Chemical and Biological O-Demethylation of Rotenone Derivatives

3-O-Demethyl and 2,3-O,O-didemethyl derivatives of natural rotenone (5′β-rotenone), 5′α-rotenone, d-epirotenone (5′β-epirotenone) and 5′α-epirotenone are obtained upon reacting 5′β-rotenone or 5′β-epirotenone with two or three molar equivalents of boron tribromide followed by recyclization of the E-ring using sodium bicarbonate. 3-Methoxy-¹⁴C-5′β-rotenone is prepared in 16% yield by treating 3-O-demethyl-5′β-rotenone with methyl-¹⁴C iodide in the presence of alkali followed by epimerization of the ¹⁴C-5′β-epirotenone byproduct for increased yield of ¹⁴C-5′β-rotenone. 3-O-Demethylation is established as a detoxification mechanism for 5′β-rotenone or for one of its metabolites based on the expiration by mice and rats of 27% and 13%, respectively, of the administered radiocarbon as ¹⁴carbon dioxide.     

mCCG methylation in angiosperms

Two different methods were used to investigate the abundance of cytosine methylation at the outer (5′) position in 5′-CCG-3′ trinucleotides in angiosperm genomes. Mspl is unable to cut its target site if the outer cytosine is methylated (5′-^mCCGG-3′). Using Mspl restriction analysis, it was shown that 5′-^mCCG-3′ is present in all angiosperm genomes examined, and that the amount of cytosine methylation at this site varies between species. Subsequently, direct measurements were made of the amount of methylation at both cytosines in a subset of 5′-CCG-3′ trinucleotides in the Arabidopsis thaliana genome. Based upon these analyses, it was estimated that approximately 20–30% of 5′-CCG-3′ trinucleotides in A. thaliana are methylated at the outer cytosine. Approximately 20% of the 5′-CCG-3′ trinucleotides contain 5-methyl-cytosine at the inner cytosine position, which corresponds to a previous determination of 5′-^mCG-3′ methylation in A. thaliana. The implications of 5′-^mCCG-3′ methylation are discussed.     

Efficient Synthesis of 2′-Bromo-2′-Deoxy-3′,5′-O-TPDS-pyrimidine Nucleosides by Boron Trifluoride Catalyzed Reaction of O2,2′-Anhydro-(1-β-D-Arabinofuran0Syl)pyrimidine Nucleosides with Lithium Bromide

Abstract

Efficient syntheses of 2′-bromo-2′-deoxy-3′,5′-O-TPDS-uridine (5a) and 1-(2-bromo-3,5-O-TPDS-β-D-ribofuranosyl)thymine (5b) from uridine and 1-(β-D-ribofuranosyl)thymine are described, respectively. The key step is a treatment of 3′,5′-O-TPDS-O²,2′-anhydro-1-(β-D-ardbinofuranosyl)uracil (4a) and -thymine (4b) with LiBr in the presence of BF₃-OEt₂ in 1,4-dioxane at 60°C to give 5a and 5b in 98%, and 96% yield, respectively.

     

Purine and Pyrimidine 5′-Nucleotide Catabolism in Tetrahymena pyriformis W1

SYNOPSIS Deamination at pH 7.5 of adenosine, deoxyadenosine, cytidine and deoxycytidine by cell-free preparations of Tetrahymena pyriformis W was observed both in the presence and absence of fluoride. Deamination of 5′-AMP, 5′-dAMP, 5′-CMP, and 5′-dCMP was found only in the absence of fluoride. Dephosphorylation of the above nucleotides by acid phosphatases occurred at pH 4.5; reduced activity was noted at pH 7.5. Fluoride effectively blocked acid phosphatase activity at both pH values. This correlation of phosphatase and deaminase activities suggests a catabolic pathway for 5′-AMP and 5′-CMP whereby dephosphorylation precedes deamination. Radiolabelled substrates were used to test this hypothesis. The experiments were designed so that conversion of as little at 1.0% of the radiolabelled substrate to the deaminated product could be detected. No 5′-IMP or 5′-UMP, the expected deamination products of 5′-AMP and 5′-CMP, respectively, was recovered after incubation of the radiolabelled substrates with cell-free enzyme preparations. Thus, it appears that Tetrahymena has no 5′-AMP or 5′-CMP deaminases and that these compounds are deaminated only after conversion to nucleosides. Acid phosphatase activity toward 5′-GMP, 5′-dGMP, 5′-TMP, 5′-UMP, and 5′-XMP was also found.     

Adenylyl-(5′, 2′)-adenosine 5′-Phosphate ((2′-5′) pA-A) in Crude Crystals of 5′-Adenylic Acid Isolated from Nuclease P1 (Penicillium Nuclease) Digest of Technical Grade Yeast RNA

Adenylyl (5′,2′)-adenosine 5′-phosphate ((2′-5′)pA-A) was detected in crude crystals of 5′-AMP prepared from Penicillium nuclease (nuclease P₁) digest of a technical grade yeast RNA. While (3′–5′)A-A was split by nuclease P₁, spleen phosphodiesterase, snake venom phosphodiesterase or alkali, (2′–5′)A-A was not split by a usual level of nuclease P₁ or spleen phosphodiesterase. Nuclease P₁ digests of 12 preparations of technical grade yeast RNA tested were confirmed to contain (2′–5′)pA-A. Its content was about 1 to 2% of the AMP component of each RNA preparation. As poly(A) was degraded completely by the Penicillium enzyme into 5′-AMP without formation of any appreciable amount of (2′–5′)pA-A, the technical grade RNA is supposed to contain 2–5′ phosphodiester linkages in addition to 3′–5′ major linkages.     

Nucleosides VI: A Novel and Convenient Synthesis of Purine S-Cyclonucleosides Via Mitsunobu Reaction

Abstract

Two representative S-cyclonucleosides, 8,5′-anhydro-2′, 3′-O-isopropylidene-8-mercaptoadenosine (3) and 8,2′-anhydro-3′,5′-O-(tetraisopropyldisiloxane-1,3-diyl)-8-mercaptoguanosine (8), were prepared in good yields by dropwise addition of one equivalent each of triphenylphosphine and DEAD in DMF into a mixture of 2′,3′-O-isopropylidene-8-mercaptoadenosine (2) or 3′,5′-O-(tetra-iso-propyldisiloxane-1,3-diyl)-8-mercaptoguanosine (7), respectively, in DMF. Treatment of compound 2 with two equivalents each of triphenylphosphine and DEAD in DMF afforded N-[8,5′-anhydro-2′,3′-O-isopropylidene-8-mercaptopurin-6-yl]triphenylphospha-λ5-azene (4) in 87% yield.     

Synthesis of the 2′-,3′-Didehydro-2′-,3′-dideoxy and 2′-,3′-Dideoxy Derivatives of 6-Azauridine and a New Route to 2′-,3′-Didehydro-2′-,3′-dideoxy-5-chlorouridine

Abstract

The 5′-O-(4,4′-dimethoxytrityl) and 5′-O-(tert-butyldimethylsilyl) derivatives of 2′-,3′-O-thiocarbonyl-6-azauridine and 2′,3′-O-thiocarbonyl-5-chlorouridine were synthesized from the parent nucleosides by reaction with 4, 4′-dimethoxytrityl chloride and tert-butyldimethylsilyl chloride, respectively, followed by treatment with 1,1′-thiocarbonyldiimidazole. Introduction of a 2′-,3′-double bond into the sugar ring by reaction of the 5′-protected 2′-,3′-O-thionocarbonates with 1, 3-dimethyl-2-phenyl-1, 3, 2-diazaphospholidiine was unsuccessful, but could be accomplished satisfactorily with trimethyl phosphite. Reactions were generally more successful with the 5′-silylated than with the 5′-tritylated nucleosides. Formation of 2′-,3′-O-thiocarbonyl derivatives proceeded in higher yield with 5′-protected 6-azauridines than with the corresponding 5-chlorouridines because of the propensity of the latter to form 2,2′-anhydro derivatives. In the reaction of 5′-O-(tert-butyldimethylsilyl)-2′-,3′-O-thiocarbonyl-6-azauridine with trimethyl phosphite, introduction of the double bond was accompanied by N³-methylation. However this side reaction was not a problem with 5′-O-(tert-butyldimethylsilyl)-2′-, 3′-O-thioarbonyl-5-chlorouridine. Treatment of 5′-O-(tert-butyldimethylsilyl)-2′-, 3′-didehydro-2′-,3′-dideoxy-6-azauridine with tetrabutylammonium fluoride followed by hydrogenation afforded 2′-,3′-dideoxy-6-azauridine. Deprotection of 5′-O-(tert-butyldimethylsilyl)-2′-, 3′-didehydro-2′-,3′-dideoxy-5-chlorouridine yielded 2′-,3′-didehydro-2′-,3′-dide-oxy-5-chlorouridine.     

Synthesis of 5′-C-Branched Thymidines and Conversion to Phosphoramidites

Abstract

Thymidine was converted to its 5′-epoxy derivative, which was reacted with nucleophiles to give 5′-C-aminomethyl-, 5′-C-bromomethyl-, 5′-C-cyanomethyl, and 5′-C-methoxymethylthymidine derivatives with defined stereochemistry. 5′-C-ally-, 5′-C-hydroxymethyl-, 5′-C-hydroxypropyl-, and 5′-C-(imidazole-4-acetamido)methyl-thymidine derivatives were also prepared. The 5′-C-branched thymidines were converted to the corresponding phosphoramidites.     

Crystal structure of guanylyl-2′,5′-cytidine dihydrate: An analogue of msDNA-RNA junction in stigmatella aurantiaca

Sequence analysis of msDNA from bacterium such as Stigmatella aurantiaca, Myxococcus xanthus and Escherichia coli B revealed that the guanine residue of the single-stranded RNA is linked to the cytosine residue of the msDNA through a 2′–5′ instead of a conventional 3′–5′ phosphodiester bond. We have now obtained the crystal structure of the self-complementary dimer guanylyl-2′,5′-cytidine (G2′p5′C) that occurs at the msDNA-RNA junction. G2′p5′C crystallizes in the orthorhombic space group P2₁2₁2₁ with a = 8.376(2), b = 16.231(5), c = 18.671(4). CuK ∝ intensity data were collected on a diffractometer in the ω ?2θ scan mode. The amount of 1699 out of 2354 reflections having I ≥ 3σ (F) were considered observed. The structure was solved by direct methods and refined by full-matrix least squares to a R factor of 0.054. The conformation of the guanine base about the glycosyl bond is syn (χ₁ = ?54°) and that of cytosine is anti (χ₂ = 156°). The 5′ and 2′ and ribose moieties show C2′-endo and C3-endo mixed puckering just like in A2′p5′A, A2′p5′C, A2′p5U, and dC3′p5′G. Charge neutralization in G2′p5′C is accomplished through protonation of the cytosine base. An important feature of G2′p5′C is the stacking of guanine on ribose 04′ of cytosine similar to that seen in other 2′–5′ dimers. G2′p5′C, unlike its 3′–5′ isomer, does not form a miniature double helix with the Watson-Crick base-pairing pattern. Comparison of G2′p5′C with A2′p5′C reveals that they are isostructural. A branched trinucleotide model for the msDNA-RNA junction has been postulated. © 1994 John Wiley & Sons, Inc.     

Molecular conformations and 8-CH exchange rates of purine ribo- and deoxyribonucleotides: investigation by Raman spectroscopy

The rate of deuterium exchange of the 8-CH group in a purine deoxyribonucleotide, is the same as the 8-CH exchange rate in the corresponding purine ribonucleotide, with the exception of 5′-nucleotides of guanine. The observed 20% slower rate of 8-CH exchange in 5′-dGMP versus 5′-rGMP, over the temperature range 50–80°C, are attributable to differences in molecular conformation, including differences in ring puckering of the furanose substituents. Minor differences in 8-CH exhange rates are observed between 5′-and cyclic (3′:5′)-deoxyribonucleotides of a given purine, which are similar to those observed previously between corresponding 5′- and cyclic ribonucleotides that have been attributed to the charge difference of their respective phosphate groups [Ferreira, S. A. & Thomas, G. J., Jr. (1981) J. Raman Spectrosc. 11 , 508–514]. The coupling of guanine and furanose ring structures in the 5′-nucleotides is also evident from the vibrational frequencies of the guanine ring, which are strongly dependent on the pucker of the attached furanose moiety. Raman difference spectroscopy clearly reveals the dependence of purine nucleotide spectra on sugar-ring pucker. In the case of GMP, the guanine characteristic ring breathing mode near 600–700 cm^?1 depends for its exact position and intensity on the proportion of C3′-endo (668 cm^?1) and C2′-endo (682 cm^?1) conformers in equilibrium with one another. The Raman intensity ratio I(668)/I(682) is proposed as a measure of the conformer ratio C3′-endo/C2′-endo in 5′-dGMP with possible application also to nucleic acids. Among cyclic nucleotides, differences in spectra of deoxyribo- and ribo- forms also appear to be related to differences of molecular conformation.     

A Nucleotide Dimer Synthesis Without Protecting Groups Using Montmorillonite as Catalyst

A synthesis has been developed providing nucleotide dimers comprising natural or unnatural nucleoside residues. A ribonucleoside 5′-phosphorimidazolide is added to a nucleoside adsorbed on montmorillonite at neutral pH with the absence of protecting groups. Approximately 30% of the imidazolide is converted into each 2′-5′ dimer and 3′-5′ dimer with the rest hydrolyzed to the 5′-monophosphate. Experiments with many combinations have suggested the limits to which this method may be applied, including heterochiral and chimeric syntheses. This greener chemistry has enabled the synthesis of dimers from activated nucleotides themselves, activated nucleotides with nucleosides, and activated nucleotides with nucleotide 5′-monophosphates.

[Supplemental materials are available for this article. Go to the publisher's online edition of Nucleosides, Nucleotides & Nucleic Acids to view the free supplemental files.]     

Degradation of Nucleic Acids and their Related Compounds by Microbial Enzymes

Seven strains of microorganisms selected by the previous screening tests were further compared on their ability to produce extracellular enzyme systems capable of degrading RNA into 5′-ribonucleotides. As a result, two strains of Streptomyces were finally concluded to be most preferable. When these two were applied, the rate of 5′-nucleotide production reached up to 70%.

Bacillus subtilis was outstanding in its activity to degrade RNA, but its PDase activity producing 5′-nucleotides from RNA was found to be lower than those of Streptomyces strains. A pathway involving 3′- and 5′-nucleotides as intermediates was proposed for the degradation of RNA by the Bacillus enzyme system. The activity of RNA-degrading enzyme system of Bacillus subtilis contained in the supernatant of culture fluid was found to be lost at 700°C but remained to certain extent at 100°C, a possible mechanism for the phenomenon being discussed. Usability of the Bacillus enzyme system in the practical production of 5′-nucleotides under the condition of high RNA concentration was discussed.     

New Dinucleoside Analogues via Cross-Coupling Metathesis

Synthesis of 3′-3′, 5′-5′, and 3′-5′ dimeric thymidine, linked by an olefinic chain between glycosidic moieties is described. Cross metathesis reaction of 3′ or 5′ O-allyl analogues of thymidine led to the expected 3′-3′ and 5′-5′ dimeric compounds, respectively. In order to obtain the 3′-5′ dimer, 5′-O-allyl and 3′-O-allyl monomers were first linked by their free 3′ OH and 5′ OH groups through a glutaryl spacer; ring closing metathesis was then operated upon this temporary dimer, followed by glutaryl removal.     

Nucleosides and Nucleotides. 104. Radical and Palladium-Catalyzed Deoxygenation of the Allylic Alcohol Systems in the Sugar Moiety of Pyrimidine Nucleosides§,1

Abstract

New methods for the synthesis of 2′,3′-didehydro-2′,3′-dideoxy-2′ (and 3′)-methyl-5-methyluridines and 2′,3′-dideoxy-2′ (and 3′)-methylidene pyrimidine nucleosides have been developed from the corresponding 2′ (and 3′)-deoxy-2′ (and 3′)-methylidene pyrimidine nucleosides. Treatment of a 3′-deoxy-3′-methylidene-5-methyluridine derivative 8 with 1,1′-thiocarbonyldiimidazole gave the allylic rearranged 2′,3′-didehydro-2′,3′-dideoxy-3′-[(imidazol-1-yl)carbonylthiomethyl] derivative 24. On the other hand, reaction of 8 with methyloxalyl chloride afforded 2′-O-methyloxalyl ester 25. Radical deoxygenation of both 24 and 25 gave 26 exclusively. Palladium-catalyzed reduction of 2′,5′-di-O-acetyl-3′-deoxy-3′-methylidene-5-methyluridine (32) with triethylammonium formate as a hydride donor regioselectively afforded the 2′,3′-dideoxy-3′-methylidene derivative 35 and 2′,3′-didehydro-2′,3′-dideoxy-3′-methyl derivative 34 in a ratio of 95:5 in 78% yield. These reactions were used on the corresponding 2′-deoxy-2′-methylidene derivatives. An alternative synthesis of 2′,3′-dideoxy-2′-methylidene pyrimidine nucleosides (43, 52, and 54) was achieved from the corresponding 1-(3-deoxy-β-D-thero-pentofuranosyl)pyrimidines (44 and 45). The cytotoxicity against L1210 and KB cells and inhibitory activity of the pathogenicity of HIV-1 are also described     

Synthesis of the Stereoisomers of Natural Rotenone

The reaction of rotenone, which has the 5′β-isopropenyl grouping, with boron tribromide in dichloromethane gives the 1′,5′-seco-5′-bromo compound having the opened E-ring. When treated with sodium bicarbonate in aqueous acetone, the compound closes the E-ring to form two products having the 5′-isopropenyl grouping in the α- and β-configurations. By this cycle, rotenone (5′β-rotenone) gives 5′α-epirotenone as well as rotenone, while d-epirotenone (5′β-epirotenone) gives 5′α-rotenone (the antipode of natural rotenone) as well as d-epirotenone.     

Theoretical drug design: 6-azauridine-5'-phosphate--its X-ray crystal structure, potential energy maps, and mechanism of inhibition of orotidine-5'-phosphate decarboxylase.

The cytostatic drug 6-azauridine is converted in vivo to 6-azauridine-5′-phosphate (z⁶Urd-5′-P), which blocks the enzyme orotidine-5′-phosphate decarboxylase (Ord-5′-Pdecase) and therefore inhibits the de novo production of uridine-5′-phosphate (Urd-5′-P). In order to relate the structure and function of z⁶Urd-5′-P, it was crystallized as trihydrate, space group P2₁2₁2₁ with a = 20.615 Å, b = 6.265 Å, c = 11.881 Å, and the structure established by Patterson methods. Atomic parameters were refined by full-matrix least-squares methods to R = 0.066 using 1638 counter measured x-ray data. The ribose of z⁶Urd-5′-P is in a twisted C(2′)-exo, C(3′)endo conformation, the heterocycle is in extreme anti position with angle N(6)-N(1)-C(1′)-O(4′) at 86.3°, and the orientation about the C(4′)-C(5′) bond is gauche, trans in contrast to gauche, gauche found for all the other 5′-ribonucleotides. Conformational energy calculations show that z⁶Urd-5′-P may adopt an extreme anti conformation not allowed to Urd-5′-P, and they also predict the same unusual trans, gauche conformation about the C(4′)-C(5′) bond in orotidine-5′-phosphate (Ord-5′-P) and in z⁶Urd-5′-P, which renders the distances O(2)…O(5′) in z⁶Urd-5′-P and O(7)…O(5′) in Ord-5′-P comparable. On this basis the function of z⁶Urd-5′-P as an Ord-5′-Pdecase inhibitor can be explained as being due to its structural similarity with the substrate Ord-5′-P and further clarifies the inhibitory action of 5′-nucleotides bearing the heterocycles oxipurinol, xanthine, or allopurinol [J. A. Fyfe, R. L. Miller, and T. A. Krenitsky, J. Biol. Chem. 248 , 3801 (1973)]. With this in mind, new inhibitors for Ord-5′-Pdecase may be designed.     

Accumulation of 5′ guanine nucleotides by mutants of Brevibacterium ammoniagenes

5′Xanthylic acid was efficiently converted to 5′guanine nucleotides (5′GMP, 5′GDP, and 5′GTP) without being degraded to guanine via 5′GMP by decoyinine resistant mutants of strain KY 13315 which had been isolated from Brevibacterium ammoniagenes and was practically devoid of 5′nucleotide degrading activity. The concentration of phosphate in the medium showed a profound effect on the ratio of the accumulated 5′guanine nucleotides, making it possible to direct the fermentation towards 5′GMP or 5′GTP. A direct accumulation of 5′guanine nucleotides from carbohydrate was possible by mixed cultivation of a 5′XMP accumulating strain and a 5′XMP converting mutant. A maximum concentration of 9.67 mg of 5′guanine nucleotides per ml was obtained directly from glucose in such a mixed culture.     

Selective Deuteration Labelling of 2′-Deoxyguanosine at the Carbon C-4’ Position

Abstract

Selective incorporation of deuterium within the sugar moiety of nucleosides and oligonucleotides can be used for different purposes including isotopic effect determination in mechanistic studies, massspectrometry fragmentation investigations, nuclear magnetic resonance analyses. We wish to report a simple method which allows the selective deuteration labelling of 2'-deoxyguanosine at the C-4'position through the intermediary of 9-(2-deoxy-B-D-erythropento-1,5-dialdo-114-furanosyllquanine. Heating of aqueous pyridine solution [1:11 of 2′-deoxyguanosine-5′-aldehyde for 1 hr at 60°C leads to a partial epimerisation of carbon C-4' with subsequent formation of 9-(2-deoxy-α-L-threopento-1,5-dialdo-1,4-furanosyl)guanine in 40% yield. A likely intermediate of this reaction appears to be a 5'-enol derivative. Similar treatment of 2′-deoxyguanosine-5′-aldehyde in D₂0-pyridine [1-1] gives after NaBH₄ reduction 60% of 2′-deoxyguanosine which is selectively deuterated at the C-4′ position. The extend of the isotopic labelling was up to 95% as determined by high resolution electron impact mass spectrometry and ¹H NMR analyses. Heating of the aqueous pyridine solution of 2′-deoxyguanosine-5′-aldehyde for a longer period (3–4 hrs) gave rise to two other nucleosides which where assigned as 9-(2-deoxy-α-D-threo-pentofuranosy1)guanine and 9-(2-deoxy-n-L-erythro-pentofuranosyl)guanine. A retro-aldol mechanism appears to be involved in the epimerization reaction which takes place at carbon C-3′.