Polymerization of optical isomers of phenylalanine N-carboxyanhydride by various secondary amines

In the polymerization of phenylalanine NCA initiated by some secondary amines, the two enatimorphs of phenylalanine NCA were polymerized with the same rate, which was almost twice as high, as that found for the racemic mixture. This stereoselectivity was observed only when the polymerization was initiated by secondary amines which are sterically crowded and reluctant to undergo a nucleophilic addition to NCA. Poly(DL -phenylalanine) produced in the stereoselective polymerization had a higher molecular weight than that produced in nonstereoselective polymerization. These findings point to the possibility that the stereoselectivity arises only in those polymerizations which are propagated by the activated monomers and not in the propagation involving the terminal amine of the growing polymer. A possible mechanism for the stereoselective polymerization is proposed and examined.     

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.     

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.     

Effect of hairpin DNA on poly(phenylalanine) synthesis.

In a poly(U) dependent poly(Phe) synthesis, an unaminoacylated tRNA(phe) binds to a ribosome and inhibits poly(Phe) synthesis in excess tRNA(Phe). A small DNA fragment having a hairpin structure was added to this system and was found to prevent an unaminoacylated tRNA(phe) from binding to a ribosome and enhance the efficiency of poly(Phe) synthesis in the presence of excess tRNA(phe).     

Solvent effects in N-carboxyanhydride (NCA) polymerization initiated by strong base type initiators

The γ-benzyl-L -glutamate N-carboxyanhydride (NCA) polymerization initialed by diisopropylamine was studied in dimethylformamide (DMF)-dioxane mixtures of different compositions. It was found that the shape of the conversion versus time plots and the molecular weights of the polymers depend on the solvent composition. Auto-catalysis is present only when dioxane predominates in the solvent mixtures. Moreover, the molecular weight of the final polymer depends strongly on the precipitation conditions when the polymerization is carried out in DMF.     

Photoresponsive poly(S-(o-nitrobenzyl)-L-cysteine)-b-PEO from a L-cysteine N-carboxyanhydride monomer: synthesis, self-assembly, and phototriggered drug release

A photoresponsive S-(o-nitrobenzyl)-l-cysteine N-carboxyanhydride (NBC-NCA) monomer was for the first time designed, and the related poly(S-(o-nitrobenzyl)-l-cysteine)-b-poly(ethylene glycol) (PNBC-b-PEO) block copolymers were synthesized from the ring-opening polymerization (ROP) of NBC-NCA in DMF solution at 25 °C. Their molecular structures, physical properties, photoresponsive self-assembly, and drug release of PNBC-b-PEO were thoroughly investigated. The β-sheet conformational PNBC block within copolymers presented a thermotropic liquid crystal phase behavior, and the crystallinity of PEO block was progressively suppressed over the PNBC composition. The characteristic absorption peaks of these copolymers at about 310 and 350 nm increased over UV irradiation time and then leveled off, indicating that the o-nitrobenzyl groups were gradually photocleaved from copolymers until the completion of photocleavage. The PNBC-b-PEO copolymers self-assembled into spherical nanoparticles in aqueous solution, presenting a photoresponsive self-assembly behavior, together with a size reduction of nanoparticles after irradiation. The anticancer drug doxorubicin can be released in a controlled manner by changing the light irradiation time, which was induced by gradually photocleaving the PNBC core of nanoparticles. This work provides a facile strategy not only for the synthesis of photoresponsive polypeptide-based block copolymers but also for the fabrication of photoresponsive nanomedicine potential for anticancer therapy.     

Geometrical and optical isomers of diethylenetriaminemonoacetato(ethylene-diamine)cobalt(III) ion and their isomerism

Two isomers of the complex ion in the title were obtained and each isomer was resolved chromatographically into its antipodes. The two isomers with their isomer proportion of 27.9 and 72.1% in the equilibrium mixture were assigned to α and β(mer-N) isomers, respectively, of three possible geometrical isomers, from the measurements of their absorption, circular dichroism, and NMR spectra.Preference of the β(mer-N) to the isomer and very poor yield of an expected β(fac-N) isomer were confirmed by conformational analyses carried out for each structure of the isomers of Λ configuration, with possible configurations around nitrogen atoms and conformations of chelate rings. They gave minimized total strain energies of 43.13, 44.24, and 52.63 kJ/mol for the Λ-R,R(en:λ) structure of a β(mer-N) isomer, the Λ-S,R(δ,δ) structure of an α isomer, and a Λ-R,S(λ,λ) structure of a β(fac-N) isomer, respectively.From the results, configurations and conformations of the enantiomers of the resolved β(mer-N) and its isomers were deduced. An unfound isomer, β(fac-N) isomer, is thought to be very unstable; it would exist as less than 2% of the amount of β(mer- N) isomer, even if it were present in the reaction mixture.     

Polymerization of gamma-benzyl-L-glutamate N-carboxyanhydride: effects of conditions of polymer precipitation on the molecular weight distribution

Poly-γ-berizyl-L -glutamate prepared by polymerization of γ-benzyl-L -glutamate NCA in dimethylformamide (DMF) with the use of diisopropylamine as the initiator was precipitated from the polymerization mixture under different conditions. A portion of the almost completely polymerized solution was treated with an excess of isopropylamine and then precipitated into diethyl ether (sample A). The remaining portion of the polymerization mixture was concentrated in a rotating evaporator, stored at room temperature for a few days, and then diluted with DMF and precipitated into diethyl ether (sample B). The molecular weight distributions of the two polymer samples were determined by the chromatographic procedure of Baker and Williams. The molecular weight of sample B is roughly three times that of sample A. However both samples have the “most probable” distribution of molecular weight. The results are interpreted according to Bamford's polymerization mechanism.     

Complete disproportionation of duplex poly(dT)*poly(dA) into triplex poly(dT)*poly(dA)*poly(dT) and poly(dA) by coralyne

Coralyne is a small crescent-shaped molecule known to intercalate duplex and triplex DNA. We report that coralyne can cause the complete and irreversible disproportionation of duplex poly(dT)·poly(dA). That is, coralyne causes the strands of duplex poly(dT)·poly(dA) to repartition into equal molar equivalents of triplex poly(dT)·poly(dA)·poly(dT) and poly(dA). Poly(dT)·poly(dA) will remain as a duplex for months after the addition of coralyne, if the sample is maintained at 4°C. However, disproportionation readily occurs upon heating above 35°C and is not reversed by subsequent cooling. A titration of poly(dT)·poly(dA) with coralyne reveals that disproportionation is favored by as little as one molar equivalent of coralyne per eight base pairs of initial duplex. We have also found that poly(dA) forms a self-structure in the presence of coralyne with a melting temperature of 47°C, for the conditions of our study. This poly(dA) self-structure binds coralyne with an affinity that is comparable with that of triplex poly(dT)·poly(dA)·poly(dT). A Job plot analysis reveals that the maximum level of poly(dA) self-structure intercalation is 0.25 coralyne molecules per adenine base. This conforms to the nearest neighbor exclusion principle for a poly(dA) duplex structure with A·A base pairs. We propose that duplex disproportionation by coralyne is promoted by both the triplex and the poly(dA) self-structure having binding constants for coralyne that are greater than that of duplex poly(dT)·poly(dA).     

Initiation of poly(ADP-ribosyl) histone synthesis by poly(ADP-ribose) synthetase

Initiation of poly(ADP-ribosyl) histone synthesis was achieved in vitro using an apparently homogeneous preparation of poly(ADP-ribose) synthetase. When poly(ADP-ribose) was synthesized in the presence of DNA and increase amounts of histone H1, increasing portions (up to about 55%) of the product were found associated with the histone, judging from solubility in 5% HClO4 and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Most of the polymers were directly attached to the histone protein and not produced by elongation from pre-existing ADP-ribose; the cohesive end of poly(ADP-ribose), isolated as ribose 5-phosphate with snake venom phosphodiesterase digestion, was labeled almost quantitatively with [ribose (NMN)-14C]NAD. The poly(ADP-ribose) . histone linkage was labile in mild alkali and neutral NH2OH, suggesting that the same bond, probably ester, was formed in this system as in crude chromatin or isolated nuclei. Elongation of a histone-bound monomer into a polymer by this enzyme was previously demonstrated (Ueda, K., Kawaichi, M., Okayama, H., and Hayaishi, O. (1979) J. Biol. Chem. 254, 679-687), but initiation of ADP-ribose chains on histone has never been shown with a purified enzyme. This appeared to be due to the low concentrations of histone so far used. These findings indicated that a single enzyme catalyzes two different types of reaction, i.e. an attachment of ADP-ribose to histone and its elongation into a polymer.     

Genetic toxicology of lysergic acid diethylamide (LSD-25)

The acute and the chronic psychotomimetic potentials of the hallucinogen lysergic acid diethylamide (LSD-25) have been recognized for almost 40 years. That additional types of the biological effects should have come under scrutiny was directly attributable to widespread use and abuse of this drug on a worldwide basis. Although “genetic toxicology” encompasses a broad spectrum of disciplines, including many areas of highly specialized research, perhaps the most germane, and those on which this review has concentrated, are Clastogenicity, Mutagenicity, Teratogenicity and Oncogenicity. Based on our current understanding and interpretation of the available data, the genetic toxicology of LSD provides an excellent example of Newton's “third law of motion”, e.g., to every force there is an equal and opposite reaction force.From the published material it is impossible to draw clear cut conclusions regarding any of the above “problem areas” in spite of the considerable scientific effort invested. Most of the in vitro studies performed on the clastogenicity of LSD indicate either suppression of mitosis or enhanced chromosome damage. However, extrapolation of such results to the in vivo situation is very difficult. With regard to in vivo human use of the drug, no concensus is attainable as to chromosome breakage and the inconsistencies within and between studies remain inexplicable. However, several of the “controlled” investigations assessing the in vivo effect of chemically pure LSD suggest a transient increase in lymphocyte chromosome breakage. On the other hand, the results of cytogenetic studies on experimental animals are contradictory. Although human studies are nonexistent, in those experimental organisms tested, using accepted techniques, LSD proved to be, at best, a weak mutagen, if mutagenic at all. Teratogenicity studies in animals are confusing due to the multitude of organisms and plethora of discriminant parameters studied. However, with regard to man there has been ample opportunity and one can conclude that LSD is not teratogenic. As to the drug's oncogenic potential, the 3 reported cases of leukemia in LSD users are most likely the result of coincidence.     

Synthesis of the optical isomers of a new anticholinergic drug, penehyclidine hydrochloride (8018)

A practical diastereoselective synthetic method for 8018 enantiopure isomers is described. The intramolecular asymmetric epoxidation of mono-sulfonate 4 was applied for the execution of the synthesis of the key chiral building block for the first time. The isomers were obtained with 70-76% yields in 99-100% ee.     

Dissociation of double-stranded poly(I) . poly(C) by cis-diammine-dichloro-Pt(II).

The covalent binding of cis-Pt(NH3)2Cl2 on the double stranded poly(I) . poly(C) induced an irreversible dissociation of the two strands. This dissociation was evidenced mainly by poly(I)-Agarose affinity chromatography which allowed to recover free strands of cis-Pt(NH3)2Cl2-poly(I) from a cis-Pt(NH3)2Cl2-poly(I) . poly(C) complex, by density equilibrium centrifugation where free poly(C) could be isolated, and by acid titrations of the metal-poly(I) . poly(C) complexes. The separation of the two strands of the polyribonucleotide upon cis-Pt(NH3)2Cl2 fixation was shown not to exceed 90--95%. A dissociation curve of the polynucleotide double helix as a function of the amount of bound cis-Pt(NH3)2Cl2 was determined and was shown to be of a characteristic cooperative effect. The fixation of the paltinum compound to poly(I) . poly(C) seemed also to be cooperative.