Polymerization of amino acid derivatives by polymer catalysts. I. Polymerization by poly-2-vinylpyridine

Polymerizations of D ,L -β-phenylalanine, p-nitro-D ,L -β- phenylalanine, and o,p-dinitro-D ,L -β-phenylalanine NCA's were carried out with the use of α-picoline or poly-2-vinyl-pyridine as initiator. Polymerizations induced by the polymer catalyst were always faster than those with α-picoline in the same base concentrations. Furthermore, the polymer effect was more marked when the number of nitro groups in the NCA's increased. It was considered that the polymer catalyst interacts with the NCA's primarily by hydrogen bonding and increases the effective concentration of NCA along the chain. The increase of the NCA concentration in the vicinity of the polymer catalyst wits also achieved through charge-transfer complexes between nitrophenyl groups in the NCA's and pyridine groups in the polymer catalyst. As the polymer chain is flexible, a collision between an adsorbed NCA and a pyridine unit in the same polymer chain is favored, thus increasing the polymerization rate.     

Polymerization of amino acid derivatives by polymer catalysts. V. Polymerization of DL-β-phenylalanine N-carboxyanhydride by several poly(N-alkylamino acid) diethylamides

The polymerization of DL -β-phenylalanine N-carboxyanhydride (NCA) initiated by poly(N-benzylglycine)diethylamide (DEA) and poly(N-methyl-DL -alanine)DEA has been investigated. As previously reported, polysarcosine DEA, poly-N-ethylglycine DEA, and poly-N-n-propylglycine DEA showed marked accelerations in the polymerization of DL -β-phenylalanine NCA as compared with the polymerization initiated by low molecular weight, amines having similar base strength. However, this phenomenon (the chain effect) was not observed with the two polymer catalysts studied in the present investigation With poly-N-methyl-DL -alanine DEA, adsorption of DL -β-phenylalanine NCA onto the polymer chain takes place, though not so effectively as with other polypeptides, so the absence of chain effect was ascribed to a reduced flexibility of the polymer chain. With poly(N-benzylglycine)DEA, the reactivity of terminal base group was found to be much lower than that of other polymer catalysts. However, the absence of the chain effect would be attributed to the rigidity of polymer chain of poly-N-benzylglycine DEA due to the bulkiness of the N-benzyl group.     

Polymerization of N-carboxyanhydrides of various α-amino acids using secondary amines as initiator

In the polymerizations of alanine, γ-ethyl glutamate, and leucine N-carboxyanhydrides (NCA's) initiated by tertiary amines and some secondary amines such as N-methyl-L -alanine dialkylamide, a stereoselectivity was observed: the polymerization rates of L - and D -NCA's were identical to each other and larger than that of DL -NCA. However, this selectivity was not observed in the polymerizations of valine and isoleucine NCA's initiated by N-methyl-L -alanine dialkylamide. The stereoselective polymerizations of valine and isoleucine NCA's were induced only with tetriary amines such as tri-n-butylamine. N-Methyl-L -alanine di-alkylamide has been shown to initiate the polymerization of usual α-amino acid NCA according to the activated-NCA mechanism, but it initiated the polymerizations of valine and isoleucine NCA's according to the primary amine-type mechanism. This is because in the latter NCA's the N–H group is masked by the adjacent C^β-branched alkyl substituent against the approach of the secondary amine. Poly(DL -alanine)s produced in the stereoselective polymerization had higher viscosities and were more stereoblock-like than those produced without the stereoselectivity. These experimental results indicate that the stereoselective polymerization is possible only when the polymerization proceeds through the activated-NCA mechanism.     

Polymerization of optical isomers of phenylalanine N-carboxyanhydride by poly(N-methylalanine) diethylamide

In the polymerization of phenylalanine N-carboxyanhydride (NCA) using poly(N-methyl-L -or DL -alanine) diethylamide as initiator, the polymerization rate was L -NCA ? D -NCA > DL -NCA. This is a new type of selective polymerization and indicates the incompleteness of earlier investigations to study the asymmetrically selective polymerization without D -NCA. Neither secondary structure nor optical activity of the polymeric initiator is a reason for the selectivity. Hence the cause for the selectivity was sought in the properties of the NCA's in solution. However, the selectivity was not observed in the polymerization initiated by poly(L -phenylalanine) dimethylamide. The importance of the initiator being a secondary amine type was suggested. The experimental results are discussed on the basis of these considerations.     

Polymerization of DL-phenylalanine NCA initiated by copolymer of sarcosine and DL-phenylalanine

Polymerizations of DL -phenylalanine NCA by block copolymers of sarcosine and DL -phenylalanine, designated by (Phe)_m(Sar)n and capable of reaction at the phenylalanyl terminal, were investigated in nitrobenzene solution at 25°C. With increasing n for constant m (m = 0, 1, 2, and 5), the polymerization rate greatly increased. Previously the acceleration of the initiation reaction in the polymerization of DL -phenylalanine NCA by polysarcosine (m = 0) was reported. The present results showing the acceleration by the copolymers of sarcosine and DL -phenylalanine indicate the presence of the polymer effect in the propagation reaction as well. However, the polymer effect was most marked with polysarcosine (m = 0), and decreased with increasing m. The same polymerizations by sequential copolymers composed of ten sarcosine units and two DL -phenylalanine units were also investigated. Again with these copolymer catalysts the polymerization rate was larger than that by monomeric amines. But the polymer effect decreased sharply when the phenylalanine units take positions near the terminal amine group of the copolymer catalyst. These two deteriorating effects of the phenylalanine unit have been interpreted in terms of the decrease of the flexibility of polymer chain, caused possibly by an intramolecular hydrogen bond of the phenylalanine unit.     

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 degree of polymerization and steric configuration of poly(2-vinylpyridine) as catalyst in the polymerization of phenylalanine NCA

Despite its being weaker base poly(2-vinylpyridine) polymerized DL -β-phenylalanine NCA at a much faster rate than pyridine and α-picoline. Poly(2-vinylpyridine) adsorbs NCA by hydrogen bonding with the cooperation of a few pyridine groups. This results in a high local concentration of NCA. The syndiotactic configuration of pyridine group seemed to be least suitable for the cooperative hydrogen bonding. Adsorbed NCA is activated to form an “activated” NCA which in turn reacts with an NCA adsorbed on the same polymer chain. Since the polymer chain is flexible, this intramolecular reaction takes place frequently, resulting in the acceleration of polymerization. The intramolecular reaction along the polymer chain is dependent on the degree of polymerization of polymer catalyst. A suitable model was proposed for the intramolecular reaction to explain the effect of degree of polymerization.     

Enantiomer selection in the reaction of N-methyl-α-amino acid N-carboxyanhydride and 3-methyl-5-substituted hydantoin: A model reaction for the stereoselective polymerization of α-amino acid N-carboxyanhydride

The addition reaction to N-methyl-(S)-alanine or N-methyl-(S)-phenylalanine N-car-boxyanhydride (NCA) of 3-methyl-5-substituted hydantoin (HDT) catalyzed by a tertiary amine was investigated as a model reaction for the propagation reaction of NCA according to the activated-NCA mechanism. Several activated HDTs having the (S)-configuration of the asymmetric carbon atom were found to react more rapidly than their activated enantiomers. This experimental result indicates that the enantiomer selection by terminal-unit control takes place in the propagation reaction according to the activated-NCA mechanism in which an activated NCA is added to a terminal acylated NCA ring of the growing chain. The enantiomer excess of the HDT recovered from the reaction mixture of N-methyl-(S)-phenylalanine NCA and racemic HDTs activated by a tertiary amine was determined. The extent of the enantiomer selection in the polymerization was found to be 3–10 times as large as that in the model reaction. From these results, it was concluded that the chirality of the penultimate unit, as well as that of the terminal NCA ring, plays an important role in determining the enantiomer selection in the NCA polymerization.     

Acid–base behavior of poly (vinylpyrrolidone–vinylimidazole) copolymers

Copolymers of vinylimidazole and vinylpyrrolidone containing 0.7–24% of the former residue have been prepared. Titration behavior was examined over a range of temperature and at several ionic strengths. Intrinsic pK's, corrected for electrostatic effects, arc independent of mole fraction of imidazole residue in the copolymer. Nevertheless they are about 1.15 pK units lower than in the corresponding model small molecule, N-ethylimidazole. Enthalpies and entropies of ionization in the copolymer are changed by ionic strength. It is apparent that the charged state of an N-ethylimidazole residue placed in a macromolecular matrix is destabilized relative to the uncharged state because of changes in the local polymer or solvent environment.     

Stepwise synthesis of oligopeptides with N-carboxy α-amino acid anhydrides. II. Oligopeptides with some polar side chains

The reaction of NCA's with some amino acids having a nucleophilic functional group on the side chain was studied in a heterogeneous reaction medium (acetonitrile-water). Glutamic acid and aspartic acid, having a free carboxyl group on the side chain, were successfully used to synthesize oligopeptides without interactions of the γ- and β-carboxyl group with NCA's. Two products were obtained by the reaction of NCA with L -lysine, which contains a free amino group on the side chain. ε-Protected lysine was used to prepare α-peptides as a nucleophile in the reaction. No racemization was observed in the synthesis of peptides by the NCA method in the heterogeneous solvent system. Oligopeptides with some polar side chains were synthesized by the NCA method.     

Stepwise synthesis of oligopeptides with N-carboxy alpha-amino acid anhydrides

Oligopeptides were synthesized in high yields by the controlled coupling reaction of N-carboxy α-amino acid anhydrides (NCA's) with amino acid and peptide sodium salts in the heterogeneous reaction medium of acetonitrile–water which contained sodium carbonate. In this solvent, it could be considered that the reaction could occur at the interface of acetonitrile and aqueous layers, and that NCA's could be protected by the organic layer from side reactions such as hydrolysis and polymerization. The careful control of reaction conditions such as pH of the solution was not necessary when the heterogeneous mixed solvent was used. Sodium carbonate which had not been used for a reaction of this kind could be satisfactorily used for stabilizing the carbamate intermediates in the aqueous layer of the heterogeneous reaction medium.     

Kinetics of γ-benzyl-L-glutamate NCA's polymerizations and molecular-weight distributions on corresponding polymers

The kinetics of γ-benzyl-L -glutamate NCA's polymerizations in dioxane as solvent are discussed. The partial orders respective to [A], the NCA concentration and [I₀], the initial initiator concentration are given; the rate constants are deduced and a mechanism is proposed to justify a rate of polymerization V_p = k[A][I₀]². The dependence of the rate constants on the conformation of the growing chains is demonstrated; the acceleration is attributed to the ordered structures favorable to hydrogen bonding. The kinetics of aging have also been examined and discussed; it is shown that they cannot modify the kinetics of polymerization. The DP _n were obtained on the same samples before and after debenzylation; it is proved that at any concentration, DP _n ? [A₀]/[I₀]. The molecular-weight distributions were obtained by chromatography and a polydispersity lower than 1.3 was deduced for each sample. The trimodal distribution, appearing as soon as [A₀]/[I₀] is larger than 3, is attributed to the existence of the three structures σ, β, and α. The weight fraction of each of the structures was correlated to the kinetics of polymerization.     

Enantiomer selection in the addition reaction of optically active 3-methyl-5-substituted hydantoins to N-[(S)-α-methylbenzyl]glycine N-Carboxyanhydride: Model Reaction for the Stereoselective Polymerization of α-amino acid N-carboxyanhydride

In order to investigate the contribution from the chiral penultimate unit to the enantiomer selection in the activated N-carboxyanhydride (NCA) polymerizations, the addition reaction to N-[(S)-methylbenzyl]glycine NCA of various α-amino acid hydantoins activated by the tertiary amines was investigated in different solvents. The reactions of activated Ala, Val, and Phe hydantoins were stereoselective and suggested the participation of the penultimate unit in the enantiomer selection of the activated NCA type of polymerization. The degree of enantiomer selection was not well correlated with the structure of hydantoins. Taking into account the dipole repulsion and the orbital overlapping between the reaction species, the transition-state model was proposed, which gave a good explanation of the selectivity for (R)-hydantoin in PhNO₂ and CH₃CN and the selectivity for (S)-hydantoin in AcNMe₂ and HCONMe₂. In these two types of solvents the orientation of the methylbenzyl group with respect to the NCA ring is so different that the direction of the approach of the activated hydantoin to the NCA is different. This difference leads to the inversion of enantiomer selection in amide solvents and in others. Cationic species derived from tertiary amines and the chiral amide compound were found to affect the enantiomer selection in the model reaction. The implications of these findings with regard to enantiomer selection in the activated NCA type of polymerization are discussed.     

On the Role of Disulfide Bonds in Polymerization of Soybean 7S Globulin during Storage

Modification of soybean 7S globulin with N-ethylmaleimide (NEM) was effective for preventing humidity-induced insolubilization during storage. The sulfhydryl-disulfide interchange reaction and/or oxidation of the sulfhydryl groups to form disulfide bonds closely related to the polymerization of the 7S globulin. A dimer, consisting of α′ and α subunits linked with disulfide bonds, was observed in the polymerized 7S globulin fractions, but this dimer was not readily apparent in the NEM-7S globulin. The formation of the dimer certainly initiates the insolubilization of the 7S globulin during storage. Although the β subunit had sulfhydryl groups, it did not take a part in the formation of the dimer.     

Reduction of ferriprotoporphyrin IX to the ferroderivative by copoly(4-vinylpyridine-N-(p-vinylbenzyl)-3-carbamoyl-1,4-dihydropyridine) in dimethyl sulfoxide

The copolymer which has both ligand sites (4-vinylpyridine) and redox sites (N-(p-vinylbenzyl)-3-carbamoyl-1,4-dihydropyridine) was synthesized by the dithionite reduction of the copoly(4-vinylpyridine-N-(p-vinylbenzyl)-3-carbamoylpyridinium chloride) and the reduction of a central ferric-iron of ferriprotoporphyrin IX by the above-described copolymer was studied spectrophotometrically in dimethyl sulfoxide. The rate of the reduction by the copolymer was much faster than by N-benzyl-3-carbamoyl-1,4-dihydropyridine. This acceleration by the copolymer could be explained by the intramolecular reduction of ferriprotoporphyrin IX which was coordinated by the pyridine residue of the copolymer.     

Effects of temperature on the polymerization of γ-ethyl DL-glutamate N-carboxy anhydride in DMF initiated by tri-n-propylamine

Polymerization of γ-ethyl DL -glutamate N-carboxy anhydride (NCA) in DMF has been carried out at various temperatures and with the use of tri-n-propylamine as the initiator. It was found that on decreasing the polymerization temperature the reaction rate is lowered but the molecular weight and the helix content of the final polymer are enhanced. An overall activation energy of ～4 kcal/mole has been found for the polymerization process. Preliminary experiments carried out on the polymerization of γ-benzyl D -glutamate NCA in DMF and with tri-n-propylamine as the initiator showed a strong depressing effect of the CO₂ evolved during the polymerization, both on the reaction rate and on the molecular weight of the polymer. All data are interpreted in terms of the Bamford-Swarc mechanism.     

Stereoselectivity in the nucleophilic addition-type polymerization of α-amino acid N-caboxyanhydride initiated by diastereomeric dipeptide amines

In order to investigate the effect of the chiral penultimate unit on the stereoselection of α-amino acid N-carboxyanhydride (NCA) by the terminal unit of a growing chain in the nucleophilic addition-type polymerization, the diastereomers of dipeptide amines, H-(R)-Phe-(S)-Phe-Mo and H-(S)-Phe-(S)-Phe-Mo, in which Mo represents a morpholine residue, were synthesized, and the stereoselectivity in their nucleophilic addition reactions to NCA was investigated and compared with that of a monopeptide amine H-(S)-Phe-OEt. In the reaction with Phe NCA in nitrobenzene, either of the dipeptide amines reacted preferentially with an enantiomer of NCAs having a configuration opposite to the N-terminal unit of the dipeptide amine. The preference of enantiomeric NCA and the extent of stereoselectivity were nearly the same as those found with H-(S)-PheOEt. The opposite-enantiomer selectivity of the dipeptide amines was also observed in the reaction with N-MePhe NCA, and the extent of stereoselectivity was found to increase very much in the reaction of H-(R)-PHe-(S)-Phe-Mo compared with that of H-(S)-Phe-OEt. Therefore, the enhancement of the stereoselectivity of the N-terminal unit by the penultimate unit was shown experimentally. On the other hand, the stereoselectivity of H-(S)-Phe-(S)-Phe-Mo was not very different from that of H-(S)-Phe-OEt. These results were obtained either in nitrobenze or in m-dimethoxybenzene. H-(S)-Phe-(S)-Phe-OEt tends to aggregate by an intermolecular hydrogen bond in aqueous and tetrahydrofuran solutions. Its pK_a value and nucleophilicity towards NCA were much lower than H-(R)-Phe-(S)-Phe-Mo, which was free from the aggregation under similar conditions. These experimental results suggest that the major product in the polymerization of (RS)-Phe NCA by amine should be an alternating copolymer. However, this prediction was not verified experimentally, and the important contributions from the aggregation and the molecular weight distribution of growing chains were suggested.     

Association studies of N-acetyl-amino acid N,N-dimethylamides in carbon tetrachloride

The self-association of N-acetylglycine N,N-dimethylamide, N-acetyl-L -valine N,N-dimethylamide, and N-acetyl-L -phenylalanine N,N-dimethylamide in carbon tetrachloride was investigated by using ir and ¹H-nmr methods. It was concluded from ir measurements that the associated species is the dimer formed as a result of the simultaneous formation of two intermolecular hydrogen bonds. This is supported by the results of ¹H-nmr measurements. Thermodynamic quantities for the association were determined from the temperature and concentration dependence of the NH proton chemical shifts of the sample solutions. Compared with the Gly derivative, L -Val and L -Phe derivatives have larger values of ?ΔH for association, which shows good correlation with Δv_NH values, the difference between the maxima of the monomer and dimer bands, obtained from ir spectra. This is due to the less stable monomer conformation and to the stronger intermolecular hydrogen bonding of the dimers in L -Val and L -Phe derivatives. The line shapes of both methyl proton resonances of L -Val residue and methylene proton resonances of L -Phe residue were found to vary with concentration and temperature of the sample solutions. These data indicate that the rotation about the C^α—C^β bond is restricted by the steric hindrance present in the associated dimers. All these experimental results can be related to the fact that L -Val and L -Phe derivatives have a warped framework because of the bulky side chains, whereas the Gly derivative has a planar framework.     

New polymer syntheses. IV. Polypeptides of lysine and ornithine with pending pyrimidine bases

Starting with β-methoxy methacryloylisocyanate, β-methoxy methacrylisothiocyanate, and β-isocyanatopropionyl chloride, on the one hand, and N^α-Z-lysine or N^α-Z-ornithine, on the other hand, N^α-Z-amino acids with pyrimidine bases in the side chain were synthesized. These Z-protected nucleoamino acids were converted to the corresponding N-carboxyanhydrides (NCAs) via the silylester method. In the case of 2-thiothymine derivatives, the reaction intermediate of the NCA synthesis caused benzylation of the thioxo- group, so that a new class of 2-mercaptopyrimidine derivatives was isolated unexpectedly. The poly(nucleoamino acids) obtained by polymerization of the nucleoamino acid NCAs were characterized by elemental analyses, optical rotations ¹H-nmr and ¹³C-nmr spectra. Vapor pressure osmometry revealed that the DP s were in the range of 20–30. Their spectra suggest a helical secondary structure. While all homopolypeptides are insoluble in water, copolypeptides containing L -lysine N^ε-hydrobromide possess good solubility in water.     

Adsorption of molecular oxygen by polymer covalently bonded co(II) porhyrin complex in toluene

Reaction betwenn molecular oxygen and polystyrene covalently bonded Co(II) protoporphyrin IX complex, which was prepaired by the incorporation of a cobaltous ion into the metal-free porphyrin polymer, was studied in the presence of N-ethylimidazole by measuring visible absorption and electron spin resonance spectra. It was found that the complex forms a monomeric oxygen adduct reversibly at low temperature dependent on oxygen pressure. In the presence of molecular oxygen, a new electron spin resonance signal due to the oxygen complex at g_iso=2.02 shows no superhyperfine splitting structure in fluid toluene solution even at ?80 °C, but it was observed in frozen toulene glass solution at ?120°C, The oxygen adducts of the complexes between C0(II) protoporphyrin IX dimethyl ester and N-ethylimidazole and copoly(styrene-N-vinylimidazole) showed eight resolved superhyperfine splitting at ?40 and ?60°C, respectively. The polymer covalently bonded Co(II) complex with N-ethylimidazole was oxidized at room temperature under oxygen atmosphere. It was suggested that a Co(II) porphyrin–oxygen adduct with an axial ligand may be oxidised monomolecularly at high temperature.