Kinetic and activation thermodynamic parameters on thermal decomposition of synthetic lubricant oils

The kinetic and thermodynamic study of synthetic lubricant oils was accomplished in this work, using isothermal and non-isothermal thermogravimetry based on mass loss as a function of time and temperature. The thermodynamic and kinetic behavior of the synthetic lubricant oils depends on atmosphere and heating rates used in TG analysis. The kinetic and thermodynamic results were satisfactory, presenting good correlation.     

The Effect of DNA Sequence Directionality on G‐Quadruplex Folding

Sequence inversion in G‐rich DNA from 5′→3′ to 3′→5′ exerts a substantial effect on the number of structures formed, while the type of G‐quadruplex fold is in fact determined by the presence of K⁺ or Na⁺ ions. The melting temperatures of G‐quadruplexes adopted by oligonucleotides with sequences in the 5′→3′ direction are higher than those of their 3′→5′ counterparts with both KCl and NaCl. CD, UV, and NMR spectroscopy demonstrates the importance of primary sequence for the structural diversity of G‐quadruplexes. The changes introduced by mere sequence reversal of the G‐rich DNA segment have a substantial impact on the polymorphic nature of the resulting G‐quadruplexes and their potential physiological roles. The insights resulting from this study should enable extension of the empirical rules for the prediction of G‐quadruplex topology.     

Solution Structure of a Locked Nucleic Acid Modified Quadruplex: Introducing the V4 Folding Topology

Sharp curves : The structure of a locked nucleic acid modified telomeric sequence from Oxytricha nova displays a remarkable folding topology, distinct from the native O. nova quadruplex. Each guanine stretch folds back in a V‐shaped turn that puts the first and fourth guanines in the same tetrad, looping over a tetrad with a sharp turn in the DNA backbone, showing how subtle interplay between sequence and conformation defines the folding topology.

     

Involvement of Long‐Lived Intermediate States in the Complex Folding Pathway of the Human Telomeric G‐Quadruplex

The energy landscapes of human telomeric G‐quadruplexes are complex, and their folding pathways have remained largely unexplored. By using real‐time NMR spectroscopy, we investigated the K⁺‐induced folding of the human telomeric DNA sequence 5′‐TTGGG(TTAGGG)₃A‐3′. Three long‐lived states were detected during folding: a major conformation (hybrid‐1), a previously structurally uncharacterized minor conformation (hybrid‐2), and a partially unfolded state. The minor hybrid‐2 conformation is formed faster than the more stable hybrid‐1 conformation. Equilibration of the two states is slow and proceeds via a partially unfolded intermediate state, which can be described as an ensemble of hairpin‐like structures.     

Site-specific control of N7-metal coordination in DNA by a fluorescent purine derivative

A synthetic strategy that utilizes O6‐protected 8‐bromoguanosine gives broad access to C8‐guanine derivatives with phenyl, pyridine, thiophene, and furan substituents. The resulting 8‐substituted 2′‐deoxyguanosines are push–pull fluorophores that can exhibit environmentally sensitive quantum yields (Φ=0.001–0.72) due to excited‐state proton‐transfer reactions with bulk solvent. Changes in nucleoside fluorescence were used to characterize metal‐binding affinity and specificity of 8‐substituted 2′‐deoxyguanosines. One derivative, 8‐(2‐pyridyl)‐2′‐deoxyguanosine (2PyG), exhibits selective binding of Cu^II, Ni^II, Cd^II, and Zn^II through a bidentate effect provided by the N7 position of guanine and the 2‐pyridyl nitrogen atom. Upon incorporation into DNA, 2‐pyridine‐modified guanine residues selectively bind to Cu^II and Ni^II with equilibrium dissociation constants (K_d) that range from 25 to 850 nM ; the affinities depend on the folded state of the oligonucleotide (duplex>G‐quadruplex) as well as the identity of the metal ion (Cu>Ni?Cd). These binding affinities are approximately 10 to 1 000 times higher than for unmodified metal binding sites in DNA, thereby providing site‐specific control of metal localization in alternatively folded nucleic acids. Temperature‐dependent circular‐dichroism studies reveal metal‐dependent stabilization of duplexes, but destabilization of G‐quadruplex structures upon adding Cu^II to 2PyG‐modified oligonucleotides. These results demonstrate how the addition of a single pyridine group to the C8 position of guanine provides a powerful new tool for studying the effects of N7 metalation on the structure, stability, and electronic properties of nucleic acids.     

DNA‐Based Peroxidation Catalyst—What Is the Exact Role of Topology on Catalysis and Is There a Special Binding Site for Catalysis?

In the last decade, there has been growing interests in studies aimed at delineating the strategies used by various nucleic acid enzymes to facilitate catalysis. Insights gained from such studies would enable the design of better DNA/RNA catalysts for various applications such as biosensing. DNA and RNA catalysts have been shown to be able to catalyze myriads of reactions, including peroxidation reactions, which are catalyzed by G-quadruplexes. In this report, we provide data that clarifies how G-quadruplex peroxidases achieve catalysis. Firstly, we show that by covalently linking a hemin cofactor to DNAzymes, anti-parallel G-quadruplexes, which have been previously shown to be catalytically inefficient, can be "resurrected" to become good peroxidation catalysts. We also reveal that the relative rates of peroxidation by DNAzyme peroxidases depend on the nature of the organic reductant, arguing for a special binding site in the peroxidase-mimicking DNAzymes for catalysis.     

Formation and stability of G-quadruplexes self-assembled from guanine-rich strands

Electrospray ionization mass spectrometry (ESI-MS) was utilized to investigate the formation and stability of G-quadruplexes. For the 15 6-nt oligonucleotides tested, ESI-MS indicated that formation of a parallel tetramer quadruplex requires at least four continuous guanines in the 6-nt sequence. In addition, the G-rich strands prefer to employ "self-association" in the formation of the G-quadruplex rather than hybridized integration, and the thermodynamic-stability order of these three G-quadruplexes is Q(2)>Q(1)>Q(3).     

Programmed Self‐Assembly of a Quadruplex DNA Nanowire

The ability to produce, reproducibly and systematically, well‐defined quadruplex DNA nanowires through controlled rational design is poorly understood despite potential utility in structural nanotechnology. The programmed hierarchical self‐assembly of a long four‐stranded DNA nanowire through cohesive self‐assembly of GpC and CpG “sticky” ends is reported. The encoding of bases within the quadruplex stem allows for an uninterrupted π‐stacking system with rectilinear propagation for hundreds of nanometers in length. The wire is mechanically stable and features superior nuclease resistance to double‐stranded DNA. The study indicates the feasibility for programmed assembly of uninterrupted quadruplex DNA nanowires. This is fundamental to the systematic investigation of well‐defined DNA nanostructures for uses in optoelectronic and electronic devices as well as other structural nanotechnology applications.     

Temperature dependence of strain energy and thermodynamic properties of V2O5‐based single‐walled nanotubes: Zone‐folding approach

A zone‐folding approach is applied to estimate the thermodynamic properties of V₂O₅‐based nanotubes. The results obtained are compared with those from the direct calculations. It is shown that the zone‐folding approximation allows an accurate estimation of nanotube thermodynamic properties and gives a gain in computation time compared to their direct calculations. Both approaches show that temperature effects do not change the relative stability of V₂O₅ free layers and nanotubes derived from the α‐ and γ‐phase. The internal energy thermal contributions into the strain energy of nanotubes are small and can be ignored. © 2016 Wiley Periodicals, Inc.     

Polycyclic Azoniahetarenes: Assessing the Binding Parameters of Complexes between Unsubstituted Ligands and G‐Quadruplex DNA

Polycyclic azoniahetarenes were employed to determine the effect of the structure of unsubstituted polyaromatic ligands on their quadruplex‐DNA binding properties. The interactions of three isomeric diazoniadibenzo[b,k]chrysenes ( 4 a – c ), diazoniapentaphene ( 5 ), diazoniaanthra[1,2‐a]anthracene ( 6 ), and tetraazoniapentapheno[6,7‐h]pentaphene ( 3 ) with quadruplex DNA were examined by DNA melting studies (FRET melting) and fluorimetric titrations. In general, penta‐ and hexacyclic azoniahetarenes bind to quadruplex DNA (K_b≈10⁶ M ^?1) even in the absence of additional functional side chains. The binding modes of 4 a – c and 3 were studied in more detail by ligand displacement experiments, isothermal titration calorimetry, and CD and NMR spectroscopy. All experimental data indicate that terminal π stacking of the diazoniachrysenes to the quadruplex is the major binding mode; however, because of different electron distributions of the π systems of each isomer, these ligands align differently in the binding site to achieve ideal binding interactions. It is proposed that tetraazonia ligand 3 binds to the quadruplex by terminal stacking with a small portion of its π system, whereas a significant part of the bulky ligand most likely points outside the quadruplex structure, and is thus partially placed in the grooves. Notably, 3 and the known tetracationic porphyrin TMPyP4 exhibit almost the same binding properties towards quadruplex DNA, with 3 being more selective for quadruplex than for duplex DNA. Overall, studies on azonia‐type hetarenes enable understanding of some parameters that govern the quadruplex‐binding properties of parent ligand systems. Since unsubstituted ligands were employed in this study, complementary and cooperative effects of additional substituents, which may interfere with the ligand properties, were eliminated.     

Multitasking Water‐Soluble Synthetic G‐Quartets: From Preferential RNA–Quadruplex Interaction to Biocatalytic Activity

Natural G‐quartets, a cyclic and coplanar array of four guanine residues held together through a Watson–Crick/Hoogsteen hydrogen‐bond network, have received recently much attention due to their involvement in G‐quadruplex DNA, an alternative higher‐order DNA structure strongly suspected to play important roles in key cellular events. Besides this, synthetic G‐quartets (SQ), which artificially mimic native G‐quartets, have also been widely studied for their involvement in nanotechnological applications (i.e., nanowires, artificial ion channels, etc.). In contrast, intramolecular synthetic G‐quartets (iSQ), also named template‐assembled synthetic G‐quartets (TASQ), have been more sparingly investigated, despite a technological potential just as interesting. Herein, we report on a particular iSQ named ^PNADOTASQ, which demonstrates very interesting properties in terms of DNA and RNA interaction (notably its selective recognition of quadruplexes according to a bioinspired process) and catalytic activities, through its ability to perform peroxidase‐like hemin‐mediated oxidations either in an autonomous fashion (i.e., as pre‐catalyst for TASQzyme reactions) or in conjunction with quadruplex DNA (i.e., as enhancing agents for DNAzyme processes). These results provide a solid scientific basis for TASQ to be used as multitasking tools for bionanotechnological applications.     

Tetraphenylethene Derivatives with Different Numbers of Positively Charged Side Arms have Different Multimeric G‐Quadruplex Recognition Specificity

Some G‐rich sequences in the human genome have the potential to fold into a multimeric G‐quadruplex (G4) structure and the formation of telomeric multimeric G4 has been demonstrated. Searching for highly specific multimeric G4 ligands is important for structure probing and for study of the function of G‐rich gene sequences, as well as for the design of novel anticancer drugs. We found different numbers of positively charged side‐arm substituents confer tetraphenylethene (TPE) derivatives with different multimeric G4 recognition specificity. 1,2‐Bis{4‐[(trimethylammonium)butoxy]phenyl}‐1,2‐tetraphenylethene dibromide (DATPE), which contains two side arms and gives a fluorescence response to only multimeric G4, has a low level of cytotoxicity and little or no effect on multimeric G4 conformation or stability. These features make DATPE a promising fluorescent probe for detection of multimeric G4 specifically in biological samples or in vivo. 1,1,2,2‐Tetrakis{4‐[(trimethylammonium)butoxy]phenyl}tetraphenylethene tetrabromide (QATPE), which contains four side arms, has a lower level of specificity for multimeric G4 recognition compared to DATPE but its binding affinity to multimeric G4 is higher compared to other structural DNAs. Its high multimeric G4‐binding affinity, excellent multimeric G4‐stabilizing ability, and the promotion of parallel G4 formation make QATPE a good candidate for novel anticancer drugs targeting multimeric G4 specifically, especially telomeric multimeric G4. This work provides information that might aid the design of specific multimeric G4 probes and the development of novel anticancer drugs.