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.     

Circular dichroism of N-phenylnaphthylamine derivatives complexed with the β-form of poly(L-lysine)

Complex formation of 1-anilinonaphthalene-8-sulfonate (ANS) and 2-p-toluidinonaphthalene-6-sulfonate (TNS) with the β-form of poly(L -lysine) [(β-Lys)_n] has been studied by circular dichroism (CD) and absorption spectra measurements. Not only hydrophobic interactions but also hydrogen-bonding and electrostatic interactions contribute to complex formation. The relative importance of these stabilizing factors depends on the relative position of the arylamino group and the sulfonate. For example, ionic interactions play a significant role in the binding of 1,8-ANS and 1,8-TNS, but not in the case of 2,6-TNS. The induced CD of the complexes of (β-Lys)_n with 1,8-ANS and 1,8-TNS is consistent with theoretical calculations for nonplanar conformations of these dyes, twisted in a left-handed sense. As expected for steric reasons, the dominant isomer is one in which the arylamino group is oriented away from the 8-sulfonate (α₁). The induced CD of complexes with 2,6-TNS can be accounted for by an equimolar mixture of left-handed isomers in which the arylamino group is oriented toward the 1-position (β₂) and toward the 3-position (β₁). Our results demonstrate that (β-Lys)_n is capable of chiral discrimination and suggest its general utility for CD studies of racemic anionic dyes.     

Kinetic studies of the interaction of methyl orange with poly(L-lysine) by stopped-flow with circular dichroism detection

The interaction of methyl orange with poly(L -lysine) was studied kinetically by the stopped-flow technique with CD detection, as well as by static CD titration experiments. In the static experiments, the differences observed in the polymer-to-dye ratio dependences of the CD spectra and absorption spectra suggested at least two kinds of bound states of the methyl orange attached to the polymer. The kinetic experiments using the stopped-flow apparatus, however, revealed four distinct reaction processes. The reaction mechanism was elucidated from the concentration dependence of the time constant for each process as follows: the first process was attributed to the bimolecular binding step of methyl orange to the side chain of poly(L -lysine), the second and third process were ascribed to the intramolecular reaction of the polymer–dye complex, and the fourth process was found to be the intermolecular aggregation of the polymer–dye complex. The origin of the stacking of methyl orange on poly(L -lysine) is discussed on the basis of the characteristics of signal amplitudes obtained from the kinetic experiments for these processes.     

Estimation of the circular dichroism exhibited by statistical coils of poly(L-alanine) and unionized poly(L-lysine) in water

The circular dichroism of Ac-(Ala)_x-OMe and H-Lys-(Lys)_x-OH with x = 1, 2, 3, and 4 has been measured in aqueous solutions. The oligomers with x = 4 show similar circular dichroism spectra in water when the lysyl amino groups are protonated, and they respond in similar fashion to heating and to sodium perchlorate. Both oligomers at 15°C exhibit a positive circular dichroism band at 217–218 nm, which is eliminated by the isothermal addition of 4 M sodium perchlorate or by heating. The positive circular dichroism of the lysine oligomer is also eliminated when the pH is elevated to deprotonate the amino groups. Positive circular dichroism is still observed for Ac-(Ala)₄-OMe at elevated pH. Circular dichroism spectra have been estimated for poly(L -alanine) and poly(L -lysine) as statistical coils under the above conditions, based on the trends established with the oligomers. Poly(L -lysine) and poly(L -alanine) are predicted to exhibit similar circular dichroism behavior in aqueous solution so long as the lysyl amino groups are protonated. The circular dichroism of the statistical coil of poly(L -lysine), but not poly(L -alanine), is predicted to change when the pH is elevated sufficiently to deprotonate the lysyl amino groups. These results suggest that the unionized lysyl side chains participate in interactions that are not available to poly(L -alanine). Hydrophobic interactions may occur between the unionized lysyl side chains. Protonation of the lysyl amino groups is proposed to disrupt these interactions, causing poly(L -alanine) and protonated poly(L -lysine) to have similar circular dichroism properties.     

Infrared linear dichroism investigations of deoxyribonucleic acid complexes with poly(L-arginine) and poly(L-lysine).

Complexes between DNAs from various sources and poly(L-lysine) and poly(L-arginine) were studied by means of infrared linear dichroism. The measurements of dichroic ratios allowed us to determine the orientation of the phosphate group of DNA in the complexes with basic polypeptides. At high relative humidities (higher than 90%, B form), the bisector of the less than OPO in the complexes forms an angle with respect to the helical axis which has a value lower by about 4 degrees than in the corresponding DNA sample. This change of orientation of the phosphate group of DNA indicates a modification of the B form upon binding of polylysine or polyarginine. The structural transitions B leads to A and B leads to C measured as a function of relative humidities were not affected by formation of complexes with both basic polypeptides. Similar results were obtained for complexes prepared by direct mixing or by salt gradient dialysis. The presence of A and C forms was observed in complexes of DNA with poly(L-lysine) and poly(L-arginine) at lower relative humidity. Thus, the conformational flexibility of DNA in complexes with polylysine and polyarginine is not changed despite a substantial increase in the Tm (melting temperature). These results are considered as a model for the understanding of interactions between DNA and histones particularly of the binding of the N-terminal fragment, lysine or arginine rich.     

The alpha-helix to beta-sheet transition in poly(L-lysine): effects of anesthetics and high pressure.

Poly(L-lysine) exists in a random-coil formation at a low pH, alpha-helix at a pH above 10.6, and transforms into beta-sheet when the alpha-helix polylysine is heated. Each conformation is clearly distinguishable in the amide-I band of the infrared spectrum. The thermotropic alpha-to-beta transition was studied by using differential scanning calorimetry. At pH 10.6, the transition temperature was 43.5 degrees C and the transition enthalpy was 170 cal/mol residue. At pH 11.85, the measurements were 36.7 degrees C and 910 cal/mol residue, respectively. Volatile anesthetics (chloroform, halothane, isoflurane and enflurane) partially transformed alpha-helix polylysine into beta-sheet. The transformation was reversed by the application of hydrostatic pressure in the range of 100-350 atm. Apparently, the alpha-to-beta transition was induced by anesthetics through partial dehydration of the peptide side-chains (beta-sheet surface is less hydrated than alpha-helix). High pressure reversed this process by re-hydrating the peptide. Because the membrane spanning domains of channel and receptor proteins are predominantly in the alpha-helix conformation, anesthetics may suppress the activity of excitable cells by transforming them into a less than optimal structure for electrogenic ion transport and neurotransmission. Proteins and lipid membranes maintain their structural integrity by interaction with water. That which attenuates the interaction will destabilize the structure. These data suggest that anesthetics alter macromolecular conformations essentially by a solvent effect, thereby destroying the solvation water shell surrounding macromolecules.     

Vacuum-ultraviolet circular dichroism of chondroitins and their complexes with poly(L-arginine)

The vacuum-ultraviolet circular dichroism (VUCD) of chondroitin and chontroitin-6-sulfate has been measured to 160 nm for films and to 170 nm for D₂O solutions. The pD-dependent dichroic behavior of these glycosaminoglycans in D₂O is similar above 200 nm and is in agreement with previous studies. Near 190 nm, the CD band sign is also dependent on pD. VUCD spectra were recorded for films and solutions of poly(L -arginine). In trifluoroethanol the polypeptide is α-helical, while in D₂O it exists as a random coil. The well-characterized coil–helix transition of poly(L -arginine) during complexation with chondroitin-6-sulfate was observed by VUCD, including the previously inaccessible entire π → π* band. By construction of difference spectra it was also possible to monitor the VUCD of the polysaccharide component during complexation.     

Vibrational circular dichroism spectra of three conformationally distinct states and an unordered state of poly(L-lysine) in deuterated aqueous solution

Fourier transform ir vibrational circular dichroism (VCD) spectra in the amide I′ region of poly(L-lysine) in D₂O solutions have confirmed the existence of three distinct conformational states and an unordered conformational state in this homopolypeptide. Characteristic VCD spectra are presented for the right-handed α-helix, the antiparallel β-sheet, an extended helix conformation previously referred to as the so-called “random coil,” and a completely unordered conformation characterized by the absence of any amide I′ VCD. VCD for the antiparallel β-sheet in solution and the unordered chain conformation are presented for the first time. Each of the four different VCD spectra is unique in appearance and lends weight to the view that VCD has the potential to become a sensitive new probe of the secondary structure of proteins in solution.     

Reassessment of the electronic circular dichroism criteria for random coil conformations of poly(L-lysine) and the implications for protein folding and denaturation studies

The circular dichroism (CD) spectra of poly(L-lysine) in water and ethanediol/water (2:1) solutions in the temperature range -110 to 85 degrees C are presented. The results combined with vibrational CD data are interpreted in terms of a two-state conformational equilibrium with a left-handed trans polyproline II conformation being preferred at low temperatures. The relevance of these studies to the CD criteria for random-coil conformations, the study of helix-coil transitions and protein/peptide folding is pointed out.     

Biphasic effects of alcohols on the phase transition of poly(L-lysine) between alpha-helix and beta-sheet conformations.

Poly(L-lysine) exists as a random-coil at neutral pH, an alpha-helix at alkaline pH, and a beta-sheet when the alpha-helix poly(L-lysine) is heated. The present Fourier-transform infrared (FTIR) study showed that short-chain alcohols (methanol, ethanol, and 2-propanol) partially transformed alpha-helix poly(L-lysine) to beta-sheet when their concentrations were low. At higher concentrations, however, these alcohols reversed the reaction, and the alcohol-induced beta-sheet was transformed back to alpha-helix structure. The reversal occurred at 1.40 M methanol, 0.96 M ethanol, and 0.55 M 2-propanol. The alcohol effects on the secondary structure were further investigated by circular dichroism (CD) on the thermally induced beta-sheet poly(L-lysine). Methanol, ethanol, and 1-propanol, but not 1-butanol, shifted the negative mean-residue ellipticity at 217 nm of the beta-sheet poly(L-lysine) to the positive side at low concentrations of the alcohols and to the negative side at high concentrations. With 1-butanol, only the positive-side shift was observed. The positive-side shift at low concentrations of alcohols indicates enhancement of the hydrophobic interactions among the side chains of the polypeptide in the beta-sheet conformation. The negative-side shift indicates a partial transformation to alpha-helix. The shift from the positive to negative side occurred at 7.1 M methanol, 4.6 M ethanol, and 3.1 M 1-propanol. The alcohol concentrations for the beta-to-alpha transition were higher in the CD study than in the IR study.(ABSTRACT TRUNCATED AT 250 WORDS)     

Highly branched poly(L-lysine)

This paper describes the synthesis of several novel water-soluble highly branched polypeptides. The synthesis starts with the ring-opening polymerization of epsilon-benzyloxycarbonyl-l-lysine N-carboxyanhydride (Z-Lys NCA) or epsilon-trifluoroacetyl-l-lysine N-carboxyanhydride (TFA-Lys NCA), followed by end functionalization of the peptide chain with N(alpha),N(epsilon)-di(9-fluorenylmethoxycarbonyl)-l-lysine (N(alpha),N(epsilon)-diFmoc Lys). Deprotection of the N(alpha),N(epsilon)-diFmoc Lys end group affords two new primary amine groups that can initiate the polymerization of a second generation of branches. Repetition of this ring-opening polymerization-end functionalization sequence affords highly branched poly(epsilon-benzyloxycarbonyl-l-lysine) (poly(Z-Lys)) and poly(epsilon-trifluoroacetyl-l-lysine) (poly(TFA-Lys)) in a small number of straightforward synthetic steps. Removal of the side-chain protective groups yields water-soluble and highly branched poly(l-lysine)s, which may be of potential interest for a variety of medical applications.     

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.     

A circular dichroism study of the binding of CC-1065 to B and Z form poly(dl-5BrdC).poly(dl-5BrdC)

CC-1065, Benzo[1,2-b:4,3-b']dipyrrole-3(2H)-carboxamide, 7-[[1,6-dihydro-4-hydroxy-5-methoxy-7-[(4,5,8,8a-tetrahydro-7-methyl-4- oxocyclopropa[c]pyrrolo[3,2-e]indol-2(1H)-yl)carbonyl]benzo [1,2-b:4,3-b']dipyrrol-3(2H)-yl]carbonyl]-1,6-dihydro-4-hydroxy- 5-methoxy-, (7bR,8aS), binds to the B form of poly(dl-5BrdC).poly(dl-5BrdC) to yield a reversibly bound species whose stability with respect to an irreversibly bound species (presumably the inosine N-3 adduct) is much greater than it is for other DNA polymers. Competitive binding experiments with netropsin, show that this reversibly bound species of CC-1065 contains CC-1065 in the minor groove of the double helix. A review of the CC-1065 binding data obtained on other synthetic DNA polymers suggests that the widely different rates of species conversion shown by these polymers may result from small differences in DNA secondary structure rather than from different alkylating abilities of the adenine or inosine N-3 active site. CC-1065 converts the Z-form of poly(dl-5BrdC).poly(dl-5BrdC) in 3.5 M sodium chloride to the B form and does not bind to the Z form in this solvent system. CC-1065 bound to the B form polymer inhibits the formation of the Z form if the helix is saturated with CC-1065. Regions of the polymer without bound CC-1065 can convert to the Z form with added salt, producing a situation where the polymer contains both the B and Z conformations. In 4.0 M sodium chloride, where the Z conformation is also predominate, the addition of CC-1065 causes chiral aggregates to form, and CC-1065 binds to the aggregates. The addition of dimethylformamide in the absence of CC-1065 or a simple dilution of the 4.0 M sodium chloride polymer solution with water also causes aggregation, indicating that the Z form of this polymer in 4.0 M sodium chloride is unstable with respect to an aggregated form.     

On the various types of circular dichroism induced on acridine orange bound to poly(S-carboxymethyl-L-cysteine).

Circular dichroism and absorption spectra are measured on mixed solutions of acridine orange and poly(S-carboxymethyl-L -cysteine) at different pH and P/D mixing ratios. The observed circular dichroism spectra are classified into several types, mainly based on the number and sign of circular dichroic bands in the visible region. Three of them are associated with the absorption spectra characteristic of dimeric dye or higher aggregates of dye. Type I is observed with solutions, of which the pH is acid and P/D is higher than 4, and it has an unsymmetrical pair of positive and negative dichroic bands at 470 and 430 nm. This type is induced on the dye bound to the polymer in the β-conformation. Types II and III are considered to be characteristic of randomly coiled polymers. Type II is exhibited by solutions of P/D higher than 1 at pH 5–7 and has two dichroic bands around the same wavelengths as Type I but with opposite signs and an additional positive band at 560 nm. Type III, shown by solutions of P/D 2–0.6 at pH 6–10.5, has three dichroic bands around the same wavelengths as Type II but with signs opposite to it. The other two types of circular dichroism, induced for the solutions of P/D less than 1 at slightly acid pH, are associated with the absorption spectra of monomeric dye and are observed with disordered or randomly coiled polymer. They have a pair of dichroic bands at 540 and 425 nm, and the signs of these bands are opposite to each other in these two types.     

HMG proteins (1 + 2) form beaded structures when complexed with closed circular DNA.

Structures bearing a resemblance to nucleosomes can be assembled by incubating calf thymus High Mobility Group proteins (1 + 2) with closed circular DNA. These HMG proteins are capable of forming beads and inducing superhelicity when bound to DNA. However, they do not protect from nuclease digestion the discrete DNA fragments characteristic of nucleosomes. The relationship between HMGs (1 + 2) and the "primitive" histone-like DNA-packaging proteins from prokaryotes and mitochondria is discussed.     

Conformational change of poly(L-lysine) induced by lipid vesicles of dilauroylphosphatidic acid

The effect of negatively charged dilauroylphosphatidic acid (DLPA) vesicles on the conformation of poly(L-lysine) was investigated by circular dichroism measurements. DLPA vesicles induced a conformational change of poly(L-lysine) from the random coil to beta-structure in 5 mM Tes, pH 7.0. The fraction of induced beta-structure (F beta) was determined via a procedure of curve fitting of the observed spectra to the reference spectra. F beta increased linearly with the molar ratio, r, of DLPA to lysine residues up to r congruent to 0.7, and reached a saturation value of 1 at r greater than 1. Within the range 0.7 less than or equal to r less than or equal to 1, precipitation occurred. The effect of dilution of the negative charge on vesicle membranes was examined by mixing DLPA with dilauroylphosphatidylcholine (DLPC). Although the beta-structure of poly(L-lysine) was also induced by mixed vesicles, the saturation value of F beta decreased with decreasing DLPA content in mixed vesicles. The variation in saturation value of F beta with the composition of mixed vesicles was interpreted in terms of the change in average distance between DLPA head groups in mixed vesicles.     

Photoresponsive polymers: Azobenzene-containing poly(L-lysine)

Poly(L -lysine) was reacted with various azo-reagents, including p-phenylazobenzoic acid, p-phenylazobenzoyl chloride, and p-phenylazobenzoic N-hydroxy-succinimide ester, to give polypeptides containing 5–44 mol % azobenzene units in the side chains. The conformation of the azo-modified polypeptides was investigated in connection with their photochromic behavior caused by the trans ? cis photoisomerization of the azo groups present in the side chains. In methanol/water solvent mixture, the 20% azo-poly(L -lysine) adopts the α-helix conformation. The helix stability was found to be higher when the azo side chains are in cis than when they are in trans configuration. So irradiation at 340 nm (trans-to-cis isomerization), and alternately at 450 nm (cis-to-trans isomerization), produced reversible variations of the α-helix content. In hexafluoro-2-propanol/water/sodium dodecyl sulfate mixture, the 43% azo-poly(L -lysine) adopts a β-structure, as indicated by CD spectra. Irradiation at 340 nm caused the disruption of the β-structure and promoted the α-helix conformation. The effect was reversed upon irradiation at 450 nm. The photoinduced β ? helix change was explained on the basis of the different geometry and hydrophobic character of the trans and the cis azobenzene units.