Novel adsorptive materials by adenosine 5ʹ‐triphosphate imprinted‐polymer over the surface of polystyrene nanospheres for selective separation of adenosine 5ʹ‐triphosphate biomarker from urine

In this study, we have developed a method to assess adenosine 5?‐triphosphate by adsorptive extraction using surface adenosine 5′‐triphosphate‐imprinted polymer over polystyrene nanoparticles (412 ± 16 nm) for selective recognition/separation from urine. Molecularly imprinted polymer was synthesized by emulsion copolymerization reaction using adenosine 5′‐triphosphate as a template, functional monomers (methacrylic acid, N‐isopropyl acrylamide, and dimethylamino ethylmethacrylate) and a crosslinker, methylenebisacrylamide. The binding capacities of imprinted and non‐imprinted polymers were measured using high‐performance liquid chromatography with UV detection with a detection limit of 1.6 ± 0.02 µM of adenosine 5′‐triphosphate in the urine. High binding affinity (Q_MIP, 42.65 µmol/g), and high selectivity and specificity to adenosine 5′‐triphosphate compared to other competitive nucleotides including adenosine 5?‐diphosphate, adenosine 5?‐monophosphate, and analogs such as adenosine, adenine, uridine, uric acid, and creatinine were observed. The imprinting efficiency of imprinted polymer is 2.11 for urine (Q_MIP, 100.3 µmol/g) and 2.51 for synthetic urine (Q_MIP, 48.5 µmol/g). The extraction protocol was successfully applied to the direct extraction of adenosine 5′‐triphosphate from spiked human urine indicating that this synthesized molecularly imprinted polymer allowed adenosine 5′‐triphosphate to be preconcentrated while simultaneously interfering compounds were removed from the matrix. These submicron imprinted polymers over nano polystyrene spheres have a potential in the pharmaceutical industries and clinical analysis applications.     

Ultra‐fast adenosine 5′‐triphosphate,adenosine 5′‐diphosphate and adenosine 5′‐monophosphate detection by pressure‐assisted capillary electrophoresis UV detection

Herein, we report a new CE method to measure adenine nucleotides adenosine 5′‐triphosphate, adenosine 5′‐diphosphate, and adenosine 5′‐monophosphate in red blood cells. For this purpose, 20 mmol/L sodium acetate buffer at pH 3.80 was used as running electrolyte, and the separation was performed by the simultaneous application of a CE voltage of 25 kV and an overimposed pressure of 0.2 psi from inlet to outlet. A rapid separation of these analytes in less than 1.5 min was obtained with a good reproducibility for intra‐ and inter‐assay (CV<4 and 8%, respectively) and an excellent analytical recovery (from 98.3 to 99%). The applicability of our method was proved by measuring adenine nucleotides in red blood cells.     

Efficient Solid‐Phase Synthesis of pppRNA by Using Product‐Specific Labeling

A novel solid‐phase synthesis and purification strategy for 5′‐triphosphate oligonucleotides by using lipophilic tagging of the triphosphate moiety is reported. This is based on triphosphate synthesis with 5′‐O‐cyclotriphosphate intermediates, whereby a lipophilic tag, such as decylamine, is introduced during the ring‐opening reaction to give a linear gamma‐phosphate‐tagged species. This method enables the highly efficient synthesis of 5′‐triphosphorylated RNA derivatives and their gamma‐phosphate‐substituted analogues and will especially facilitate the advancement of therapeutic approaches that make use of 5′‐triphosphate oligonucleotides as potent activators of the cytosolic immune sensor RIG‐I.     

Chemical Morphing of DNA Containing Four Noncanonical Bases

The ability of alternative nucleic acids, in which all four nucleobases are substituted, to replicate in vitro and to serve as genetic templates in vivo was evaluated. A nucleotide triphosphate set of 5‐chloro‐2′‐deoxyuridine, 7‐deaza‐2′‐deoxyadenosine, 5‐fluoro‐2′‐deoxycytidine, and 7‐deaza‐2′deoxyguanosine successfully underwent polymerase chain reaction (PCR) amplification using templates of different lengths (57 or 525mer) and Taq or Vent (exo‐) DNA polymerases as catalysts. Furthermore, a fully morphed gene encoding a dihydrofolate reductase was generated by PCR using these fully substituted nucleotides and was shown to transform and confer trimethoprim resistance to E. coli. These results demonstrated that fully modified templates were accurately read by the bacterial replication machinery and provide the first example of a long fully modified DNA molecule being functional in vivo.     

Enzymatic Synthesis of 7′,5′‐Bicyclo‐DNA Oligonucleotides

The selection of artificial genetic polymers with tailor‐made properties for their application in synthetic biology requires the exploration of new nucleosidic scaffolds that can be used in selection experiments. Herein, we describe the synthesis of a bicyclo‐DNA triphosphate (i.e., 7′,5′‐bc‐TTP) and show its potential to serve for the generation of new xenonucleic acids (XNAs) based on this scaffold. 7′,5′‐bc‐TTP is a good substrate for Therminator DNA polymerase, and up to seven modified units can be incorporated into a growing DNA chain. In addition, this scaffold sustains XNA‐dependent DNA synthesis and potentially also XNA‐dependent XNA synthesis. However, DNA‐dependent XNA synthesis on longer templates is hampered by competitive misincorporation of deoxyadenosine triphosphate (dATP) caused by the slow rate of incorporation of 7′,5′‐bc‐TTP.     

Zirconia—A stationary phase capable of the separation of polar markers of myocardial metabolism in hydrophilic interaction chromatography

Creatine, phosphocreatine, and adenine nucleotides are highly polar markers of myocardial metabolism that are poorly retained on RP silica sorbents. Zirconia represents an alternative material to silica with high promise to be used in hydrophilic interaction chromatography (HILIC). This study describes a first systematic investigation of the ability of ZrO₂ to separate creatine, phosphocreatine, adenosine 5′‐monophosphate, adenosine 5′‐diphosphate, and adenosine 5′‐triphosphate and compares the results with those obtained on TiO₂. All analytes showed a HILIC‐like retention pattern when mobile phases of different strengths were tested. Stronger retention and better column performance were achieved in organic‐rich mobile phases as compared to aqueous conditions, where poor retention and insufficient column performance were observed. The effect of mobile phase pH and ionic strength was evaluated as well. The analysis of myocardial tissue demonstrated that all compounds were separated in a relevant biological material and thus proved ZrO₂ as a promising phase for HILIC of biological samples that deserves further investigation.     

DNA‐Catalyzed Introduction of Azide at Tyrosine for Peptide Modification

We show that DNA enzymes (deoxyribozymes) can introduce azide functional groups at tyrosine residues in peptide substrates. Using in vitro selection, we identified deoxyribozymes that transfer the 2′‐azido‐2′‐deoxyadenosine 5′‐monophosphoryl group (2′‐Az‐dAMP) from the analogous 5′‐triphosphate (2′‐Az‐dATP) onto the tyrosine hydroxyl group of a peptide, which is either tethered to a DNA anchor or free. Some of the new deoxyribozymes are general with regard to the amino acid residues surrounding the tyrosine, while other DNA enzymes are sequence‐selective. We use one of the new deoxyribozymes to modify free peptide substrates by attaching PEG moieties and fluorescent labels.     

Polymerase Synthesis of Photocaged DNA Resistant against Cleavage by Restriction Endonucleases

5‐[(2‐Nitrobenzyl)oxymethyl]‐2′‐deoxyuridine 5′‐O‐triphosphate was used for polymerase (primer extension or PCR) synthesis of photocaged DNA that is resistant to the cleavage by restriction endonucleases. Photodeprotection of the caged DNA released 5‐hydroxymethyluracil‐modified nucleic acids, which were fully recognized and cleaved by restriction enzymes.     

A cationic dye triplet as a unique "glue" that can connect fully matched termini of DNA duplexes

In this study, we propose that three consecutive cationic p‐methylstilbazoles tethered on D ‐threoninols ( Z residues) at 5′ termini act as a unique “glue” connecting DNA duplexes by their interstrand cluster formation. Interstrand clustering of p‐methylstilbazoles ( ZZZ triplets) induces narrowing and hypsochromic shift of bands at 350 nm, which can be assigned to the absorption of p‐methylstilbazole. However, single‐stranded DNA conjugates involving a ZZZ triplet at the 5′ terminus of 8‐mer native nucleotides is found not to induce such large spectral changes, which implies that the intrinsic self‐assembling property of ZZZ triplets is weak. Interestingly, when this conjugate is hybridized with a complementary 8‐mer native oligonucleotide, a remarkable spectral change is observed, indicating the dimerization of a duplex through the interstrand clustering of ZZZ triplets. Dimerization of the duplex is also evidenced by cold‐spray ionization mass spectrometry. This interstrand clustering is observed only when a ZZZ triplet is tethered to a 5′ rather than 3′ terminus. Furthermore, the stability of the interstrand cluster increases by increasing the number of nucleobases of the DNA portion, and when mismatched base pairs are incorporated or when a base next to the Z residue is deleted, the stability substantially drops. When we apply the ZZZ triplet to the formation of a nanowire using two complementary DNA conjugates, each of which has a ZZZ triplet at the 5′ termini as overhang, we demonstrate the successful formation of a nanowire by native PAGE analysis. Since native sticky ends that have three nucleotides do not serve as “glue”, ZZZ triplets with their unique glue‐like properties are prime candidates for constructing DNA‐based nanoarchitectures.     

DNA‐Catalyzed Lysine Side Chain Modification

Catalyzing the covalent modification of aliphatic amino groups, such as the lysine (Lys) side chain, by nucleic acids has been challenging to achieve. Such catalysis will be valuable, for example, for the practical preparation of Lys‐modified proteins. We previously reported the DNA‐catalyzed modification of the tyrosine and serine hydroxy side chains, but Lys modification has been elusive. Herein, we show that increasing the reactivity of the electrophilic reaction partner by using 5′‐phosphorimidazolide (5′‐Imp) rather than 5′‐triphosphate (5′‐ppp) enables the DNA‐catalyzed modification of Lys in a DNA‐anchored peptide substrate. The DNA‐catalyzed reaction of Lys with 5′‐Imp is observed in an architecture in which the nucleophile and electrophile are not preorganized. In contrast, previous efforts showed that catalysis was not observed when Lys and 5′‐ppp were used in a preorganized arrangement. Therefore, substrate reactivity is more important than preorganization in this context. These findings will assist ongoing efforts to identify DNA catalysts for reactions of protein substrates at lysine side chains.     

A supramolecular optic receptor for selective recognition CDP in neutral aqueous solution

We designed and synthesized a Cu-coordination complex based on a seven-membered amide cycle and studied its binding ability with nucleotides (cytidine 5′-monophosphate (CMP), cytidine 5′-diphosphate (CDP), cytidine 5′-triphosphate (CTP), cytidine d-5′-monophosphate (dCMP), and thymidine d-5′-monophosphate (dTMP)) by UV-Vis spectroscopy. Results indicate that the compound shows the highest binding ability with CDP among the studied nucleotides and can selectively and strongly bind nucleotides in neutral aqueous solution. The compound can be used as optical receptor for the detection of CDP.     

Straightforward Ball-Milling Access to Dinucleoside 5′,5′-Polyphosphates via Phosphorimidazolide Intermediates

A solvent-assisted mechanochemical approach to access symmetrical and mixed dinucleoside 5,5′-polyphosphates is reported. Under ball-milling conditions, nucleoside 5′-monophosphates were quantitatively activated using 1,1′-carbonyldiimidazole, forming their phosphorimidazolide derivatives. The addition of a nucleoside 5′-mono-, di- or triphosphate directly led to the formation of the corresponding dinucleotides. Benefits of the reported one-pot method include the use of unprotected nucleotides in their sodium or acid form, activation by the eco-friendly 1,1′-carbonyldiimidazole, non-dry conditions, short reaction time, high conversion rates, and easy setup and purification. This work offers new perspectives for the synthesis of nucleotide conjugates and analogues, combining the phosphorimidazolide approach and milling conditions.     

A Facile and Cost‐effective Electroanalytical Strategy for the Quantification of Deoxyguanosine and Deoxyadenosine in Oligonucleotides Using Screen‐printed Graphite Electrodes

The development of electroanalytical methods for the detection and quantification of nucleotides in DNA offers vital implications in assessing the degree of oxidation or epigenetic modification in DNA. Unfortunately, the electrochemical response of oligonucleotides is strongly influenced by the size, composition and nucleic base sequence. In this article, an optimized analytical procedure for the enzymatically breakdown of the oligonucleotides to their corresponding nucleotides for the evaluation of the electrochemical response through the use of square wave voltammetry (SWV) is presented. Enzymatic digestion of oligonucleotides has been optimized in terms of buffer composition, digestion time, strategy for stopping the enzymatic reaction and filtration requirement for enzyme removal, and then compared to an established protocol. Under the optimized protocol SWV response of a number of untreated and enzymatically digested six‐mer oligonucleotides, namely 5′‐GGGGGG‐3′, 5′‐AAAAAA‐3′, 5′‐CGCGCG‐3′ and 5′‐AAACGC‐3′ have been analysed, providing a higher sensitivity for the determination of guanosine and adenosine monophosphate species under digestion conditions with a more facile and cost effective procedure. The novel strategy for the enzymatically treated oligonucleotides in combination with the SWV response provides a proof of principle for feasible applications in the diagnosis of methylated guanosine in DNA as a potential biomarker due to its relation with cancer.     

In‐capillary reactant mixing for monitoring glycerol kinase kinetics by CE

CE was used for the first time to study the two‐substrate enzyme glycerol kinase. The capillary was used as a nanoreactor in which the enzyme and its two substrates glycerol and adenosine‐5′‐triphosphate were in‐capillary mixed to realize the enzymatic assay. For kinetic parameters determination, reactants were injected (50 mbar × 5 s) as follows: (i) incubation buffer; (ii) adenosine‐5′‐triphosphate; (iii) enzyme, and (iv) glycerol. Enzymatic reaction was then initiated by mixing the reactants using electrophoretically mediated microanalysis (+20 kV for 6 s) followed by a zero‐potential amplification step of 3 min. Finally, electrophoretic separation was performed; the product adenosine‐5′‐diphosphate was detected at 254 nm and quantified. For enzyme inhibition, an allosteric inhibitor fructose‐1,6‐bisphosphate plug was injected before the first substrate plug and +20 kV for 8 s was applied for reactant mixing. A simple, economic, and robust CE method was developed for monitoring glycerol kinase activity and inhibition. Only a few tens of nanoliters of reactants were used. The results compared well with those reported in literature. This study indicates, for the first time, that at least four reactant plugs can be in‐capillary mixed using an electrophoretically mediated microanalysis approach.     

Anomalous electrophoretic migration of short oligodeoxynucleotides labelled with 5′‐terminal Cy5 dyes

By using a fluorescent exonuclease assay, we reported unusual electrophoretic mobility of 5′‐indocarbo‐cyanine 5 (5′‐Cy5) labelled DNA fragments in denaturing polyacrylamide gels. Incubation time and enzyme concentration were two parameters involved in the formation of 5′‐Cy5‐labelled degradation products, while the structure of the substrate was slightly interfering. Replacement of positively charged 5′‐Cy5‐labelled DNA oligonucleotides (DNA oligos) by electrically neutral 5′‐carboxyfluorescein (5′‐FAM) labelled DNA oligos abolished the anomalous migration pattern of degradation products. MS analysis demonstrated that anomalously migrating products were in fact 5′‐labelled DNA fragments ranging from 1 to 8 nucleotides. Longer 5′‐Cy5‐labelled DNA fragments migrated at the expected position. Altogether, these data highlighted, for the first time, the influence of the mass/charge ratio of 5′‐Cy5‐labelled DNA oligos on their electrophoretic mobility. Although obtained by performing 3′ to 5′ exonuclease assays with the family B DNA polymerase from Pyrococcus abyssi, these observations represent a major concern in DNA technology involving most DNA degrading enzymes.     

The electrophoretic mobility of DNA fragments differing by a single 3′‐terminal nucleotide in an automated capillary DNA sequencer

The electrophoretic mobility of DNA fragments that differ by a single 3′‐terminal nucleotide was assessed by capillary electrophoresis. This was accomplished using dideoxy sequencing with a 5′‐fluorescently labelled primer to generate DNA fragments with 3′‐hydrogen ends. The resulting DNA fragments were electrophoresed on the ABI 3730 automated capillary sequencer, and the data were analysed with the GeneMapper software to determine the electrophoretic mobility differences on addition of a 3′‐terminal nucleotide. It was found that the 3′‐terminal nucleotide gave rise to different electrophoretic mobility profiles depending on the identity of the terminal nucleotide. The apparent electrophoretic mobility was (faster) –C > ?A > ?T > ?G (slower). The C‐terminated fragments were the fastest and the G‐terminated fragments the slowest, relative to other nucleotides. It was proposed that the terminal nucleotide effect was due to changes in partial net charges on the nucleotides that resulted in alterations in the electrophoretic mobility of the DNA fragments in the automated capillary DNA sequencer. Other alternative explanations are also discussed. Copyright © 2012 John Wiley & Sons, Ltd.     

Simultaneous Determination of Adenosine and Adenosine‐5′‐triphosphate at Nanogold Modified Indium Tin Oxide Electrode by Osteryoung Square‐Wave Voltammetry

Simultaneous determination of adenosine and adenosine‐5′‐triphosphate has been described using nanogold modified indium tin oxide electrode. Gold nanoparticles catalyze adenosine oxidation which results in increasing separation of oxidation peaks of adenosine and ATP, making it possible to determine adenosine and adenosine‐5′‐triphosphate simultaneously. The detection limits for adenosine and ATP were found as 0.07 μM and 0.10 μM respectively with sensitivity 22.9 nA μM^?1 and 20.9 nA μM^?1. The proposed method was also used for sensing the compounds in biological samples. Influence of various square‐wave parameters and different pH conditions on peak current has also been reported.     

Accelerated,untargeted metabolomics analysis of cutaneous T‐cell lymphoma reveals metabolic shifts in plasma and tumor adjacent skins of xenograft mice

Cutaneous T‐cell lymphoma (CTCL) is a heterogeneous group of skin‐homing T‐cell neoplasms. Clinical management is stage based but diagnosis and prognosis could be extremely challenging. The presented study aims to explore the metabolic profiling of CTCL by an accelerated untargeted metabolomics data analysis tool “Mummichog” to facilitate the discoveries of potential biomarkers for clinical early stage diagnosis, prognosis, and treatments in CTCL. Ultra high‐performance liquid chromatography–quadrupole time‐of‐flight–based untargeted metabolomics were conducted on the skin and plasma of CTCL mice. It showed that the metabolism of skin changed greatly versus control samples in the development of CTCL. Increased l ‐glutamate and decreased adenosine monophosphate were the most essential metabolic features of CTCL tumor and tumor adjacent skins. Unique metabolism changes in tumor adjacent non‐involved skin tissues (ANIT) occurred in the progress of carcinogenesis, including upregulated cytidine‐5′‐triphosphate, aberrant biosynthesis of prostaglandins, pyrimidine, mevalonate pathway, and tryptophan degradation. Sharply elevated 5‐phospho‐α‐d ‐ribose 1‐diphosphate (PRPP) marked the final state of tumor in CTCL. In the plasma, systematic shifts in corticosterone, sphingolipid, and ceramide metabolism were found. These uncovered aberrant metabolites and metabolic pathways suggested that the metabolic reprogramming of PRPP in tumor tissues may cause the disturbance of cytidine and uridine metabolic homeostasis in ANIT. Accumulative cytidine‐5′‐triphosphate in ANIT may exert positive feedback on the PRPP level and leads to CTCL further development. In addition, the accelerated data analysis tool “Mummichog” showed good practicability and can be widely used in high‐resolution liquid chromatography mass spectrometry–based untargeted metabolomics.     

Stability and structure of mixed-ligand metal ion complexes that contain Ni2+, Cu2+, or Zn2+, and Histamine, as well as adenosine 5'-triphosphate (ATP4-) or uridine 5'-triphosphate (UTP(4-): an intricate network of equilibria

With a view on protein–nucleic acid interactions in the presence of metal ions we studied the “simple” mixed‐ligand model systems containing histamine (Ha), the metal ions Ni²⁺, Cu²⁺, or Zn²⁺ (M²⁺), and the nucleotides adenosine 5′‐triphosphate (ATP^4?) or uridine 5′‐triphosphate (UTP^4?), which will both be referred to as nucleoside 5′‐triphosphate (NTP^4?) . The stability constants of the ternary M(NTP)(Ha)^2? complexes were determined in aqueous solution by potentiometric pH titrations. We show for both ternary‐complex types, M(ATP)(Ha)^2? and M(UTP)(Ha)^2?, that intramolecular stacking between the nucleobase and the imidazole residue occurs and that the stacking intensity is approximately the same for a given M²⁺ in both types of complexes: The formation degree of the intramolecular stacks is estimated to be 20 to 50 %. Consequently, in protein–nucleic acid interactions imidazole–nucleobase stacks may well be of relevance. Furthermore, the well‐known formation of macrochelates in binary M²⁺ complexes of purine nucleotides, that is, the phosphate‐coordinated M²⁺ interacts with N7, is confirmed for the M(ATP)^2? complexes. It is concluded that upon formation of the mixed‐ligand complexes the M²⁺? N7 bond is broken and the energy needed for this process corresponds to the stability differences determined for the M(UTP)(Ha)^2? and M(ATP)(Ha)^2? complexes. It is, therefore, possible to calculate from these stability differences of the ternary complexes the formation degrees of the binary macrochelates: The closed forms amount to (65±10) %, (75±8) %, and (31±14) % for Ni(ATP)^2?, Cu(ATP)^2?, and Zn(ATP)^2?, respectively, and these percentages agree excellently with previous results obtained by different methods, confirming thus the internal validity of the data and the arguments used in the evaluation processes. Based on the overall results it is suggested that M(ATP)^2? species, when bound to an enzyme, may exist in a closed macrochelated form only, if no enzyme groups coordinate directly to the metal ion.     

Semiempirical studies on the interactions of dialkyldi(aquo)tin cations, [R2Sn(H2O)2]2+, with selected nucleotides

Semiempirical calculations have been carried out on the interactions of [R₂Sn(H₂O)₂]²⁺, [R = H(CH₂)_n: n = 1–8], mainly with five nucleotides, 5′‐adenosine monophosphate (5′‐AMP), but also with guanosine 5′‐monophosphate (5′‐GMP), cytidine 5′‐monophosphate (5′‐CMP), uridine‐5′‐monophosphate (5′‐UMP) and inosine 5′‐monophosphate (5′‐IMP). The preferred sites of interaction were calculated to be the ribose O2 and O3 hydroxyl oxygens and/or the phosphate oxygens, with the nitrogen sites in the bases the least attractive to the tin compounds. This is in general agreement with experimental findings. Structures of the 1:1 coordination complexes vary from distorted tetrahedral, to distorted trigonal pyramidal to distorted octahedral geometries. Copyright © 2007 John Wiley & Sons, Ltd.