North‐ and South‐Bicyclo[3.1.0]Hexene Nucleosides: The Effect of Ring Planarity on Anti‐HIV Activity

The syntheses of new conformationally locked North‐ and South‐bicyclo[3.1.0]hexene nucleosides is reported. The North analogues were synthesized by a convergent approach from the known (1S,2R,5R)‐5‐[(tert‐butyldiphenylsilyloxy)methyl]bicyclo[3.1.0]hex‐3‐en‐2‐ol by Mitsunobu coupling with the nucleobases. The South analogues were synthesized from their bicyclo[3.1.0]hexane nucleoside precursors by the selective protection of the primary hydroxy group, conversion of the secondary alcohol into a good leaving group, and base‐catalyzed elimination to generate the olefin. The transformation of a bicyclo[3.1.0]hexane nucleoside into a bicyclo[3.1.0]hexene nucleoside flattens the five‐membered ring of the bicyclic system and rescues anti‐HIV activity for North‐D4T, North‐D4A, and South‐D4C. The relationship between planarity and the anti/syn disposition of the nucleobase that is favored by a particular pseudosugar platform are proposed as key parameters in controlling biological activity.     

A Conformational Mimetic Approach for the Synthesis of Carbocyclic Nucleosides as Anti‐HCV Leads

Computer‐aided approaches coupled with medicinal chemistry were used to explore novel carbocyclic nucleosides as potential anti‐hepatitis C virus (HCV) agents. Conformational analyses were carried out on 6‐amino‐1H‐pyrazolo[3,4‐d]pyrimidine (6‐APP)‐based carbocyclic nucleoside analogues, which were considered as nucleoside mimetics to act as HCV RNA‐dependent RNA polymerase (RdRp) inhibitors. Structural insight gained from the modeling studies revealed the molecular basis behind these nucleoside mimetics. The rationally chosen 6‐APP analogues were prepared and evaluated for anti‐HCV activity. RdRp SiteMap analysis revealed the presence of a hydrophobic cavity near C7 of the nucleosides; introduction of bulkier substituents at this position enhanced their activity. Herein we report the identification of an iodinated compound with an EC₅₀ value of 6.6 μM as a preliminary anti‐HCV lead.     

Recognizing nucleosides with transverse electronic transport via perpendicular direction of base planes for DNA sequencing

Putting the four DNA nucleosides in the middle of gold [111] nanoelectrodes with base planes parallel to the electrode surface layer, we study the transverse electronic transport properties of four nucleosides along the direction of electrodes. First, the optimal distance of the electrodes is released. The results show that the optimal electrode distance to study transverse electronic transport characteristics of DNA nucleosides is about 0.68 nm. Second, we theoretically calculate the conductance and current of the four nucleosides via perpendicular direction of base planes in the bias range of [−2, 2] V by exploiting the first principle theory. According to the calculated results, we propose three methods to recognize the nucleoside type in practice application.     

Optimized Biocatalytic Synthesis of 2-Selenopyrimidine Nucleosides by Transglycosylation**

Selenium-modified nucleosides are powerful tools to study the structure and function of nucleic acids and their protein interactions. The widespread application of 2-selenopyrimidine nucleosides is currently limited by low yields in established synthetic routes. Herein, we describe the optimization of the synthesis of 2-Se-uridine and 2-Se-thymidine derivatives by thermostable nucleoside phosphorylases in transglycosylation reactions using natural uridine or thymidine as sugar donors. Reactions were performed at 60 or 80 °C and at pH 9 under hypoxic conditions to improve the solubility and stability of the 2-Se-nucleobases in aqueous media. To optimize the conversion, the reaction equilibria in analytical transglycosylation reactions were studied. The equilibrium constants of phosphorolysis of the 2-Se-pyrimidines were between 5 and 10, and therefore differ by an order of magnitude from the equilibrium constants of any other known case. Hence, the thermodynamic properties of the target nucleosides are inherently unfavorable, and this complicates their synthesis significantly. A tenfold excess of sugar donor was needed to achieve 40−48 % conversion to the target nucleoside. Scale-up of the optimized conditions provided four Se-containing nucleosides in 6–40 % isolated yield, which compares favorably to established chemical routes.     

Biosynthesis and Genome Mining Potentials of Nucleoside Natural Products

Nucleoside natural products show diverse biological activities and serve as leads for various application purposes, including human and veterinary medicine and agriculture. Studies in the past decade revealed that these nucleosides are biosynthesized through divergent mechanisms, in which early steps of the pathways can be classified into two types (C5' oxidation and C5' radical extension), while the structural diversity is created by downstream tailoring enzymes. Based on this biosynthetic logic, we investigated the genome mining discovery potentials of these nucleosides using the two enzymes representing the two types of C5' modifications: LipL-type α-ketoglutarate (α-KG) and Fe-dependent oxygenases and NikJ-type radical S-adenosyl-L-methionine (SAM) enzymes. The results suggest that this approach allows discovery of putative nucleoside biosynthetic gene clusters (BGCs) and the prediction of the core nucleoside structures. The results also revealed the distribution of these pathways in nature and implied the possibility of future genome mining discovery of novel nucleoside natural products.     

Does Intracellular Metabolism Render Gemcitabine Uptake Undetectable in Mass Spectrometry?

The ergothioneine transporter ETT (formerly OCTN1; human gene symbol SLC22A4) is a powerful and highly specific transporter for the uptake of ergothioneine (ET). Recently, Sparreboom et al. reported that the ETT would transport nucleosides and nucleoside analogues such as cytarabine and gemcitabine with the highest efficiency. In our assay system, we could not detect any such transport. Subsequently, Sparreboom suggested that the intracellular metabolization of the nucleosides occurs so fast that the original compounds cannot be detected by LC–MS/MS after inward transport. Our current experiments with 293 cells disprove this hypothesis. Uptake of gemcitabine was easily detected by LC–MS/MS measurements when we expressed the Na⁺/nucleoside cotransporter CNT3 (SLC28A3). Inward transport was 1280 times faster than the intracellular production of gemcitabine triphosphate. The deoxycytidine kinase inhibitor 2-thio-2′-deoxycytidine markedly blocked the production of gemcitabine triphosphate. There was no concomitant surge in intracellular gemcitabine, however. This does not fit the rapid phosphorylation of gemcitabine. Uptake of cytarabine was very slow, but detection by MS was still possible. When the ETT was expressed and incubated with gemcitabine, there was no increase in intracellular gemcitabine triphosphate. We conclude that the ETT does not transport nucleosides.     

Improvement of SNAr Reaction Rate by an Electron‐Withdrawing Group in the Crosslinking of DNA Cytosine‐5 Methyltransferase by a Covalent Oligodeoxyribonucleotide Inhibitor

DNA cytosine 5‐methyltransferase (DNMT) catalyzes methylation at the C5 position of the cytosine residues in the CpG sequence. Aberrant DNA methylation patterns are found in cancer cells. Therefore, inhibition of human DNMT is an effective strategy for treating various cancers. The inhibitors of DNMT have an electron‐deficient nucleobase because this group facilitates attack by the catalytic Cys residue in DNMTs. Recently, we reported the synthesis and properties of mechanism‐based modified nucleosides, 2‐amino‐4‐halopyridine‐C‐nucleosides (d^XP), as inhibitors of DNMT. To develop a more efficient inhibitor of DNMT for oligonucleotide therapeutics, oligodeoxyribonucleotides (ODNs) containing other nucleoside analogues, which react more quickly with DNMT, are needed. Herein, we describe the design, synthesis, and evaluation of the properties of 2‐amino‐3‐cyano‐4‐halopyridine‐C‐nucleosides (d^XP^CN) and ODNs containing d^XP^CN, as more reactive inhibitors of DNMTs. Nucleophilic aromatic substitution (S_NAr) of the designed nucleosides, d^XP^CN, was faster than that of d^XP, and the ODN containing d^XP^CN effectively formed a complex with DNMTs. This study suggests that the incorporation of an electron‐withdrawing group would be an effective method to increase reactivity toward the nucleophile of the DNMTs, while maintaining high specificity.     

RNA nucleoside recognition by phthalocyanine-based molecularly imprinted polymers

Highly selective molecularly imprinted polymers (MIPs) having a phthalocyanine-based recognition centre as receptors for RNA nucleoside were prepared. In particular, a zinc phthalocyanine peripherally substituted with methacrylic groups was synthesized and utilized as functional monomer in combination with methacrylic acid (MAA) to form polymers with the aim to obtain MIPs having improved binding capacity and selectivity for nucleosides. Tri-O-acetyladenosine (TOAA) was utilized as model template in the preparation of the MIPs. The corresponding non metallated phthalocyanine was also prepared and used as functional monomer for the preparation of the MIPs in order to understand the role of the Zinc(II) ion in the binding capacity of the polymers towards the template molecule. The MIP prepared by using both the zinc phthalocyanine and MAA showed higher binding ability towards TOAA compared to the MIPs prepared using only MAA or its combination with the non metallated phthalocyanine. The results obtained suggest that the nucleoside is specifically bound to the polymer through multi-point interactions involving both the coordination of the nucleoside to the metal of the phthalocyanine and hydrogen bonding/electrostatic interactions with MAA and the modifiers linked to the phthalocyanines. As for the selectivity, the MIPs exhibited relative high binding affinities for TOAA while they did not show any binding capacity for the other RNA nucleosides.     

Modified Galacto- or Fuco-Clusters Exploiting the Siderophore Pathway to Inhibit the LecA- or LecB-Associated Virulence of Pseudomonas aeruginosa

Galacto- and fuco-clusters conjugated with one to three catechol or hydroxamate motifs were synthesised to target LecA and LecB lectins of Pseudomonas aeruginosa (PA) localised in the outer membrane and inside the bacterium. The resulting glycocluster–pseudosiderophore conjugates were evaluated as Trojan horses to cross the outer membrane of PA by iron transport. The data suggest that glycoclusters with catechol moieties are able to hijack the iron transport, whereas those with hydroxamates showed strong nonspecific interactions. Mono- and tricatechol galactoclusters ( G1C and G3C ) were evaluated as inhibitors of infection by PA in comparison with the free galactocluster ( G0 ). All of them exhibited an inhibitory effect between 46 to 75 % at 100 μM, with a higher potency than G0 . This result shows that LecA localised in the outer membrane of PA is involved in the infection mechanism.     

CycloSal‐phosphate Pronucleotides of Cytostatic 6‐(Het)aryl‐7‐deazapurine Ribonucleosides: Synthesis,Cytostatic Activity,and Inhibition of Adenosine Kinases

A series of cycloSal‐phosphate prodrugs of a recently described new class of nucleoside cytostatics (6‐hetaryl‐7‐deazapurine ribonucleosides) was prepared. The corresponding 2′,3′‐isopropylidene 6‐chloro‐7‐deazapurine nucleosides were converted into 5‐O′‐cycloSal‐phosphates. These underwent a series of Stille or Suzuki cross‐couplings with diverse (het)arylstannanes or ‐boronic acids to yield the protected 6‐(het)aryl‐7‐deazapurine pronucleotides that were subsequently deprotected to give 12 derivatives of free pronucleotides. The in vitro cytostatic effect of the pronucleotides was compared with parent nucleoside analogues. In most cases, the activity of the pronucleotide was similar to or somewhat lower than that of the corresponding parent nucleosides, with the exception of 7‐fluoro pronucleotides 13 a , 13 b , and 13 d , which had exhibited GIC₅₀ values that were improved by one order of magnitude (to the low nanomolar range). The presence of a cycloSal‐phosphate group also influenced selectivity toward various cell lines. Several pronucleotides were found which strongly inhibit human adenosine kinase but only weakly inhibit the MTB adenosine kinase.     

Production,Characterization and Synthetic Application of a Purine Nucleoside Phosphorylase from Aeromonas hydrophila

Purine nucleoside phosphorylase (PNP) from Aeromonas hydrophila encoded by the deoD gene has been over‐expressed in Escherichia coli, purified, characterized about its substrate specificity and used for the preparative synthesis of some 6‐substituted purine‐9‐ribosides. Substrate specificity towards natural nucleosides showed that this PNP catalyzes the phosphorolysis of both 6‐oxo‐ and 6‐aminopurine (deoxy)ribonucleosides. A library of nucleoside analogues was synthesized and then submitted to enzymatic phosphorolysis as well. This assay revealed that 1‐, 2‐, 6‐ and 7‐modified nucleosides are accepted as substrates, whereas 8‐substituted nucleosides are not. A few transglycosylation reactions were carried out using 7‐methylguanosine iodide ( 4 ) as a D ‐ribose donor and 6‐substituted purines as acceptor. In particular, following this approach, 2‐amino‐6‐chloropurine‐9‐riboside ( 2c ), 6‐methoxypurine‐9‐riboside ( 2d ) and 2‐amino‐6‐(methylthio)purine‐9‐riboside ( 2g ) were synthesized in very high yield and purity.     

The Peculiar Case of the Hyper-thermostable Pyrimidine Nucleoside Phosphorylase from Thermus thermophilus**

The poor solubility of many nucleosides and nucleobases in aqueous solution demands harsh reaction conditions (base, heat, cosolvent) in nucleoside phosphorylase-catalyzed processes to facilitate substrate loading beyond the low millimolar range. This, in turn, requires enzymes that can withstand these conditions. Herein, we report that the pyrimidine nucleoside phosphorylase from Thermus thermophilus is active over an exceptionally broad pH (4–10), temperature (up to 100 °C) and cosolvent space (up to 80 % (v/v) nonaqueous medium), and displays tremendous stability under harsh reaction conditions with predicted total turnover numbers of more than 10⁶ for various pyrimidine nucleosides. However, its use as a biocatalyst for preparative applications is critically limited due to its inhibition by nucleobases at low concentrations, which is unprecedented among nonspecific pyrimidine nucleoside phosphorylases.     

Fluorescent 5-alkynyl-2'-deoxyuridines: high emission efficiency of a conjugated perylene nucleoside in a DNA duplex

Four fluorescent 5-alkynyl-2'-deoxyuridines were studied in DNA oligonucleotides and their duplexes. The fluorescence response to hybridization differs dramatically for nucleosides containing a perylene fluorochrome either conjugated or not conjugated to the nucleobase. The conjugated nucleoside, 5-(perylen-3-ylethynyl)-2'-deoxyuridine, shows enhanced long-wavelength emission in the DNA duplex, in contrast to the blue fluorescence of perylene on a flexible linker (in 5-[(perylen-3-yl)methoxyprop-1-ynyl]-2'-deoxyuridine), which is quenched upon duplex formation.     

Quenching of fluorescent nucleobases by neighboring DNA: the "insulator" concept

Fluorescent nucleosides are widely used as probes of biomolecular structure and mechanism in the context of DNA, but they often exhibit low quantum yields because of quenching by neighboring DNA bases. Here we characterize the quenching by DNA of fluorescent nucleosides that have pyrene (Y), perylene (E), benzopyrene (B), or 2-aminopurine (2AP) as nucleobase replacements, and we investigate the effect of inserting varied nucleosides as potential "insulators" between the fluorescent nucleosides and other nearby DNA bases as a strategy for increasing quantum yields. The data show that the hydrocarbons are quenched by adjacent pyrimidines, with thymine being the strongest quencher. The quantum yield of pyrene is quenched 120-fold by a single adjacent T, that of benzopyrene tenfold, and that of perylene by a factor of 2.5. Quenching of excimer and exciplex dinucleoside labels (Y-Y, Y-E, E-E, etc.) was considerably lessened, but was strongest with neighboring thymine. 2-Aminopurine (2AP) is most strongly quenched (15-fold) by neighboring G. We tested four different insulator candidates for reducing this quenching by measuring the fluorescence of short oligonucleotides containing insulators placed between a fluorescent base and a quenching base. The insulators tested were a C(3) abasic spacer (S), dihydrothymidine nucleoside (DHT), terphenyl nucleoside (TP), and adenine deoxynucleoside (dA). Results showed that the abasic spacer had little effect on quenching, while the other three had substantial effects. DHT and terphenyl enhanced fluorescence of the fluorophores by factors of 5 to 70. Adenine base reduced the quenching of pyrene 40-fold. The results underscore the importance of the nearest neighbors in DNA-quenching mechanisms, and establish simple strategies for enhancing fluorescence in labeled DNAs.     

Synthesis and Antiviral Evaluation of TriPPPro‐AbacavirTP,TriPPPro‐CarbovirTP,and Their 1′,2′‐cis‐Disubstituted Analogues

Herein we describe the synthesis of lipophilic triphosphate prodrugs of abacavir, carbovir, and their 1′,2′‐cis‐substituted carbocyclic analogues. The 1′,2′‐cis‐carbocyclic nucleosides were prepared by starting from enantiomerically pure (1R,2S)‐2‐((benzyloxy)methyl)cyclopent‐3‐en‐1‐ol by a microwave‐assisted Mitsunobu‐type reaction with 2‐amino‐6‐chloropurine. All four nucleoside analogues were prepared from their 2‐amino‐6‐chloropurine precursors. The nucleosides were converted into their corresponding nucleoside triphosphate prodrugs (TriPPPro approach) by application of the H‐phosphonate route. The TriPPPro compounds were hydrolyzed in different media, in which the formation of nucleoside triphosphates was proven. While the TriPPPro compounds of abacavir and carbovir showed increased antiviral activity over their parent nucleoside, the TriPPPro compounds of the 1′,2′‐cis‐substituted analogues as well as their parent nucleosides proved to be inactive against HIV.     

Synthesis of 2,6‐Dihalogenated Purine Nucleosides by Thermostable Nucleoside Phosphorylases

The enzymatic transglycosylation of 2,6‐dichloropurine (26DCP) and 6‐chloro‐2‐fluoropurine (6C2FP) with uridine, thymidine and 1‐(β‐D ‐arabinofuranosyl)‐uracil as the pentofuranose donors and recombinant thermostable nucleoside phosphorylases from G. thermoglucosidasius or T. thermophilus as biocatalysts was studied. Selection of 26DCP and 6C2FP as substrates is determined by their higher solubility in aqueous buffer solutions compared to most natural and modified purines and, furthermore, synthesized nucleosides are valuable precursors for the preparation of a large number of biologically important nucleosides. The substrate activity of 26DCP and 6C2FP in the synthesis of their ribo‐ and 2′‐deoxyribo‐nucleosides was closely similar to that of related 2‐amino‐ (DAP), 2‐chloro‐ and 2‐fluoroadenines; the efficiency of the synthesis of β‐D ‐arabinofuranosides of 26DCP and 6C2FP was lower vs. that of DAP under similar reaction conditions. For a convenient and easier recovery of the biocatalysts, the thermostable enzymes were immobilized on MagReSyn^® epoxide beads and the biocatalyst showed high catalytic efficiency in a number of reactions. As an example, 6‐chloro‐2‐fluoro‐(β‐D ‐ribofuranosyl)‐purine ( 9 ), a precursor of various antiviral and antitumour drugs, was synthesized by the immobilized enzymes at 60 °C under high substrate concentrations (uridine:purine ratio of 2:1, mol). The synthesis was successfully scaled‐up [uridine (2.5 mmol), base (1.25 mmol); reaction mixture 50 mL] to afford 9 in 60% yield. The reaction reveals the great practical potential of this enzymatic method for the efficient production of modified purine nucleosides of pharmaceutical interest.

     

Aryloxy Phosphoramidate Triesters: a Technology for Delivering Monophosphorylated Nucleosides and Sugars into Cells

Prodrug technologies aimed at delivering nucleoside monophosphates into cells (protides) have proved to be effective in improving the therapeutic potential of antiviral and anticancer nucleosides. In these cases, the nucleoside monophosphates are delivered into the cell, where they may then be further converted (phosphorylated) to their active species. Herein, we describe one of these technologies developed in our laboratories, known as the phosphoramidate protide method. In this approach, the charges of the phosphate group are fully masked to provide efficient passive cell‐membrane penetration. Upon entering the cell, the masking groups are enzymatically cleaved to release the phosphorylated biomolecule. The application of this technology to various therapeutic nucleosides has resulted in improved antiviral and anticancer activities, and in some cases it has transformed inactive nucleosides to active ones. Additionally, the phosphoramidate technology has also been applied to numerous antiviral nucleoside phosphonates, and has resulted in at least three phosphoramidate‐based nucleotides progressing to clinical investigations. Furthermore, the phosphoramidate technology has been recently applied to sugars (mainly glucosamine) in order to improve their therapeutic potential. The development of the phosphoramidate technology, mechanism of action and the application of the technology to various monophosphorylated nucleosides and sugars will be reviewed.     

Palladium‐Catalyzed Aryl Amination Reactions of 6‐Bromo‐ and 6‐Chloropurine Nucleosides

Palladium‐catalyzed C N bond forming reactions of 6‐bromo‐ as well as 6‐chloropurine ribonucleosides and the 2′‐deoxy analogues with arylamines are described. Efficient conversions were observed with palladium(II) acetate/Xantphos/cesium carbonate, in toluene at 100 °C. Reactions of the bromonucleoside derivatives could be conducted at a lowered catalytic loading [5 mol% Pd(OAc)₂/7.5 mol% Xantphos], whereas good product yields were obtained with a higher catalyst load [10 mol% Pd(OAc)₂/15 mol% Xantphos] when the chloro analogue was employed. Among the examples evaluated, silyl protection for the hydroxy groups appears better as compared to acetyl. The methodology has been evaluated via reactions with a variety of arylamines and by synthesis of biologically relevant deoxyadenosine and adenosine dimers. This is the first detailed analysis of aryl amination reactions of 6‐chloropurine nucleosides, and comparison of the two halogenated nucleoside substrates.     

Synthesis and Anti‐herpetic Activity of Phosphoramidate ProTides

Among the many prodrug approaches aimed at delivering nucleoside monophosphates into cells, the phosphoramidate ProTide approach is one that has shown success, which has made it possible for some of the phosphoramidates to enter into clinical trials. Herein, we report the synthesis and antiviral activity of a series of phosphoramidate ProTides designed to bypass the thymidine kinase (TK) dependence of the parent nucleoside analogues. Phosphoramidate derivatives of (E)‐5‐(2‐bromovinyl)‐2′‐deoxyuridine (BVDU) that contain L ‐alanine or pivaloyloxymethyl iminodiacetate (IDA‐POM) exhibit anti‐HSV‐1 and anti‐VZV activity in cell cultures, but they largely lost antiviral potency against TK‐deficient virus strains. Among deazapurine nucleosides and their phosphoramidate derivatives, the 7‐deazaadenine containing nucleosides and their phosphoramidate triester derivatives showed weak antiviral activity against VZV. Apparently, intracellular nucleotide delivery with these phosphoramidates is partly successful. However, none of the compound prodrugs showed superior activity to their parent drugs.