Ribavirin: Biotechnological Synthesis and Effect on the Reproduction of Vaccinia Virus

The biotechnological method of synthesis of ribavirin, vidarabin, and 6-azauridine by the use of immobilized recombinant enzymatic preparations of nucleoside phosphorylase was improved. The effect of ribavirin and its combinations with the other synthesized nucleosides on the reproduction of Vaccinia virus was studied on the culture of Vero cells. The combination of ribavirin and vidarabin was shown to provide the antiviral effect at lesser concentrations than with these compounds taken separately.     

Biotechnological synthesis of ribavirin. Effect of ribavirin and its various combinations on the reproduction of Vaccinia virus

The biotechnological method of synthesis of ribavirin, vidarabin, and 6-azauridine by the use of immobilized recombinant enzymatic preparations of nucleoside phosphorylase was improved. The effect of ribavirin and its combinations with the other synthesized nucleosides on the reproduction of Vaccinia virus was studied using cultures of Vero cells. The combination of ribavirin and vidarabin was shown to provide an antiviral effect at lesser concentrations than when these compounds were taken separately. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2004, vol. 30, no. 6; see also http://www.maik.ru.     

Ionic Liquid Mediated Synthesis of 5-Halouracil Nucleosides: Key Precursors for Potential Antiviral Drugs

Synthesis of antiviral 5-halouracil nucleosides, also used as key precursors for the synthesis of other potential antiviral drugs, has been demonstrated using ionic liquids as convenient and efficient reaction medium.     

Achievements and prospects of the directed search for antiviral agents in the nucleoside series and their derivatives]

Recent advances of antiviral drug design among nucleosides and their derivatives have been summarized. The first chapter deals with the history of nucleic acids components and further developments in this area. Next part discusses the mechanism of action of biologically active nucleosides: 2',3'-dideoxynucleosides, acyclic analogues, phosphonate derivatives and nucleoside antibiotics. The third chapter describes planning of complicated synthesis of nucleoside analogues from branched-chain sugars and stereo-specific formation of glycosidic bond upon synthesis of ribonucleoside and 2'-deoxyribonucleoside. The last part outlines further perspectives, i. e. preparation of antiviral compounds and use of nucleoside analogues in oligonucleotide synthesis.     

Asymmetric Synthesis of Cyclopropyl Carbocyclic Nucleosides

Abstract

A number of nucleosides have been synthesized as potential antiviral and antitumor agents.¹ More recently, various dideoxynucleosides have been synthesized and found to be potent anti-HIV agents.² As a part of our drug discovery program for the treatment of HIV and HBV, we have initiated to synthesize cyclopropyl carbocyclic nucleosides as potential antiviral agents. Several papers regarding the synthesis of cyclopropyl carbocyclic nucleosides have appeared in the literature.^3–5 However, they are all reported as racemic mixtures. In this abstract, we wish to report the asymmetric synthesis of cylopropyl carbocyclic nucleosides from optically active common intermediates, 6 and 11.     

An enzymatic transglycosylation of purine bases

An enzymatic transglycosylation of purine heterocyclic bases employing readily available natural nucleosides or sugar-modified nucleosides as donors of the pentofuranose fragment and recombinant nucleoside phosphorylases as biocatalysts has been investigated. An efficient enzymatic method is suggested for the synthesis of purine nucleosides containing diverse substituents at the C6 and C2 carbon atoms. The glycosylation of N(6)-benzoyladenine and N(2)-acetylguanine and its O(6)-derivatives is not accompanied by deacylation of bases.     

New insights on nucleoside 2′-deoxyribosyltransferases: a versatile Biocatalyst for one-pot one-step synthesis of nucleoside analogs

In recent years, glycosiltransferases have arisen as standard biocatalysts for the enzymatic synthesis of a wide variety of natural and non-natural nucleosides. Such enzymatic synthesis of nucleoside analogs catalyzed by nucleoside phosphorylases and 2′-deoxyribosyltransferases (NDTs) has demonstrated to be an efficient alternative to the traditional multistep chemical methods, since chemical glycosylation reactions include several protection–deprotection steps. This minireview exhaustively covers literature reports on this topic with the final aim of presenting NDTs as an efficient option to nucleoside phosphorylases for the synthesis of natural and non-natural nucleosides. Detailed comments about structure and catalytic mechanism of described NDTs, as well as their possible biological role, substrate specificity, and advances in detection of new enzyme specificities towards different non-natural nucleoside synthesis are included. In addition, optimization of enzymatic transglycosylation reactions and their application in the synthesis of natural and non-natural nucleosides have been described. Finally, immobilization of NDTs is shown as a practical procedure which leads to the preparation of very interesting biocatalysts applicable to industrial nucleoside synthesis.     

Synthesis and biological activity of 4'-thio-L-xylofuranosyl nucleosides

A series of 4'-thio-L-xylofuranosyl nucleosides were prepared and evaluated as potential anticancer and antiviral agents. The details of a convenient and high-yielding synthesis of the carbohydrate precursor 1-O-acetyl-2,3,5-tri-O-benzyl-4-thio-L-xylofuranose (6) are presented. Proof of structure and configuration at all chiral centers of the nucleosides was obtained by proton and carbon NMR. All target compounds were evaluated in a series of human cancer cell lines in culture and as antiviral agents.     

Synthesis and Biological Evaluation of Pyrimidine and Purine α-L-2′,3′-Dideoxy Nucleosides

Abstract

A series of α-L-2′,3′-dideoxy nucleosides was prepared as potential antiviral agents. The pyrimidine nucleosides were prepared by standard Vorbrüggen coupling reactions. The purine analogues were prepared by enzymatic transfer of the dideoxy sugar from a pyrimidine to a purine base. These compounds were inactive against HIV-1, HBV, HSV-1 and -2, VZV, and HCMV.     

The synthesis of deuterionucleosides

The synthesis of deuterionucleosides for site-specific incorporation into oligo-DNA or -RAA is herein reviewed for NMR or biological studies. The review covers the following aspects: (i) deuteration of the aglycone; (ii) single-site chemical deuteration of the sugar residues; (iii) multiple-site chemical deuteration of the sugar residues; (iv) enzymatic synthesis of deuterated nucleosides or nucleotides; and (v) synthesis of labelled nucleosides with multiple isotopes     

The enzymatic synthesis of antiviral agents.

The majority of potential antiviral agents which are currently undergoing clinical trials are inhibitors of the replication of nucleic acids. The most common class of these inhibitors are nucleoside analogues and the elucidation of synthetic routes to these compounds has been of interest for many years as many are anticancer agents. One synthetic development has been the application of bio-transformations to nucleoside syntheses. This topic has been reviewed recently (Shirae et al., 1991) but this review is not widely available. In the present review, the application of biotechnology to the synthesis of antiviral agents including those which are not nucleoside analogues will be discussed. Enzymatic syntheses of nucleosides can be simpler and quicker than syntheses carried out by chemical methods. The most useful enzymes are those found in catabolic pathways. Nucleoside phosphorylases and N-deoxyribosyltransferases have both been widely used for nucleoside synthesis catalysing the transfer of sugar residues from a donor nucleoside to a heterocyclic base. Enzymatic methods have also been applied to the resolution of racemic mixtures and adenosine deaminase is a convenient catalyst for the hydrolysis of amino groups on purines and purine analogues. Regioselective deprotection of nucleoside esters has been achieved with lipases and these enzymes have also been applied to the synthesis of esters of sugar-like alkaloids. The latter have potential as inhibitors of the replication of HIV. Esterases have also been used in combined chemical and enzymatic syntheses of organophosphorus antiviral agents.     

Synthesis and primary evaluation of novel HIV-1 inhibitors

The overcoming of antiviral drug resistance is an important challenge in the treatment of HIV-1 infection. According to the theory of viral error catastrophe, slightly increasing the mutation rate could exceed the error threshold for viability of a viral population and kill it. Investigation of this mechanism could lead to the discovery of new antiviral agents capable of bypassing viral resistance. To this aim, we designed several modified nucleosides. We describe here the synthesis and partial evaluation of 8-amido-2'-deoxyadenosine. The supplementary amide group on the base should allow base-pairing with several natural nucleosides, thus creating supplementary mutations that would kill the virus.     

Antiviral activity of cyclopentenyl nucleosides against orthopox viruses (Smallpox,monkeypox and cowpox)

An improved method for the synthesis of enantiomerically pure D-cyclopentenyl nucleosides has been accomplished and their antiviral activity against orthopox viruses have been evaluated. The key intermediate, L-cyclopent-2-enone 13 was prepared from D-ribose using a ring closing metathesis reaction in eight steps. Among the synthesized nucleosides, the adenine 2 (Neplanocin A), cytosine 14, and 5-F-cytosine 15 analogues exhibited potent anti-orthopox virus activity, including smallpox virus.     

The Synthesis of Deuterionucleosides

Abstract

The synthesis of deuterionucleosides for site-specific incorporation into oligo-DNA or -RNA is herein reviewed for NMR or biological studies. The review covers the following aspects: (i) deuteration of the aglycone; (ii) single-site chemical deuteration of the sugar residues; (iii) multiple-site chemical deuteration of the sugar residues; (iv) enzymatic synthesis of deuterated nucleosides or nucleotides; and (v) synthesis of labelled nucleosides with multiple isotopes.     

Anti-retroviral and cytostatic activity of 2',3'-dideoxyribonucleoside 3'-disulfides

Herein, we report the synthesis, antiviral and cytostatic effects of nucleosides bearing a 3'-disulfide function as prodrugs of potentially active 3'-mercaptonucleotides. The lack of the anti-HIV effects in mutant CEM/TK-cells for most of the thymidine disulfides suggests that a phosphorylation step involving thymidine kinase is necessary for the eventual antiviral activity of the thymidine nucleosides. The comparable anti-HIV activities of most of the disulfides and their rapid reduction in CEM cell extracts imply an inhibitory effect of the 2',3'-dideoxy-3'-mercaptothymidine 5'-triphosphate metabolite. The cytostatic effects of the disulfides in CEM/0 and Molt4/C8 cells appeared to be strongly dependent on the nature of the non-nucleosidic disulfide moiety and were decreased in preserving the anti-retroviral activity.     

First enzymatic galactosylation of acyclic nucleoside drugs by β-galactosidase: Synthesis of water-soluble β-D-galactosidic prodrugs

Acyclic nucleoside analogs constitute an important group of antiviral agents. However, these nucleoside drugs suffer from poor water solubility and low oral bioavailability in the clinic use. In the present work, the enzymatic synthesis of the water-soluble galactosidic prodrugs of acyclic nucleosides by using bovine liver β-galactosidase was described. In the enzymatic transgalactosylation between acyclovir (ACV) and o-nitrophenyl β-galactopyranoside (oNPGal), the optimum enzyme dosage, buffer pH, temperature and molar ratio of ACV to oNPGal were 0.225 U/mL, 7.0, 40°C and 2.5, respectively, under which the initial reaction rate and the yield reached 0.40 mM/h and 29%, respectively. In addition, this enzyme could accept ganciclovir (GCV) and penciclovir (PCV) as substrates, affording the corresponding 4’-β-galactosylated derivatives with the yields of 26% and 71%, respectively.     

Synthesis and biological evaluation of novel 2-deoxy-4-thio-imidazole nucleosides

A study on the use of 3'-directing groups for the synthesis of imidazole 2'-deoxy-4'-thionucleosides led to varying alpha:beta ratios in the glycosylation reaction. The para-nitrobenzoyl group gave the optimum result in the glycosylation step; therefore, this protected thiosugar 10b was used for the synthesis of a series of novel 2'-deoxy-4'-thio-imidazole nucleosides which have been evaluated for antiviral activity in vitro.     

L-nucleosides containing modified nucleobases

The synthesis of base modified L-nucleosides is described with pyrrolo[2,3-d]pyrimidines, pyrazolo[3,4-d]pyrimidines, benzimidazoles, and imidazo[1,2-a]-s-triazines as nucleobases. The conformation of the nucleosides is studied and the antiviral activity is evaluated.     

L-NUCLEOSIDES CONTAINING MODIFIED NUCLEOBASES

The synthesis of base modified l-nucleosides is described with pyrrolo[2,3-d]pyrimidines, pyrazolo[3,4-d)pyrimidines, benzimidazoles and imidazo[1,2-a]-s-triazines as nucleobases. The conformation of the nucleosides is studied and the antiviral activity is evaluated.     

Synthesis of 1,1,2-trisubstituted cyclopropane nucleosides in enantiomerically pure forms

Abstract

Due to the unique rigid and small steric feature of cyclopropane, cyclopropane nucleosides (CPNs) in which the ribose (deoxyribose) of nucleosides are replaced by a hydroxy-substituted cyclopropane, are of great biological interest. Novel 1,1,2-trisubstituted cyclopropane nucleosides were synthesized in enantiomerically pure forms as potential antiviral agents. In the synthesis, two cyclopropane tosylates, which were prepared from chiral cyclopropane lactones previously reported by us, were used effectively as common intermediates for the CPNs. These CPNs are also potentially useful as nucleoside units to incorporate into oligonucleotides in nucleic acids chemotherapy studies.