Membrane‐permeable Triphosphate Prodrugs of Nucleoside Analogues

The metabolic conversion of nucleoside analogues into their triphosphates often proceeds insufficiently. Rate‐limitations can be at the mono‐, but also at the di‐ and triphosphorylation steps. We developed a nucleoside triphosphate (NTP) delivery system (TriPPPro‐approach). In this approach, NTPs are masked by two bioreversible units at the γ‐phosphate. Using a procedure involving H‐phosphonate chemistry, a series of derivatives bearing approved, as well as potentially antivirally active, nucleoside analogues was synthesized. The enzyme‐triggered delivery of NTPs was demonstrated by pig liver esterase, in human T‐lymphocyte cell extracts and by a polymerase chain reaction using a prodrug of thymidine triphosphate. The TriPPPro‐compounds of some HIV‐inactive nucleoside analogues showed marked anti‐HIV activity. For cellular uptake studies, a fluorescent TriPPPro‐compound was prepared that delivered the triphosphorylated metabolite to intact CEM cells.     

Supramolecular Complexation of Biological Phosphates with an Acyclic Triazolium‐Linked Anthracenyl‐1,3‐Diconjugate of Calix[4]Arene: Synthesis,Characterization, Spectroscopy,Microscopy, and Computational Studies

A triazolium‐anthracenyl calix[4]arene conjugate ( L ) was synthesized by methylating the precursor triazole derivative and then characterized. The potential of the cationic L to differentiate nucleoside triphosphates (NTPs) from their mono‐ and diphosphates was demonstrated. Due to its unique combination of arms with the calix‐platform, a fluorescence enhancement was observed for L with all the NTPs, whereas there is no report with such enhancement being exhibited in case of all the NTPs. This has been supported by the aggregation of L observed from microscopy. Selectivity of L towards NTPs over other phosphates was a result of specific weak interactions, namely, ion–ion, hydrogen bonding and π ??? π, present in the 1:2 complex of L and NTPs (based on ESI MS), which were absent in their congener‐phosphates as delineated by NMR and computational studies. Thus, L stands as a unique receptor for NTPs.     

Cyclometalated Iridium(III) Complexes with Deoxyribose Substituents

Fundamental study of enzymatic nucleoside transport suffers for lack of optical probes that can be tracked noninvasively. Nucleoside transporters are integral membrane glycoproteins that mediate the salvage of nucleosides and their passage across cell membranes. The substrate recognition site is the deoxyribose sugar, often with little distinction among nucleobases. Reported here are nucleoside analogues in which emissive, cyclometalated iridium(III) complexes are “clicked” to C‐1 of deoxyribose in place of canonical nucleobases. The resulting complexes show visible luminescence at room temperature and 77 K with microsecond‐length triplet lifetimes. A representative complex is crystallographically characterized. Transport and luminescence are demonstrated in cultured human carcinoma (KB3‐1) cells.     

A highly selective and sensitive fluorescence sensing system for distinction between diphosphate and nucleoside triphosphates

Among the numerous chemosensors available for diphosphate (P(2)O(7)(4-), PPi) and nucleoside triphosphates (NTPs), only a few can distinguish between PPi and NTPs. Hence, very few bioanalytical applications based on such selective chemosensors have been realized. We have developed a new fluorescence sensing system for distinction between PPi and NTPs based on the combination of two sensors, a binuclear Zn(II) complex (1·2Zn) and boronic acid (BA), in which one chemosensor (1·2Zn) shows signal changes depending on the PPi (or NTP) concentration, and the other (BA) blocks the signal change caused by NTPs; this system enables the distinction of PPi from NTPs and is sensitive to nanomolar concentrations of PPi. The new sensing system has been successfully used for the direct quantification of RNA polymerase activity.     

Time-resolved events on the reaction pathway of transcript initiation by a single-subunit RNA polymerase: Raman crystallographic evidence

The nucleotidyl transfer reaction leading to formation of the first phosphodiester bond has been followed in real time by Raman microscopy, as it proceeds in single crystals of the N4 phage virion RNA polymerase (RNAP). The reaction is initiated by soaking nucleoside triphosphate (NTP) substrates and divalent cations into the RNAP and promoter DNA complex crystal, where the phosphodiester bond formation is completed in about 40 min. This slow reaction allowed us to monitor the changes of the RNAP and DNA conformations as well as bindings of substrate and metal through Raman spectra taken every 5 min. Recently published snapshot X-ray crystal structures along the same reaction pathway assisted the spectroscopic assignments of changes in the enzyme and DNA, while isotopically labeled NTP substrates allowed differentiation of the Raman spectra of bases in substrates and DNA. We observed that substrates are bound at 2-7 min after soaking is commenced, the O-helix completes its conformational change, and binding of both divalent metals required for catalysis in the active site changes the conformation of the ribose triphosphate at position +1. These are followed by a slower decrease of NTP triphosphate groups due to phosphodiester bond formation that reaches completion at about 15 min and even slower complete release of the divalent metals at about 40 min. We have also shown that the O-helix movement can be driven by substrate binding only. The kinetics of the in crystallo nucleotidyl transfer reaction revealed in this study suggest that soaking the substrate and metal into the RNAP-DNA complex crystal for a few minutes generates novel and uncharacterized intermediates for future X-ray and spectroscopic analysis.     

An Aptamer Intrinsically Comprising 5‐Fluoro‐2′‐deoxyuridine for Targeted Chemotherapy

An aptamer specifically binding the interleukin‐6 receptor and intrinsically comprising multiple units of the nucleoside analogue 5‐fluoro‐2′‐deoxyuridine can exert a cytostatic effect direcly on certain cells presenting the receptor. Thus the modified aptamer fulfils the requirements for active drug targeting in an unprecedented manner. It can easily be synthesized in a single enzymatic step and it binds to a cell surface receptor that is conveyed into the lysosome. Upon degradation of the aptamer by intracellular nucleases the active drug is released within the targeted cells exclusively. In this way the aptamer acts as a prodrug meeting two major prerequisites of a drug delivery system: specific cell targeting and the controlled release of the drug triggered by an endogenous stimulus.     

Nucleotide Analogues Bearing a C2′ or C3′-Stereogenic All-Carbon Quaternary Center as SARS-CoV-2 RdRp Inhibitors

The design of novel nucleoside triphosphate (NTP) analogues bearing an all-carbon quaternary center at C2′ or C3′ is described. The construction of this all-carbon stereogenic center involves the use of an intramoleculer photoredox-catalyzed reaction. The nucleoside analogues (NA) hydroxyl functional group at C2′ was generated by diastereoselective epoxidation. In addition, highly enantioselective and diastereoselective Mukaiyama aldol reactions, diastereoselective N-glycosylations and regioselective triphosphorylation reactions were employed to synthesize the novel NTPs. Two of these compounds are inhibitors of the RNA-dependent RNA polymerase (RdRp) of SARS-CoV-2, the causal virus of COVID-19.     

核苷及其类似物的三磷酸化方法研究进展

三磷酸核苷是一种具有三个磷酸基团的核苷酸,不仅在细胞的能量代谢中起着重要作用,也可用于心脑血管和神经系统等许多疾病的治疗和辅助治疗,随着分子生物学的发展,三磷酸核苷在许多生物检测技术中也应用广泛。新冠疫情爆发以来,抗病毒核苷类药物成为研究的热点,这类药物大多在体外不具有活性,而是在细胞内代谢为三磷酸形式发挥作用,在对这类化合物的抗病毒机理研究中,研究其抗病毒活性、抗病毒机制等都需要将核苷类药物进行三磷酸化,因此开发一种高效的核苷三磷酸化方法是十分必要的。本文根据三磷酸核苷的合成历史进程,综述了迄今为止三磷酸核苷的化学合成方案。旨在为核苷及其类似物的三磷酸化以及相关药物的研发提供参考。     

Structural and Docking Studies of a Nucleoside Diphosphate Kinase 1 (CsNDPK1) from Tea [Camellia sinensis (L.) O. Kuntze]

Nucleoside diphosphate kinase (NDPK, EC 2.7.4.6) is a housekeeping gene, which functions in the general homeostasis of cellular nucleoside triphosphate (NTP) pools. Among the various NDPK isoforms, cytosolic NDPK1 has been shown to be the main NDPK isoform in plants, accounting for more than 70?% of total NDPK activity in plants. For the first time, a full-length cDNA (697?bp), designated as CsNDPK1 was cloned from tea leaves and consisted of a 448-bp open reading frame (ORF) encoding a 147-amino-acid polypeptide with calculated molecular mass of 16.1?kDa and a pI of 6.3. Homology modeling of CsNDPK1 shows that the presented tea NDPK1 also contains several motifs, binding and catalytic sites which are highly conserved among other NDPKs. Docking studies of CsNDPK1 with its substrates (NTPs) are discussed in detail. In summary, we describe a reliable model of CsNDPK1 that can be used in structure-based protein?Cprotein interaction studies for identifying its potential role in intracellular communication and its physiological significance in tea.     

One-pot synthesis of nucleoside 5'-triphosphates from nucleoside 5'-H-phosphonates

Nucleoside 5'-triphosphates (NTPs) play key roles in biology and medicine. However, these compounds are notoriously difficult to synthesize. We describe a one-pot method to prepare NTPs from nucleoside 5'-H-phosphonate monoesters via pyridinium phosphoramidates, and we used this approach to synthesize ATP, UTP, GTP, CTP, ribavirin-TP, and 6-methylpurine ribonucleoside-TP (6MePTP). Poliovirus RNA-dependent RNA polymerase efficiently employed 6MePTP as a substrate, suggesting that the cognate nucleoside, a poorly understood antiviral agent, may damage viral RNA.     

Fine synthetic nucleoside chemistry based on nucleoside natural products synthesis

Synthetic nucleoside chemistry based on nucleoside natural products synthesis were described. First, a samarium diiodide (SmI 2)-promoted aldol reaction with the use of alpha-phenylthioketone as an enolate was developed. The characteristics of this reaction are that the enolate can be regioselectively generated and the aldol reaction proceeds under near neutral condition. This reaction is proved to be a powerful reaction for the synthesis of complex nucleoside natural products, and herbicidin B and fully protected tunicaminyluracil, which were undecose nucleoside natural products, were synthesized. Next, the synthetic methodology of the caprazamycins, which are promising antibacterial nucleoside natural products, was also developed by the strategy including beta-selective ribosylation without using a neighboring group participation. Our synthetic route provided a range of key analogues with partial structures to define the pharmacophore. Simplification of the caprazamycins was further pursued to develop diketopiperazine analogs.     

Metallo-nucleosides: synthesis and biological evaluation of hexacarbonyl dicobalt 5-alkynyl-2'-deoxyuridines

Reactions of 5-alkynyl-2'-deoxyuridines with dicobalt octacarbonyl Co2(CO)8 in THF at room temperature gave hexacarbonyl dicobalt nucleoside complexes (77-93%). The metallo-nucleosides were characterized, including an X-ray structure of a 1-cyclohexanol derivative. In crystalline form, the Co-Co bond is perpendicular to the plane of the uracil base, which is found in the anti position. The level of growth inhibition of MCF-7 and MDA-MB-231 human breast cancer cell lines was examined and compared to results obtained with the alkynyl nucleoside precursors. The cobalt compounds displayed good antiproliferative activities with IC50 values in the range of 5-50 microM. Interestingly, the coordination of the dicobalt carbonyl moiety to 5-alkynyl-2'-deoxyuridines led to a significant increase in the cytotoxic potency for alkyl/aryl substituents at the non-nucleoside side of the alkyne, but in the case of hydrogen (terminal alkyne) or a silyl group, a decrease of the cytotoxic effect was observed. As demonstrated using examples for an active and a low active target compound, the cytotoxicity was significantly influenced by the uptake into the tumor cells and the biodistribution into the nuclei.     

Leaving Group Assisted Strategy for Photoinduced Fluoroalkylations Using N‐Hydroxybenzimidoyl Chloride Esters

Redox‐active esters (RAEs) as alkyl radical precursors have been extensively developed for C?C bond formations. However, the analogous transformations of fluoroalkyl radicals from the corresponding acid or ester precursors remain challenging because of the high oxidation potential of the fluoroalkyl carboxylate anions. The newly developed N‐hydroxybenzimidoylchloride (NHBC) ester provides a general leaving group assisted strategy to generate a portfolio of fluoroalkyl radicals, and can be successfully applied in photoinduced decarboxylative hydrofluoroalkylation and heteroarylation of unactivated olefins. In addition, DFT calculations revealed that the NHBC ester proceeds by the fluorocarbon radical pathway, whereas other well‐known RAEs proceed by the nitrogen radical pathway.     

Synthesis and Some Biochemical Properties of a Novel 5,6,7,8‐Tetrahydropyrimido[4,5‐c]pyridazine Nucleoside

A novel nucleoside analogue is described based on the pyridazine ring system. The nucleoside was successfully incorporated into DNA via both its phosphoramidite and 5′‐triphosphate derivatives. Enzymatically, the analogue behaves essentially as thymidine: it is a good substrate for the DNA polymerases Taq and exonuclease‐free Klenow fragment, leading to full‐length products when present in either the primer or template strands. In hybridisation studies, the nucleoside displays ambiguous base‐pairing properties, including universal base properties.     

Interrelationships between purine nucleotide degradation and radical formation during intestinal ischaemia and reperfusion: an application of ion-pair high-performance liquid chromatography of nucleotides, nucleosides and nucleobases

There are peroxidative changes during the reperfusion of the rat small intestine following a 1h period of total ischaemia. That is demonstrated by the increases of the concentrations of glutathione disulphide and of thiobarbituric acid-reactive substances. An important source of the active oxygen species leading to peroxidations is the degradation of purine nucleotides. The nucleotides and their derivatives were measured by an ion-pair reversed-phase high-performance liquid chromatographic separation in a single analysis within 40 min. Modification of the elution gradient resulted in a high resolution of nucleosides and nucleobases, including allopurinol and oxypurinol. The decrease of the nucleoside triphosphate concentration and the increase of nucleoside monophosphate concentration, followed by accumulations of nucleosides and nucleobases in the course of the ischaemia were measured. During reperfusion the nucleotide pools are filled up. Restoration of adenosine triphosphate and guanosine triphosphate can be accelerated by application of the xanthine oxidoreductase inhibitor allopurinol. Pretreatment of the animals with allopurinol also diminished the formation of glutathione disulphide and thiobarbituric acid-reactive substances.     

Transport engineering in microbial cell factories producing plant-specialized metabolites

Transport engineering strategies use altered expression of transporter proteins to change metabolite distribution within an organism. The production of plant specialized metabolites in microbial cell factories encounters a set of challenges that could benefit from the implementation of transport engineering technology. The range of challenges includes premature pathway termination due to secretion of intermediates, feedback inhibition due to inefficient export of final products, low yields in bioconversion processes due to inefficient import of precursors, and poor connectivity between subcellular compartments expressing different parts of complex biosynthetic pathways. We highlight the latest examples of transport engineering in microbial cell factories producing plant specialized metabolites, identify the current knowledge gap, and propose future research for advancing the field.     

Hydrophilic interaction chromatography of nucleoside triphosphates with temperature as a separation parameter

Eight deoxynucleoside triphosphates (dNTPs) and nucleoside triphosphates (NTPs): ATP, CTP, GTP, UTP, dATP, dCTP, dGTP and dTTP, were separated with two 15 cm ZIC-pHILIC columns coupled in series, using LC-UV instrumentation. The polymer-based ZIC-pHILIC column gave significantly better separations and peak shape than a silica-based ZIC-HILIC column. Better separations were obtained with isocratic elution as compared to gradient elution. The temperature markedly affected the selectivity and could be used to fine tune separation. The analysis time was also affected by temperature, as lower temperatures surprisingly reduced the retention of the nucleotides. dNTP/NTP standards could be separated in 35 min with a flow rate of 200 μL/min. In Escherichia coli cell culture samples dNTP/NTPs could be selectively separated in 7 0min using a flow rate of 100 μL/min.