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 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.     

Solvent effect in the stereoselective polymerization of α-amino acid N-carboxyanhydride and some considerations on the mechanism of stereoregulation

In the Polymerization of phenylalanine N-carboxyanhydride (NCA) in No₂Oh initiated by MeNHBzl, L -,D -, and DL -NCA As were polymerized at the same rate, and no stereoselectivity was observed. When the same experiment was carried out in HCONEt₂, however, L - and D -NCA were both polymerized at a rate which was about twice as large as that of DL -NCA. In this case, the polymerization is stereoselective, ascribable to a preferable reaction between the optical enantiomorphs of the terminal residue of the growing chain and the NCA of the same chirality. On the other hand, the polymerization initiated by SarNMe₂ and MeNH(CH₂)₂CONMe₂ were stereoselective in NO₂Ph and HCONEt₂, but they were not stereoselective in m-(MeO)₂Ph. These findings indicate that the polymerizations initiated by a strong base in highly dipolar solvents are stereoselective. Apparently, the reaction between a chiral, cyclic terminal of growing chain and a chiral, cyclic activated NCA in the activated-NCA mechanism is highly stereoselective. In addition, from a kinetic investigation on on the copolymerization between L - and D -NCAs, the penultimate chiral centers were also suggested to contribute to the stereoselection. Stereoselection by the α-helical conformation of the growing chain and by a chiral, linear terminal amine have been considered so far, and the contribution from the present type of stereoselection must have been overlooked.     

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.     

The chain effect. Part III. Induction of secondary structure in copolymerizations

Studies of the properties of copolymers of N-carboxy sarcosine anhydride with other N-carboxy α-amino acid anhydrides have shown that the secondary structure may be a function of the type of initiator used. In particular, when polysarcosine is the initiator, and the “chain effect” becomes possible, blocklike character appears in the copolymer. This is the result of selective and rapid polymerization of N-unsubstituted N-carboxy α-amino acid anhydrides by the chain-effect mechanism. In suitable circumstances, therefore, the latter may be used to induce order into copolymerizations of this type.     

Synthesis of poly-O-tert-butyl-L-serine and poly-L-serine

The synthesis of polymers containing O-tert-butyl-L -serine, O-tert-butyl-DL -serine, L -serine, and DL -serine is reported. The N-benzyloxycarbonyl-(L or DL )-serine benzyl ester was used to synthesize the corresponding N-benzyloxycarbonyl-O-tert-butyl-(L or DL )-serine benzyl ester. Catalytic hydrogenation of this material gave O-tert-butyl-(L or DL )-serine. The reaction of O-tert-butyl-(L or DL )-serine with phosgene produced the corresponding N-carboxyanhydrides. The kinetics of polymerization of N-carboxyanhydrides were investigated to facilitate, the preparation of block copolymers. The O-tert-butyl blocking group was removed from polymers by treatment with HCl and HBr in benzene. Both high molecular weight (water-insoluble) and low molecular weight (water-soluble) homopolymers have been prepared, as well as water-soluble block copolymers of the type (DL -serine)_x (L -serine)_y, (DL -serine)_z.     

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.     

Block copolymers of amino acids. I. Synthesis and structure of copolymers of L-alanine or L-phenylalanine with D,L-lysine-d7 or D,L-lysine

Water-soluble block copolymers of the type (A)_m-(B)_n-(A)_p, where (A)_m,p was either poly(D ,L -lysine-α,β,β,γ,γ,δ,δ-d₇) or poly(D ,L -lysine) and (B)_n was either poly(L -alanine) or poly(L -phenylalanine), were synthesized for conformational studies by proton magnetic resonance spectroscopy. Analytical determination of the amount of the initiator fragment (n-hexylamine) at the C-terminus of the copolymers was used to obtain the number-average degrees of polymerization, DP _n, and thereby, together with the amino acid composition, to establish the covalent structures of the polymers. The values of DP _n were found to be much lower than those deduced from sedimentation equilibrium or form viscosity measurements. These deviations, which also are thought to have arisen in similar studies reported in the literature, are attributable to intermolecular aggregation; the relation of such aggregation to covalent structure (and its effect on the polymerization reaction) is discussed in terms of the conditions and mechanism of synthesis of block copolymers of amino acids.     

Carrier design: Conformational studies of amino acid (X) and oligopeptide (X-DL-Alam) substituted poly(L-lysine)

The present study was undertaken to examine the influence of the reversal of the sidechain sequential order on the conformation of branched polypeptides. At the same time, the influence of the optically active amino acid joined directly to the poly (L -Lys) backbone and the DL -Ala oligomer grafted as chain-terminating fragment were separately analyzed. Therefore two sets of polypeptides were synthesized corresponding to the general formula poly [Lys-(X_i,)] (XK) and poly[Lys-(DL -Ala_m-X_i)] (AXK) when X = Ala, D -Ala, Leu, D -Leu, Phe, D -Phe, Ile, Pro, Glu.,D -Glu, or His. For coupling amino acid X to polylysine, three types of active ester methods were compared: the use of pentafluorophenyl or pentachlorophenyl ester, and the effect of the addition of an equimolar amount of 1-hydroxybenzotriazole. After cleavage of protecting groups, AXK polypeptides were synthesized by grafting short oligo (DL -Ala) chains to XK by using N-carboxy-DL -Ala anhydride. The CD measurements performed in water solutions of various pH values and ionic strengths were used for classification of the polypeptide conformations as either ordered (helical) or unordered. Different from what was observed with the unsubstituted poly (L -Lys), poly[Lys-(X_i)] type polypeptides can adopt ordered structure even under nearly physiological conditions (pH 7.3, 0.2M NaCl). These data suggest that the introduction of amino acid residue with either (ar) alkyl side chain (Ala, Leu, Phe) or negatively charged side chain (Glu) promotes markedly the formation of ordered structure. Comparison of chiroptical properties of poly [Lys- (DL -Ala_m-X_i)] and of poly [Lys- (X_i)] reveals that side-chain interactions play an important role in the stabilization of ordered solution conformation of AXK type branched polypeptides. The results give rather conclusive evidence that not only hydrophobic interactions, but also ionic attraction, can be involved in the formation and stabilization of helical conformation of branched polypeptides. © 1993 John Wiley & Sons, Inc.     

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.     

Asymmetric selection in the copolymerization of N-carboxyl-L- and D-alanine anhydride

The copolymerization of N-carboxy-L - and D -alanine anhydride with methanol as initiator was carried out. The enantiomer excess in the starting monomer mixture is preferentially incorporated into polymer chains, demonstrating asymmetric selection during the D - and L -copolymerization. The mechanism of asymmetric-selective polymerization of α-amino acid NCA is discussed in terms of the stereoregulation by molecular asymmetry of the growing polymer chain.     

Coformational aspects of polypeptide structure XL. The synthesis of poly((S)-thiazolidine-4-carboxylic acid)

The synthesis of poly[(S)-thiazolidine-4-carboxylic acid] is described. The polymer is obtained by the polymerization of the N-carboxyanhydride of (S)-thiazolidine-4-carboxylic acid in pyridine or nitrobenzene using triethylamine as an initiator. The amino acid is prepared by the condensation of cysteine and formaldehyde. N-Acetyl-(S)-thiazolidine-4-carboxylic acid methyl ester is also prepared as a model compound by standard acetylation and esterification reactions.     

On the amino-acid-sequence distribution in benzylglutamate-methionine copolymers prepared from N-carboxyanhydrides

The amino-acid-sequence distribution in poly(γ-benzyl-L -glutamate, L -methionine) prepared by polymerization of the respective N-carboxyanhydrides has been investigated. This copolymer was converted first to poly(L -glutamic acid, L -methionine), which was subsequently cleaved by treatment with cyanogen bromide. The resulting material was fractionated into oligomers of (glutamic acid)_n-homoserine whose relative molar amounts were determined quantitatively. The results have been compared with those for a random incorporation of the methionine in a γ-benzylglutamate host polymer. Fairly close agreement has been found.     

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.     

Syntheses of poly[γ-(l)-menthyl L- and D-glutamates] and their secondary structures

γ-(l)-Menthyl L - and D -glutamates were prepared by a fusion reaction of N-phthalyl-L - and D -glutamic anhydrides with l-menthol, followed by hydrazinolysis. The monomers were polymerized to poly[γ-(l)-menthyl L - and D -glutamates] by the N-carboxyanhydride method. These polymers were soluble in many organic solvents, such as ethyl ether, chloroform, tetrahydrofuran, and n-hexane. From the results obtained by a study of the infrared absorption spectra, the x-ray photographs, the optical rotatory dispersions and the circular dichroisms, poly[γ-(l)-menthyl L -glutamate] was found to be a right-handed α-helix in the solid state and in solution. Similarly, poly[γ-(l)-menthyl D -glutamate] was a left-handed α-helix. The helix-coil transition of these polymers was observed in the vicinity of 40% dichloroacetic acid in a chloroform–dichloroacetic acid mixture.     

Syntheses of poly[beta-(l)-menthyl D- and L-aspartates] and their secondary structures

β-(l)-Menthyl D - and L -aspartates were prepared by a fusion reaction of N-phthalyl D - and L -aspartic anhydrides with l-menthol, followed by hydrazinolysis. The monomers were then polymerized to poly[β-(l)-menthyl D - and L -aspartates] by the N-carboxyanhydride method. These polymers were soluble in many organic solvents, such as diethyl ether, tetrahydrofuran, chloroform, n-bexane, and dioxane. From the results obtained by a study of the optical rotatory dispersions and circular dichroisms, poly [β-(l)-menthyl D -aspartate] was found to be a β form structure in solution. On the other hand, poly[β-(l)-menthyl L -aspartate] was a random-coil structure. These results suggest that the asymmetry of the l-menthyl chromophore in the side chain interacts with the polypeptide main chain and causes an extraordinary optical rotation.     

Circular dichroism studies on the polymerization of N-carboxy alpha-amino acid anhydride

The D and L copolymerizations of N-carboxy γ-benzyl glutamate anhydride (NCA) were carried out in a homogeneous solution with various D /L ratios, initiated by either n-butylamine or sodium methoxide, and were followed directly by circular dichroism (CD) to observe the behavior of the secondary structure of growing polymer molecules. In the n-butylamine system, the difference of the helical content between the righthanded and the lefthanded (Δα-helix) gradually increased as the polymerization proceeded, while in the sodium methoxide system, the Δα-helix had a tendency to decrease during the later stages of the polymerization. These results suggest a difference of the power of stereo-selection of monomer antipodes by the growing chain end between these systems, the stereoselectivity by the growing chain end in the sodium methoxide system being higher than that in the n-butylamine system.     

Synthesis and gelation of copolypept(o)ides with random and block structure

Copolypept(o)ides of polysarcosine (PSar) and poly(N‐isopropyl‐L‐glutamine) (PIGA) with random and block sequence structures were synthesized by ring‐opening polymerization (ROP) of sarcosine N‐carboxyanhydrides (Sar‐NCA) and γ‐benzyl‐l ‐glutamate N‐carboxyanhydrides (BLG‐NCA) and post modification. With different distribution of Sar along the main chain, H‐bonding pattern and secondary structure of polypeptides were turned, as well as aggregation and gelation behavior. Both copolypept(o)ides formed hydrogels above their critical gelation concentrations (CGCs) without thermo‐sensitivity, which was normally reserved for PEG copolypeptides (eg, PEG‐b‐PIGA). In particular, a different mechanism from previously reported micellar percolation or fibrillar entanglement was suggested for gelation of the random copolypept(o)ide. Therefore, hydrogels from copolymers of PSar and PIGA represented a new approach to construct easy‐handling, biocompatible, biodegradable and thermo‐stable gels that could potentially be applied in biomedical fields.     

15N-NMR spectroscopy. 34. Stereospecificity of the polymerization of D,L-leucine N-carboxyanhydride and γ-OMe-D,L-glutamic acid N-carboxyanhydride

D ,L -Leucine-N-carboxyanhydride (D ,L -Leu-NCA) and γ-methyl-D ,L -glutamic acid N-carboxyanhydride (γ-OMe-D ,L -Glu-NCA) were synthesized with ca. 2.5% ¹⁵N enrichment. Their polymerizations were conducted under a variety of conditions using benzylamine, triethylamine potassium tert-butanolate, and pyridine as initiators. The 40.55-MHz ¹⁵N-nmr spectra of the resulting stereocopolypeptides measured in trifluoroacetic acid display at least four signals, representing the isotatic, syndiotactic, and two heterotactic triads. From the signal intensities it was concluded that these NCAs behave nearly identically. With benzylamine initiation the formation of isotactic blocks is slightly favored, and they are still more predominant when strong bases are used as initiators. Initiation by pyridine favors the formation of syndiotactic sequences. However, in all cases the average lengths of the stereoblocks never exceeded 4 monomer units. The low stereospecificity of most polymerizations of D ,L -NCAs is confirmed by the high degree of solubility of the resulting poly(D ,L -amino acids) in aprotic solvents. Penultimate effects are weak or absent, so that most polymerizations follow Bernoullian type statistics. Deviations from these statistics were found for polymerizations in pyridine.     

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.