful for the study of the structural features of small molecule binding sites.

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.

Synthesis of novel proteins.

De novo and rational protein design are progressing towards the chemical synthesis of proteins with pre-selected structure and function. The data illustrate diverse experimental and computational approaches which test our comprehension of protein structure, hydrophobic core packing and global stability, especially of coiled-coil proteins. The incorporation of biological cofactors, including hemes, as well as active sites, such as that of iron superoxide dismutase, into designed proteins provides an exciting next step towards the synthesis of proteins with enzymatic function.

Ferredoxin and ferredoxin-heme maquettes.

A 16-amino acid residue peptide derived from a consensus motif of natural ferredoxins incorporates a tetranuclear iron sulfur cluster under physiological conditions. Successful assembly of the [4Fe-4S]2+/1+ cluster within a monomeric peptide was demonstrated using size exclusion chromatography, UV-visible, visible CD, and cryogenic EPR spectroscopies. The robustness of [4Fe-4S]2+/1+ formation was tested using peptides with either the ligating cysteine exchanged for alanine or with the intervening amino acids replaced by glycine. The small size of the peptide allows for modular incorporation into more complex protein structures. In one larger structure, we describe a tetra-alpha-helix bundle that self-assembles both iron-sulfur clusters and hemes, thereby demonstrating feasibility for the general synthesis of maquettes containing multiple, juxtaposed redox cofactors. This is a motif common to the catalytic sites of native oxidoreductases.

Binding of the volatile anesthetic halothane to the hydrophobic core of a tetra-alpha-helix-bundle protein.

Although volatile general anesthetics interact with several proteins, little is known about the location or characteristics of the binding sites at the molecular level. A detailed structural description of how anesthetics associate with macromolecules is necessary for understanding anesthetic mechanisms of action. The recent introduction of designed synthetic proteins provides new opportunities for obtaining structural and functional information on anesthetic-protein interactions. A synthetic tetra-alpha-helix-bundle protein was used to examine the interaction of halothane with a designed protein interior. The tetra-alpha-helix-bundle comprises 124 residues in the form of two identical 62-residue di-alpha-helical peptides, held together in an all-parallel bundle by hydrophobic forces. Steady-state and time-resolved tryptophan fluorescence and circular dichroism spectroscopy were used to study the anesthetic-protein interaction. Halothane quenches bundle tryptophan fluorescence with a dissociation constant of 2.3 +/- 0.4 mM and a Hill number of 0.9 +/- 0.1. Tryptophan fluorescence decay analysis indicates that halothane quenches the protein fluorescence by a static mechanism. Circular dichroism spectroscopy revealed no change in protein secondary structure on exposure to halothane. Dissociation of the tetra-alpha-helix-bundle into 62-residue di-alpha-helical peptides by trifluoroethanol eliminated the halothane-protein interaction. The results suggest that halothane binds to the hydrophobic interior of the tetra-alpha-helix-bundle, close to the tryptophan residues. The protein tertiary and quaternary structures are required for anesthetic binding. This study demonstrates the feasibility of using synthetic tetra-alpha-helix-bundles as model anesthetic-binding proteins. The use of de novo designed bundle proteins should allow structural, energetic and functional descriptions of anesthetic-protein interactions.

A fluorescence and CD study on the interaction of synthetic lipophilic hepatitis B virus preS(120-145) peptide analogues with phospholipid vesicles.

The interaction of the immunogenic peptide of human hepatitis B virus (HBV) preS(120-145), including B and T epitopes, with phospholipid vesicles has been studied by fluorescence techniques and CD. In addition, interaction of three lipopeptides derived from preS(120-145) containing stearoyl, cholanoyl, and tripalmitoyl-S-glyceryl-cysteine (Pam3C) SS moieties with dipalmitoylphosphatidylcholine (DPPC) has been investigated by polarization fluorescence spectroscopy. Fluorescence experiments showed an increase in fluorescence intensity and a blue shift of the maximum emission wavelength upon interaction of preS(120-145) with DPPC vesicles below the transition temperature (Tc), indicating that the tryptophan moiety enters a more hydrophobic environment. Moreover, fluorescence polarization experiments showed that the peptide decreased the membrane fluidity at the hydrophobic core, increasing the Tc of the lipid and decreasing the amplitude of the change of fluorescence polarization associated with the cooperative melting of 1,6-diphenyl-1,3,5-hexatriene labeled vesicles. The absence of leakage of vesicle-entrapped carboxyfluorescein indicates that the peptide did not promote vesicle lysis. Besides, the three lipopeptides derived from preS(120-145) showed a more pronounced rigidifying effect at the hydrophobic core of the bilayer, with a significative increase in the Tc. Stearoyl- and cholanoyl-preS(120-145) restricted the motion of lipids also at the polar surface, whereas Pam3CSS-preS(120-145) did not alter the polar head group order. Finally, CD studies in 2,2,2-trifluoroethanol or in presence of vesicles suggested that the bound peptide adopted amphiphilic alpha-helical and beta-sheet structures, with an important contribution of the beta-turn. It is concluded that preS(120-145) can interact with the lipid membrane through the formation of an amphipathic structure combination of beta-sheet and alpha-helix aligned parallel to the membrane surface, involving the N-terminal residues, and penetrating only a short distance into the hydrophobic core. The C-terminal part, with a combination of beta-turn and beta-sheet structure, remains at the outer part of the bilayer, being potentially accessible to immunocompetent cells. Furthermore, coupling of an hydrophobic moiety to the N-terminal part of the peptide favors anchoring to the membrane, probably facilitating interaction of the peptide with the immunoglobulin receptor. These results are in agreement with the induction of immune response by preS(120-145) and with the enhanced immunogenicity found in general for lipid-conjugated immunopeptides.

CD of proline-rich polypeptides: application to the study of the repetitive domain of maize glutelin-2.

An overview of CD of proline-rich peptides is reported. First, structural characteristics, theoretical CD studies, and the biological relevance of polyproline II structure in such peptides are discussed. Second, a CD study of peptides belonging to the repetitive domain of maize glutelin-2, H-(Val-His-Leu-Pro-Pro-Pro)n-OH (n = 3, 5, 8), is described. This series of peptides displayed the CD features of polyproline II structure in water (5 degrees C, pH 5). Moreover, it was shown that the addition of increasing amounts of the polyanionic molecule heparin forced a displacement of the conformational equilibrium of those peptides toward higher proportions of the polyproline II structure. In contrast, when the temperature is raised such a structure gradually disappears, leading to more disordered conformations.

Interaction of opiate molecules with lipid monolayers and liposomes.

The interaction of opiate molecules (buprenorphine, codeine, dextromethorphan, diprenorphine, etorphine, meperidine, methadone, morphine, and naloxone) with lipids (phosphatidylcholine, phosphatidylinositol, phatidylinositol, phosphatidylserine, and cholesterol) by using liposomes and monomolecular layers as membrane models is described. The ability of opiates to induce leakage of carboxyfluorescin from liposomes is highly dependent on the hydrophobicity of the opiate molecules. Buprenorphine and etorphine increased the membrane permeability in all the experiments. On the contrary, naloxone, morphine, and codeine only caused a slight release of the entrapped dye in the presence of acidic phospholipids. Moreover, the leakage of carboxyfluorescein is directly related to the concentration of drug in the incubation media. Studies of the kinetics of the surface penetration of these molecules into monolayers of phospholipids were performed. Again, in this system, buprenorphine and etorphine exhibited stronger interactions than the most hydrophilic opiates. Nevertheless, in these experiments, differences among the opiate molecules are not so high as in the liposomes. The time course of the penetration of all of these molecules in the monolayers fits the Lineweaver-Burk equation. This fact suggests a lack of specific interactions and the predominance of hydrophobic factors. Moreover, the high percentage of release of entrapped dye caused by some opiate molecules suggests a possible toxic side-effect for these agents.

Continuous-flow solid-phase synthesis of potential antigenic peptides of hepatitis B virus.

The synthesis of three hepatitis B surface antigens derived from S and pre-S proteins (adw S(140-147), [Tyr148] adw S(139-148), and adw pre-S(120-145)) has been accomplished by the continuous flow Fmoc-polyamide solid phase method. The use of different scavengers and trimethylsilyl bromide (TMSBr) in trifluoroacetic acid as deprotecting procedures is discussed.