Carrier design: Synthesis and conformational studies of poly (L-lysine) based branched polypeptides with hydroxyl groups in the side chains

In the present study the development of a new series of branched polypeptides that contain hydroxyl groups in side chains is reported. Serine or threonine were attached by 1-hydroxy-benzotriazole catalyzed active ester method to the N-terminals of oligo (DL -alanine) chains grafted to a polylysine backbone resulted in poly[Lys-(Ser₁-DL -Ala_m)] (SAK) and poly-[Lys-(Thr_i-DL -Ala_m)] (TAK). Ser was coupled also directly to the η-amino groups of polylysine followed by polymerization of N-carboxy-DL -alanine anhydride resulting oligo (DL -Ala) chain terminals. In this way a reverse sequence was built up in the side chain corresponding to the poly[Lys-(DL -Ala_m-Ser_i)] (ASK). The number of hydroxyl groups in the polymer was increased by the synthesis of a branched polypeptide with oligo (DL -serine) branches instead of oligo (DL -alanine) ones—poly[Lys-(DL -Ser_m)] (SK). Classification of solution conformations of branched polypeptides was carried out by CD spectroscopy performed in water solution of various pH values and ionic strengths. Incorporation of single Ser residues in poly[Lys-(X_i)]-type polypeptides markedly promotes the formation of ordered structure without resulting precipitation even in high salt concentration. The presence of branches with multiple DL -Ser residues resulted in a slightly decreased ability of the polypeptide backbone to adopt an ordered conformation. Comparison of the CD properties of the SAK-ASK pair demonstrates that these compounds are similar, showing an increased tendency to form an ordered spatial arrangement in solution at elevated pH or ionic strength; however, differences in their CD spectra suggest that SAK has higher capability to form regular conformation under comparable conditions. The replacement of Ser by the Thr residue in poly[Lys-(X_i-DL -Ala_m)] induced a conformational transition and TAK exhibited a more helical structure. These results might indicate that not only hydrophobic or ionic attraction, but also H-bond interaction, can play a role in the formation and/or stabilization of ordered conformation of branched polypeptides. Findings with the hydroxyl group containing polymers reported in this paper can also explain their prolonged shelf stability and high water solubility. © 1997 John Wiley & Sons, Inc. Biopoly 42: 719–730, 1997     

Interaction of branched chain polymeric polypeptides with phospholipid model membranes

The surface properties at the air/water interface and the interaction of branched chain polymeric polypeptides with a general formula poly[Lys-(DL -Ala_m-X₁)], where X = Π (AK), Ser (SAK), or Glu (EAK), with phospholipids were investigated. Polylysine derivatives with polycationic (SAK, AK) or amphoteric (EAK) were capable to spread and form stable monomolecular layers. The stability of monolayers at the air/water interface was dependent on the side-chain terminal amino acid residue of polymers and can be described by SAK < AK < EAK order. The area per amino acid residue values calculated from compression isotherms were in the same range as compared to those of linear poly-α-amino acids and proteins. Moreover, these polymers interact with phospholipid monomolecular layers composed of dipalmitoyl phosphatidyl choline (DPPC) or DPPC/PG (PG: phosphatidyl glycerol; 95/5, mol/mol). Data obtained from compression isotherms of phospholipids spread on aqueous polymer solutions at different initial surface pressure indicated that insertion into lipid monolayers for SAK or AK is more pronounced than for EAK. The interaction between branched polypeptides and phospholipid membranes was further investigated using lipid bilayers with DPPC/PG and fluorescent probes located either at the polar surface [1-(4-trimethylammonium-phenyl)-6-phenyl-1,3,5-hexatriene (TMA-DPH) sodium anilino naphthalene sulfonate (ANS)] or within the hydrophobic core (DPH) of the liposome. Changes in fluorescence intensity and in polarization were observed when TMA-DPH or ANS, but not DPH were used. Comparative data also indicate that all three polymers interact only with the outer surface of the bilayer, but even the most marked penetration of polycationic polypeptide (SAK) did not result in alteration of the ordered state of the alkyl chains in the bilayer. Taken together, data obtained from mono- or bilayer experiments suggest that the interaction between branched polymers and phospholipids are highly dependent on the charge properties (Ser vs Glu) and on the identity (Ser vs Ala) of side-chain terminating amino acids. The binding of polymers to the model membranes could be mainly driven by electrostatic forces, but the significant role of hydrophilic properties in case of SAK cannot be excluded. © 1998 John Wiley & Sons, Inc. Biopoly 46: 169–179, 1998     

Experimental investigations on the backbone folding of proline-containing model tripeptides

Some proline-containing tripeptides with the general formulas R⁰CO-L -Pro-X-NHR³ (X = Gly,Sar,L -Ala,D -Ala) and R⁰CO-X-L -Pro-NHR³ (X = Gly,L -Ala,D -Ala) have been investigated in solution by ir and ¹H-nmr spectroscopies. Their favored conformational states depend mainly on both the primary structure and the chiral sequence of the molecules. In inert solvents the βII-folding mode is the most favored conformation for the L -Pro-D -Ala and L -Pro-Gly tripeptides, while the βII′-turn is largely preferred by D -Ala-L -Pro derivatives. Under the same conditions only about one-third of the whole conformers of L -Pro-L -Ala molecules adopts the βI-folding mode. Semiopened C₇C₅ and C₅C₇ conformations are appreciably populated in the L -Pro-L -Ala sequence, on the one hand, and in the Gly-L -Pro and L -Ala-L -Pro derivatives, on the other hand. In L -Pro-Sar and X-L -Pro models, the cis–trans isomerism around the middle tertiary amide function is observed. Thus cis L -Pro-Sar and L -Ala-L -Pro conformers are folded by an intramolecular i + 3 → i hydrogen bond, whereas cis D -Ala-L -Pro and Gly-L -Pro molecules accommodate an open conformation. In dimethylsulfoxide the βII- and βII′-folding modes are not essentially destabilized, as contrasted with the βI conformation, which is less populated. In water solution all the above-mentioned conformations, with the possible exception of the βII′-folding mode for D -Ala-L -Pro molecules, seem to vanish. Solute conformations are also compared with the crystal structures of four proline-containing tripeptides.     

The influence of the side-chain sequence on the structure-activity correlations of immunomodulatory branched polypeptides. Synthesis and conformational analysis of new model polypeptides

New branched polypeptides were synthesized for a detailed study of the influence of the side-chain structure on the conformation and biological properties. The first subset of polypeptides were prepared by coupling of tetrapeptides to poly[L-Lys]. These polymers contain either DL-Ala3-X [poly[Lys-(X-DL-Ala3)n]] or X-DL-Ala3 [poly[Lys-(DL-Ala3-X)n] (n less than or equal to 1)] tetrapeptide side chains. Another group of branched polymers comprise a mixture of DL-Alam and of DL-Alam-X oligomeric branches in a random distribution [poly[Lys-(DL-Alam-Xi)] (i less than 1, m approximately 3)]. In each subset the X = Leu or Phe derivatives were prepared. The N-protected tetrapeptides were synthesized by conventional liquid phase methods and were coupled as active esters. The degree of racemization was found relatively high both for active esters and coupled derivatives, when optically active amino acids were in the C-terminal position of the tetrapeptides. In the case of the poly[Lys-(Leu-DL-Ala3)n] derivative, comparative experiments were carried out using various methodical alterations. The highest stereochemical homogeniety could be achieved when the tetrapeptide active ester was synthesized by the "backing off" method. CD spectra of poly[Lys-(Xi-DL-Alam)] (i less than 1, m approximately 3) and of poly[Lys-(X-DL-Ala3)n] were analyzed and compared to those of poly[Lys-(DL-Alam-Xi)] and of poly[Lys-(DL-Ala3-X)n]. All measurements were performed in water solutions of varying pH values and ionic strengths. The data obtained suggest that branched polypeptides containing a mixture of two different types of oligomeric side chains (DL-Alam and DL-Alam-Xi or Xi-DL-Alam) distributed randomly adopt an almost identical conformation to those that comprise only the respective tetrapeptide (DL-Ala3-X or X-DL-Ala3) branches. The results also indicate that the tendency to form an ordered structure is determined by the identity and the position of the chiral amino acid X (Phe or Leu) in the side chain.     

The beta conformation of polypeptides of valine, isoleucine, and threonine in solution and solid-state: optical and infrared studies.

Water-soluble polypeptides of L -valyl and L -isoleucyl residues flanked with DL -lysyl blocks [poly(DL Lys · HCl)_x–poly(L Val)_y–poly(DL Lys · HCl)_x, poly(DL Lys · HCl)_x–poly-(L Ile)_y–poly(DL Lys · HCl)_x] and homopoly(L -threonine) were prepared. The β conformation of these polymers in water, as well as in aqueous methanol, was confirmed by infrared spectroscopy and circular dichroism studies. The optical properties of these valyl and isoleucyl polypeptides were quite different from those of previously reported synthetic homopolypeptides in the β structure. Their differences could be explained by the presence of a “single extended β chain” without either intra- or interchain association.     

Block sequential polypeptides of L-alanine and glycine with D, L-glutamic acid

Sequential polypeptides of L -alanine(A) and glycine(G), which were incorporated between two blocks of poly(D ,L -glutamic acid) (DL), were synthesized by applying Merri-field's solid-phase method. On the basis of optical rotatory dispersion criteria, DL(A)₃₈-DL was found to assume the α-helix in the whole range of the water-methanol system; whereas other block sequential polypeptides were found to assume the random-coiled conformation in water and partly the α-helix at the high methanol content. The stability of the α-helix decreased in the order: DL(A)₃₈DL, DL(A₂G)₁₀DL, DL(A₂G)₆DL, and DL(A₃G)₇DL. This phenomenon may be explained in terms of the dependence of hydrophobic bonding between the C₃H group of the ith L -alanine regularly arranged on the surface of the α-helix and the C₂H group of the (i + 3)th residue on whether the residue is alanine or glycine. The role which the methanol plays in stabilizing the α-helix is also discussed.     

Synthesis of poly(L-Tyr-L-Glu-L-Ala-Gly) and poly(L-Glu-L-Lys-L-Ala) and their circular dichroism spectra in aqueous solution

Two sequential polypeptides, poly(O-benzyl-L -Tyr-γ-benzyl-L -Glu-L -Ala-Gly) and poly(ε-benzyloxycarbonyl-L -Lys-L -Glu-L -Ala), were synthesized, the former by the pentachlorophenyl ester of the tetrapeptide monomer and the latter by the azide of the tripeptide monomer. After deprotection and dialysis, poly(L -Tyr-L -Glu-L -Ala-Gly) was obtained in 71% yield and had a molecular weight of 53,000. The circular dichroism spectra (CD) of the polymer at pH's 7.2, 10.5, and 11.8 and of oligomers and of the monomer at pH 7.2 indicated that the polymer exists in an α-helical conformation. After deprotection, poly(L -Lys-L -Glu-L -Ala) was obtained in 37% yield and had a molecular weight of 3000. The CD spectra of the polymer at pH 7.2 and 2.8, and of the monomer at pH 7.2, indicated that the polymer is in a randomly coiled configuration.     

Conformation of sequential and random copolypeptides of lysine and alanine in sodium dodecyl sulfate solution

A series of sequential polypeptides, (Lys_i-Ala_j)_n, and random copolypeptides, (Lys^x, Ala^y)_n, were synthesized. The competitive effect of Ala, a helix former, and Lys, whose homopolymer has a β-form in neutral NaDodSO₄ solution, was determined by CD and absorption spectroscopy. All the polypeptides studied were unordered in neutral solution without the surfactant. Of the six sequential polypeptides only (Lys-Ala)_n adopted a stable β-form in NaDodSO₄ solution. Most striking is the difference between this polypeptide, (Lys₂-Ala₂)_n and (Lys^x, Ala^y)_n, even though they all have equimolar Lys and Ala. (Lys₂-Ala₂)_n was partially helical in 2.5–5 mM NaDodSO₄ but approached the unordered form in 50 mM NaDodSO₄, whereas (Lys⁵⁰, Ala⁵⁰)_n was completely helical in all NaDodSO₄ concentrations. Even Lysrich (Lys₂-Ala)_n and (Lys₃-Ala)_n formed a partial helix and a trace of the β-form, respectively, in low NaDodSO₄ concentrations; both reverted to the unordered form in high NaDodSO₄ concentrations. These results can be explained by Pauling-Corey's model for β-pleated sheets. Only (Lys-Ala)_n has all DodSO-bound Lys⁺ residues on one side and Ala residues on the other side of the polypeptide chain. They can nestle quiet efficiently in a β-sheet and between neighboring β-sheets. Our results further imply that random copolypeptides are not completely random; they comprise varying segments of (Lys_k-Ala_m), where k and m could vary from zero to a small integer.     

Solid-state conformation of copolymers of β-benzyl-L-aspartate with L-alanine,L-leucine,L-valine, γ-benzyl-L-glutamate,or ϵ-carbobenzoxy-L-lysine

The solid-state conformation of copolymers of β-benzyl-L -aspartate [L -Asp(OBzl)] with L -leucine (L -Leu), L -alanine (L -Ala), L -valine (L -Val), γ-benzyl-L -glutamate [L -Glu(OBzl)], or ?-carbobenzoxy-L -lysine (Cbz-L -Lys) has been studied by ir spectroscopy and circular dichroism (CD). The ir spectra in the region of the amide I and II bands and in the region of 700–250 cm^?1 have been determined. The results from the ir studies are in good agreement with data obtained by CD experiments. Incorporation of the amino acid residues mentioned above into poly[L -Asp(OBzl)] induces a change from the left-handed into the right-handed α-helix. This conformational change for the poly[L -Asp(OBzl)] copolymers was observed in the following composition ranges: L -Leu, 0–15 mol %; L -Ala, 0–32 mol %; L -Val, 0–8 mol %; L -Glu(OBzl), 3–10 mol %; and Cbz-L -Lys, 0–9 mol %.     

Thermal denaturation of chromatin and lysine copolymer-DNA complexes. Effects of ethylene glycol.

Chromatin was thermally denatured in the presence and absence of 1M ethylene glycol using a technique whereby both the hyperchromism and ellipticity are monitored simultaneously. Model complexes containing poly(L -Lys) or poly(L -Lys, L -Ala, Gly) and DNA were similarly melted in order to assist in interpreting the chromatin results. In both cases a general pattern emerged whereby ethylene glycol perturbed the resultant melting profile, showing increased hyperchromicity, ellipticity, and premelt slope. In addition, ethylene glycol destabilizes and reduces the high melting region of polypeptide-bound DNA and the extent of higher ordered structure in model complexes and chromatin. These results emphasize the importance of hydrophobic forces in polypeptide–polypeptide and polypeptide–DNA interactions.     

15N-nmr spectroscopy. 33. Assignments of isotactic and syndiotactic sequences in poly(D,L-amino acids)

¹⁵N-enriched (D ,L -Leu)_n, (γ-OMe-D ,L -Glu)_n, (D ,L -Val)_n, and (D ,L -Phe)_n were prepared, 40.55-MHz ¹⁵N-nmr spectra were measured in various solvents. The signal patterns depend strongly on the nature of the solvent, yet in most cases at least four signals are resolved, representing the four enantiomeric pairs of triads L -L -L (D -D -D ), L -D -L (D -L -D ), L -L -D (D -D -L ), and D -L -L (L -D -D ). Numerous copolypeptides of the general structure (A)_n-B*-(A)_m (the asterisk denotes 40–50% ¹⁵N enrichment) were synthesized and measured as models for syndiotactic sequences in the spectra of poly(D ,L -amino acids). In this way unambiguous assignments for both isotactic and syndiotactic trials were obtained. A spectroscopic rule was established: “isotactic sequences absorb downfield of syndiotactic ones.” Furthermore, the spectra of various types of stereocopolypeptides such as (L -Leu/L -Val)_n and (L -Leu/D -Val)_n were investigated, including the ternary systems (L -Leu/L -Ala/D -Ala)_n (L -Leu/L -Ala/Gly)_n, (L -Leu/D -Ala/Gly)_n, (L -Val/L -Ala/Gly)_n, and (L -Val/D -Ala/Gly)_n. All copolymerization of D - and L -amino acid NCAs investigated in this work showed a low degree of stereoselectivity.     

Raman spectroscopic study of poly (β-benzyl-L-aspartate) and sequential polypeptides

Poly-β-benzyl-L -aspartate (poly[Asp(OBzl)]) forms either a lefthanded α-helix, β-sheet, ω-helix, or random coil under appropriate conditions. In this paper the Raman spectra of the above poly[Asp(OBzl)] conformations are compared. The Raman active amide I line shifts from 1663 cm^?1 to 1679 cm^?1 upon thermal conversion of poly[Asp(OBzl)] from the α-helical to β-sheet conformation while an intense line appearing at 890 cm^?1 in the spectrum of the α-helix decreases in intensity. The 890 cm^?1 line also displays weak intensity when the polymer is dissolved in chloroform–dichloroacetic acid solution and therefore is converted to the random coil. This line probably arises from a skeletal vibration and is expected to be conformationally sensitive. Similar behavior in the intensity of skeletal vibrations is discussed for other polypeptides undergoing conformational transitions. The Raman spectra of two cross-β-sheet copolypeptides, poly(Ala-Gly) and poly(Ser-Gly), are examined. These sequential polypeptides are model compounds for the crystalline regions of Bombyx mori silk fibroin which forms an extensive β-sheet structure. The amide I, III, and skeletal vibrations appeared in the Raman spectra of these polypeptides at the frequencies and intensities associated with β-sheet homopolypeptides. Since the sequential copolypeptides are intermediate in complexity between the homopolypeptides and the proteins, these results indicate that Raman structure–frequency correlations obtained from homopolypeptide studies can now be applied to protein spectra with greater confidence. The perturbation scheme developed by Krimm and Abe for explaining the frequency splitting of the amide I vibrations in β-sheet polyglycine is applied to poly(L -valine), poly-(Ala-Gly), poly(Ser-Gly), and poly[Asp(OBzl)]. The value of the “unperturbed” frequency, V₀, for poly[Asp(OBzl)] was significantly greater than the corresponding values for the other polypeptides. A structural origin for this difference may be displacement of adjacent hydrogen-bonded chains relative to the standard β-sheet conformation.     

Synthesis, conformation, biodistribution, and in vitro cytotoxicity of daunomycin-branched polypeptide conjugates.

Daunomycin has been attached to various structurally related synthetic branched polypeptides with a polylysine backbone, using its acid-labile cis-aconityl derivative (cAD). Due to the importance of the side-chain structure in alpha-helix formation and immunological and pharmacological properties of branched polypeptides, we have investigated the conformation, biodistribution, and in vitro cytotoxicity of cAD-carrier conjugates with polypeptides containing amino acid residues of different identity and/or configuration at the side-chain end (XAK type) or at the position next to the polylysine backbone (AXK type), where X = Leu, D-Leu, Pro, Glu, or D-Glu. According to CD studies, polycationic conjugates with hydrophobic Leu in the side chains could assume a highly ordered conformation, while amphoteric conjugates containing Glu proved to be unordered in PBS. The reduction of in vitro cytotoxic activity of cAD by conjugation to carriers and the biodistribution profile of the conjugates were found to be dependent predominantly on the charge properties and on the side-chain sequence of the carrier polypeptide. It was demonstrated that by proper combination of structural elements of the carrier molecule, it is feasible to construct a cAD-branched polypeptide conjugate with significantly prolonged blood survival and with no reduction in in vitro cytotoxicity of the drug.     

Conformational energy studies on N-methylated analogs of thyrotropin releasing hormone, enkephalin, and luteinizing hormone-releasing hormone

Empirical conformational energy calculations have been carried out for N-methyl derivatives of alanine and phenylalanine dipeptide models and N-methyl-substituted active analogs of three biologically active peptides, namely thyrotropin-releasing hormone (TRH), enkephalin (ENK), and luteinizing hormone-releasing hormone (LHRH). The isoenergetic contour maps and the local dipeptide minima obtained, when the peptide bond (ω) preceding the N-methylated residue is in the trans configuration show that (1) N-methylation constricts the conformational freedom of both the ith and (i + 1)th residues; (2), the lowest energy position for both residues occurs around ? = ?135° ± 5° and ψ = 75° ± 5°, and (3) the α_L conformational state is the second lowest energy state for the (i + 1)th residue, whereas for the ith residue the C₅ (extended) conformation is second lowest in energy. When the peptide bond (ω_i) is in the cis configuration the ith residue is energetically forbidden in the range ? = 0° to 180° and ψ = ?180° to +180°. Conformations of low energy for ω_i = 0° are found to be similar to those obtained for the trans peptide bond. In all the model systems (irrespective of cis or trans), the α_R conformational state is energetically very high. Significant deviations from planarity are found for the peptide bond when the amide hydrogen is replaced by a methyl group. Two low-energy conformers are found for [(N-Me)His²]TRH. These conformers differ only in the ? and ψ values at the (N-Me)His² residue. Among the different low-energy conformers found for each of the ENK analogs [D -Ala²,(N-Me)Phe⁴, Met⁵]ENK amide and [D -Ala²,(N-Me)Met⁵]ENK amide, one low-energy conformer was found to be common for both analogs with respect to the side-chain orientations. The stability of the low-energy structures is discussed in the light of the activity of other analogs. Two low-energy conformers were found for [(N-Me)Leu⁷]LHRH. These conformations differ in the types of bend around the positions 6 and 7 of LHRH. One bend type is eliminated when the active analog [D -Ala⁶,(M-Me)Leu⁷]LHRH is considered.     

Helix promotion in polypeptides by polyols

The helix content of [L -Lys(Me₃)]_n · ClO₄, and [L -Lys(Me₃)⁵⁰, L -Ala⁵⁰]_n · ClO₄ in water is markedly increased by the presence of sucrose and glycerol. For [L -Lys(Me₃)]_n · ClO₄ the ellipticity at 222 nm changes from +2 × 10³ deg cm² dmole^?1 in water to ?44 × 10³ in 50% glycerol. Sucrose does not promote helix formation in melittin at pH 7.2, but glycerol does. At pH 5.5 sucrose and, more so, glycerol, induce helix in melittin. Glycerol induces some helix in methylated melittin, but less than in melittin. The results are discussed in relation to excluded volume effects, ΔG of transfer of peptide and hydrophobic groups from water to mixed solvents, electrostatic effects, and preferential hydration. © 1993 John Wiley & Sons, Inc.     

Unusual conformational preferences of β-alanine containing cyclic peptides. VII

In the present paper we describe the synthesis, purification, and single crystal x-ray analysis of the cyclic pentapeptide cyclo-(Pro-Phe-Phe-β-Ala-β-Ala). This compound crystallizes in the orthorhombic space group P2₁2₁2₁ from methanol and adopts in the solid state an unusual conformation characterized by a cis β-Ala⁵-Pro¹ peptide bond and by an intramolecular hydrogen bond stabilizing a C₁₁- and a C₁₂-ring structure. The C₁₁, structure contains the Phe³ and the β-Ala⁴ at the corner position of the turn; it is the first observation of a type II β-turn enlargement due to the insertion of an extra methylene group of the β-alanine residue. The rest of the molecule participates in a newly characterized C₁₂-ring structure, which incorporates a β-Ala residue at position i of the turn. © 1996 John Wiley & Sons, Inc.     

Polymerization of L- and DL-phenylalanine N-carboxyanhydride by poly(N-methyl-L-alanine)

Polymerizations of L - and DL -phenylalanine N-carboxyanhydride in nitrobenzene by poly (N-methyl-L -alanine) of varying degrees of polymerization (n = 1–30) were investigated. Poly(N-methyl-L -alanine) was prepared by the polymerization of N-methyl-L -alanine NCA with N-methyl-L -alanine diethylamide and the degree of polymerization was controlled by the molar ratio [NCA]/[Catalyst] + 1. This polymer was shown to be an asymmetrically selective catalyst which polymerized L -phenylalanine NCA at a faster rate than DL -phenylalanine NCA. With increasing degree of polymerization the stability of the secondary structure of poly(N-methyl-L -alanine) increased. This was confirmed by circular dichroism spectra. However, the degree of asymmetric selection did not increase as the stability of the secondary structure of poly(N-methyl-L -alanine) increased. These findings indicate that the interaction of a growing polypeptide in an ordered structure with NCA molecules prior to the reaction does not lead to an asymmetric selection, and that the mechanism of the asymmetric selection by poly(N-methyl-L -alanine) should be different from those proposed so far.     

Effect of phospholipid bilayers on solution conformation of branched polymeric polypeptides and peptide-polymer conjugates

This report provides a detailed analysis on the influence of phosholipid bilayers on the conformation of poly[Lys(X(i)-DL-Ala(m))] (XAK, where X = Ser, Orn, Glu, or AcGlu) type branched polypeptides and their peptide conjugates. CD spectra of polycationic (SAK, OAK), amphoteric (EAK), or polyanionic (Ac-EAK) polylysine derivatives were recorded in 0.25M acetate buffer at pH 7.4 as well as in the presence of DPPC or DPPC/PG (95/5, 80/20 mol/mol) liposomes. Based on these data, two groups of polypeptides are described. Group one contains polypeptides with significantly ordered conformation even in buffer solution (SAK, AcEAK), which is essentially not altered by phospholipids. Group two, branched polypeptides (OAK, EAK), with only partially ordered conformation in aqueous solution in the presence of phospholipid bilayers with high PG content, could adopt more (EAK) or less (OAK) ordered alpha-helical structure depending on their charge properties. In addition, we report on the synthesis of two new sets of oligopeptide-branched polypeptide conjugates. Studies with selected conjugates suggest that these compounds are highly ordered in buffer solution almost regardless from the helix-forming ability of the carrier (AK, SAK, EAK) and from the hydrophilic/hydrophobic character of peptides attached (AVKDEL vs FWRGDLVFDFQV). Addition of phospholipid bilayers with different composition essentially had no modifying effect on conformation of conjugates. From this we can conclude that the covalently coupled oligopeptides has a predominant effect of the conformational properties of conjugates.     

Absorption and circular dichroism spectra of CuCl2 complexed with poly(S-carboxymethyl-L-cysteine) and poly(S-carboxyethyl-L-cysteine)

The interaction of CuCl₂ with poly(S-carboxymethyl-L -cysteine) (poly[Cys(CH₂COOH)]) and poly(S-carboxyethyl-L -cysteine) (poly[Cys(C₂H₄COOH)]) were studied by absorption spectra and circular dichroism (CD). On mixing CuCl₂ with polypeptide solutions, absorption bands appeared at 320–325 nm in both polypeptides, and at 255–260 nm in the case of poly[Cys(CH₂COOH)]. A stable bound species was formed in the case of poly[Cys(CH₂COOH)], since the apparent molar absorption coefficient of the bound species did not depend on the mixing ratio. From the absorption data, it was inferred that Cu²⁺ ions were complexed with the side chains, most probably with sulfur atoms and carboxyl groups. Induced optical activities were observed for the two polypeptides. The CD spectra of poly[Cys(CH₂COOH)] + CuCl₂ gave simpler aspects than those of poly[Cys(C₂H₄COOH)] + CuCl₂.     

The β association of (DLLys)10–(LVal)20–(DLLys)10: An nmr study

(DL Lys)₁₀–(L Val)₂₀–(DL Lys)₁₀, a copolymer of a valine block in the β conformation with randomly coiled flanking blocks of lysine [Kubota, S. & Fasman, G. D. (1975) Biopolymers 14 , 605–631], was studied by nuclear magnetic resonance. The peak areas of the N? H and C? H resonances of valine and lysine are concentration-dependent with little chemical shift change. A model is presented describing the aggregation of the copolymer. Additional evidence, obtained by monitoring the spin-lattice relaxation times of amino, amide, γ-methyl-valine, and ?-methylene-lysine, is consistent with the aggregation model. Hydrodynamic studies are presented which show monomer → oligomer aggregation of four or five subunits.