Noncovalent Helicene Structure between Nucleic Acids and Cyanuric Acid

Cyanuric acid (CA), a triazine heterocycle, is extensively utilized for noncovalent self-assembly. The association between poly(adenine) and CA into micron-length fibers was a remarkable observation made by Sleiman and co-workers, who proposed that adenine and CA adopt a hexameric rosette configuration in analogy with previously reported structures for CA assemblies. However, recent experimental observations from the Krishnamurthy group led to a reevaluation of the hexameric rosette model, wherein they have proposed a hydrogen-bonded helicene model as an alternative. Our molecular dynamics simulations show that the hexad model is indeed unlikely and that this novel noncovalent helicene geometry, where the adenine and CA bases form an extended helical hydrogen-bond network across the system, is a more probable structural motif. The existence of noncovalent helicene compounds may have wide-ranging applications in DNA nanotechnology and helicene chemistry.     

X-ray absorption spectroscopy of the nucleotide bases at the carbon, nitrogen, and oxygen K-edges

Near-edge X-ray absorption fine structure spectra of three pyrimidine (viz., cytosine, uracil, and thymine) and two purine (viz., adenine and guanine) nucleobases, which are the key constituents of DNA and RNA, were measured at the C, N, and O K-edges using the self-absorption-free partial electron yield mode. The nucleobase samples were prepared as highly pure native polycrystalline powder films. The spectra are analyzed in terms of the electronic structure of the nucleobases. Subtle chemical effects related to the molecular structures of these heterocyclic compounds with extended pi-electron systems are considered and discussed.     

Mesomorphic phases obtained through molecular recognition of complementary adenine and thymine nucleobases functionalized with long aliphatic chains

Complementary adenine and thymine nucleobases were functionalized with long aliphatic chains. The materials exhibited a mesomorphic character which was attributed to the formation of supramolecular architectures. Molecular recognition through hydrogen bonding of the complementary ends of the molecules was the driving force for their formation. It was also found that these structures are affected by the crystallization medium.     

Two-dimensional supramolecular nanopatterns formed by the coadsorption of guanine and uracil at the liquid/solid interface

A novel supramolecular nanostructure formed by the coadsorption of the complementary nucleobases guanine (G) and uracil (U) at the liquid (1-octanol solvent)/solid (graphite) interface is revealed by scanning tunneling microscopy (STM). The GU supramolecular structure is distinctly different from the structures observed by STM when the individual nucleobases (NB) are adsorbed on graphite in the control experiments. Using a systematic methodology and ab initio density functional theory (DFT), an atomistic structural model is proposed for the supramolecular coadsorbed GU structure, which consists of a periodic repetition of cyclic units based on the strongest GU base pairing.     

Nucleobases as supramolecular motifs

The five main natural nucleobases adenine, cytosine, guanine, thymine and uracil are involved in the self-assembly of one of nature's most interesting and intriguing class of biopolymers, namely the nucleic acids DNA and RNA. As such, these nucleobases have held a fascination to researchers in a diverse range of fields. With the growth in the field of supramolecular chemistry and consequently a better understanding of how molecules interact with each other, more and more information is emerging on the complex supramolecular behaviour of these nucleobase. This tutorial review tries to bring together some of the basic concepts of how nucleobases can interact not only with each other, but also with other small organic molecules as well as metals and then looks at how such an understanding is starting to influence the development of new materials and polymers.     

Mesomorphic phases obtained through molecular recognition of complementary adenine and thymine nucleobases functionalized with long aliphatic chains

Abstract

Complementary adenine and thymine nucleobases were functionalized with long aliphatic chains. The materials exhibited a mesomorphic character which was attributed to the formation of supramolecular architectures. Molecular recognition through hydrogen bonding of the complementary ends of the molecules was the driving force for their formation. It was also found that these structures are affected by the crystallization medium.     

腺嘌呤与富马酸共晶体的太赫兹光谱分析

利用太赫兹时域光谱(THz-TDS)技术在室温下对腺嘌呤、富马酸及两者的共晶体进行测量, 实验结果显示腺嘌呤与富马酸共晶体在0.92、1.24、1.52 THz处有明显的吸收峰, 与腺嘌呤和富马酸不同, 表明共晶体物相结构不同于原料. 根据腺嘌呤分子氢键供体与受体的结构特点, 使用密度泛函理论(DFT)对腺嘌呤与富马酸三种可能的共晶体结构进行模拟. 结果显示其中一种可能的共晶体结构在0.89、1.16、1.41 THz处存在特征吸收峰, 与实验结果较好吻合. 由此判断腺嘌呤与富马酸共晶体氢键形成位置为腺嘌呤的氨基与富马酸其中一个羧酸的碳氧双键形成氢键, 而此羧酸的羟基与腺嘌呤六元环上的邻位氮原子形成第二处氢键. 本文还结合理论模拟的结果对腺嘌呤与富马酸共晶体的特征吸收峰对应的相关振动模式进行了归属.     

Helical supramolecular self-assembly by prolamide thymidine/uridine analogues

This report describes the syntheses of rationally designed non-sugar nucleoside as prolamide nucleosides which contain prolyl ring and pyrimidine nucleobases (uracil/thymine) via acetamide bonds. These nucleosides have propensity to form distinctive self-assembly supramolecular helical structures ubiquitously through Watson-Crick/reverse type of hydrogen bonding with nucleobases. Moreover, the prolyl acetamide backbone groups- carbonyl (-C = O) and hydroxyl (-OH) group, are also involved in strengthening of self-assembled helical structures. Importantly, both prolamide thymidine and prolamide uridine have shown two distinctive helical structural patterns, in spite of containing the same backbone. Hence thymine and uracil moieties of prolamide nucleosides are responsible for unique supramolecular helical structural architectures.     

Electron attachment to DNA and RNA nucleobases: An EOMCC investigation

We report a benchmark theoretical investigation of both vertical and adiabatic electron affinities of DNA and RNA nucleobases: adenine, guanine, cytosine, thymine, and uracil using equation of motion coupled cluster method. The vertical electron affinity (VEA) values of the first five states of the DNA and RNA nucleobases are computed. It is observed that the first electron attached state is energetically accessible in gas phase. Furthermore, an analysis of the natural orbitals exhibits that the first electron attached states of uracil and thymine are valence‐bound in nature and undergo significant structural changes on attachment of an extra electron, which reflects in the deviation of the adiabatic electron affinity (AEA) than that of the vertical ones. Conversely, the first electron attached states of cytosine, adenine, and guanine are in the category of dipole‐bound anions. Their structure, by and large, remain unaffected on attachment of an extra electron, which is evident from the observed small difference between the AEA and VEA values. VEA and AEA values of all the DNA and RNA nucleobases are found to be negative, which implies that the first electron attached states are not stable rather quasi bound. The results of all previous theoretical calculations are out of track and shows large deviation with respect to the experimentally measured values, whereas, our results are found to be in good agreement. Therefore, our computed values can be used as a reliable standard to calibrate new theoretical methods. © 2015 Wiley Periodicals, Inc.     

Adsorption of DNA/RNA nucleobases on hexagonal boron nitride sheet: an ab initio study

Our ab initio calculations indicate that the interaction of deoxyribonucleic/ribonucleic acid (DNA/RNA) nucleobases [guanine (G), adenine (A), thymine (T), cytosine (C), and uracil (U)] with the hexagonal boron nitride (h-BN) sheet, a polar but chemically inert surface, is governed by mutual polarization. Unlike the case of graphene, all nucleobases exhibit the same stacking arrangement on the h-BN sheet due to polarization effects: the anions (N and O atoms) of nucleobases prefer to stay on top of cations (B) of the substrate as far as possible, regardless of the biological properties of nucleobases. The adsorption energies, ranging from 0.5 eV to 0.69 eV, increase in the order of U, C, T, A and G, which can be attributed to different side groups or atoms of nucleobases. The fundamental nature of DNA/RNA nucleobases and h-BN sheet remains unchanged upon adsorption, suggesting that the h-BN sheet is a promising template for DNA/RNA-related research, such as self-assembly.     

Extended Peptide Nucleic Acid Nucleobases Based on Isoorotic Acid for the Recognition of A–U Base Pairs in Double-Stranded RNA

Peptide nucleic acids (PNA) with extended isoorotamide containing nucleobases ( I _o ) were designed for binding A–U base pairs in double-stranded RNA. Isothermal titration calorimetry and UV thermal melting experiments revealed improved affinity for A–U using the Io scaffold in PNA. PNAs having four sequential Io extended nucleobases maintained high binding affinity.     

Electrocatalytic oxidation of nucleobases by TiO2 nanobelts

Two kinds of TiO(2) nanobelts were prepared from commercial P-25 powders via an alkaline hydrothermal method with and without an acid etching process. The uncauterized nanobelts (TNs) exhibited a smooth surface, and mixed phases of anatase and TiO(2) (B), whereas the cauterized ones (CTNs) displayed a rough surface and a pure anatase structure. TNs and CTNs were then deposited onto a glassy carbon electrode (GCE) surface with a conductive adhesive (CA), and the resulting chemically modified electrodes exhibited electrocatalytic activities in the oxidation of nucleobases in a 0.1 M phosphate buffer solution (PBS) at pH 7.4. For guanine and adenine, well-defined oxidation peaks were observed in voltammetric measurements at about +0.62 and +0.89 V, respectively, at a potential sweep rate of 100 mV s(-1), whereas for cytosine, uracil and thymine, the voltammetric features were not obvious. The average surface coverages (Γ) of guanine and adenine on the CTNs/CA/GCE electrode were estimated to be 4.75 × 10(-10) and 7.44 × 10(-10) mol cm(-2), respectively, which were about twice those at the TNs/CA/GCE electrode. The enhanced activity of the CTN-based electrode towards purine nucleobase oxidation was ascribed to the large specific surface area and anatase structures with enhanced (001) facets of the CTN that facilitated adsorption of the analytes onto the electrode surface and charge transport through the electrode surface layer.     

Nonempirically Tuned Range-Separated DFT Accurately Predicts Both Fundamental and Excitation Gaps in DNA and RNA Nucleobases

Using a nonempirically tuned range-separated DFT approach, we study both the quasiparticle properties (HOMO-LUMO fundamental gaps) and excitation energies of DNA and RNA nucleobases (adenine, thymine, cytosine, guanine, and uracil). Our calculations demonstrate that a physically motivated, first-principles tuned DFT approach accurately reproduces results from both experimental benchmarks and more computationally intensive techniques such as many-body GW theory. Furthermore, in the same set of nucleobases, we show that the nonempirical range-separated procedure also leads to significantly improved results for excitation energies compared to conventional DFT methods. The present results emphasize the importance of a nonempirically tuned range-separation approach for accurately predicting both fundamental and excitation gaps in DNA and RNA nucleobases.     

Calix[6]arene acetic acid extraction behavior and specificity with respect to nucleobases

The extraction behavior of various nucleobases was investigated with a series of calixarene derivatives. A calix[6]arene acetic acid was found to extract around 80% of adenine from an aqueous phase, and showed the highest specificity for adenine among all the nucleobases tested. The important factors influencing the recognition properties of calixarene were discovered to be its cyclic structure, its cavity size, and the functional carboxylic acid groups. The carbonyl group and the position of the amino group in the guest molecules also affect the extraction efficiency. Calix[6]arene forms a stable 1:1 complex with adenine by entrapping it into the cavity. Adenine was readily recovered from the organic phase by contacting with a fresh acidic solution.     

One-dimensional oxalato-bridged Cu(II), Co(II), and Zn(II) complexes with purine and adenine as terminal ligands

The reaction of nucleobases (adenine or purine) with a metallic salt in the presence of potassium oxalate in an aqueous solution yields one-dimensional complexes of formulas [M(mu-ox)(H(2)O)(pur)](n) (pur = purine, ox = oxalato ligand (2-); M = Cu(II) [1], Co(II) [2], and Zn(II) [3]), [Co(mu-ox)(H(2)O)(pur)(0.76)(ade)(0.24)](n)(4) and ([M(mu-ox)(H(2)O)(ade)].2(ade).(H(2)O))(n) (ade = adenine; M = Co(II) [5] and Zn(II) [6]). Their X-ray single-crystal structures, variable-temperature magnetic measurements, thermal behavior, and FT-IR spectroscopy are reported. The complexes 1-4 crystallize in the monoclinic space group P2(1)/a (No. 14) with similar crystallographic parameters. The compounds 5 and 6 are also isomorphous but crystallize in the triclinic space group P (No. 2). All compounds contain one-dimensional chains in which cis-[M(H(2)O)(L)](2+) units are bridged by bis-bidentate oxalato ligands with M(.)M intrachain distances in the range 5.23-5.57 A. In all cases, the metal atoms are six-coordinated by four oxalato oxygen atoms, one water molecule, and one nitrogen atom from a terminal nucleobase, building distorted octahedral MO(4)O(w)N surroundings. The purine ligand is bound to the metal atom through the most basic imidazole N9 atom in 1-4, whereas in 5 and 6 the minor groove site N3 of the adenine nucleobase is the donor atom. The crystal packing of compounds 5 and 6 shows the presence of uncoordinated adenine and water crystallization molecules. The cohesiveness of the supramolecular 3D structure of the compounds is achieved by means of an extensive network of noncovalent interactions (hydrogen bonds and pi-pi stacking interactions). Variable-temperature magnetic susceptibility measurements of the Cu(II) and Co(II) complexes in the range 2-300 K show the occurrence of antiferromagnetic intrachain interactions.     

核酸碱基互变异构体的结构、稳定性及其物理化学性质

核酸碱基是DNA及RNA分子的重要组成部分, 在基因遗传信息的传递方面起着主导作用. 核酸碱基存在多种互变异构体, 它们在DNA及RNA分子中主要以最稳定的异构体形式存在, 但是在气相或凝聚相中也有少量的其他异构体形式存在. 核酸碱基的稀有互变异构体往往能够引起碱基对的错配对, 这可能会导致DNA及RNA分子形成不规则的结构, 并进一步导致DNA或RNA双螺旋的自发突变. 因此, 对核酸碱基的互变异构体进行系统的研究, 有助于人们深入认识DNA和RNA分子的结构和性质. 国际上有很多研究小组已经通过实验和理论对核酸碱基互变异构体的结构、相对能量及其性质进行了研究. 本文对文献中有关核酸碱基互变异构体的实验和理论研究进行了综述. 在对前人研究进行归纳总结的基础上, 我们利用密度泛函计算对核酸碱基的互变异构体进行了排序, 得到的最优异构体结构参数和相对能量与实验值相比较为一致. 此外, 因为核酸碱基的物理化学性质可以为生物、化学、材料等方面的研究提供重要的基础性信息, 因此我们还对它们的电子亲和能、电离能、质子亲和能等研究进行了总结.     

Spatial,Hysteretic, and Adaptive Host–Guest Chemistry in a Metal–Organic Framework with Open Watson–Crick Sites

Biological and artificial molecules and assemblies capable of supramolecular recognition, especially those with nucleobase pairing, usually rely on autonomous or collective binding to function. Advanced site‐specific recognition takes advantage of cooperative spatial effects, as in local folding in protein–DNA binding. Herein, we report a new nucleobase‐tagged metal–organic framework (MOF), namely ZnBTCA (BTC=benzene‐1,3,5‐tricarboxyl, A=adenine), in which the exposed Watson–Crick faces of adenine residues are immobilized periodically on the interior crystalline surface. Systematic control experiments demonstrated the cooperation of the open Watson–Crick sites and spatial effects within the nanopores, and thermodynamic and kinetic studies revealed a hysteretic host–guest interaction attributed to mild chemisorption. We further exploited this behavior for adenine–thymine binding within the constrained pores, and a globally adaptive response of the MOF host was observed.     

Spatial,Hysteretic, and Adaptive Host–Guest Chemistry in a Metal–Organic Framework with Open Watson–Crick Sites

Biological and artificial molecules and assemblies capable of supramolecular recognition, especially those with nucleobase pairing, usually rely on autonomous or collective binding to function. Advanced site‐specific recognition takes advantage of cooperative spatial effects, as in local folding in protein–DNA binding. Herein, we report a new nucleobase‐tagged metal–organic framework (MOF), namely ZnBTCA (BTC=benzene‐1,3,5‐tricarboxyl, A=adenine), in which the exposed Watson–Crick faces of adenine residues are immobilized periodically on the interior crystalline surface. Systematic control experiments demonstrated the cooperation of the open Watson–Crick sites and spatial effects within the nanopores, and thermodynamic and kinetic studies revealed a hysteretic host–guest interaction attributed to mild chemisorption. We further exploited this behavior for adenine–thymine binding within the constrained pores, and a globally adaptive response of the MOF host was observed.     

Preparation of supramolecular chromophoric assemblies using a DNA duplex

Organization of supramolecular assemblies of chromophores with precisely-controlled orientation and sequence remains challenging. Nucleic acids with complementary base sequences spontaneously form double-helical structures. Therefore, covalent attachment of chromophores to DNA or RNA can be used to control assembly and orientation of chromophores. In this perspective, we first review our recent work on the assemblies of fluorophores (pyrene and perylene) by using natural base pairs. The interaction between dyes can be strictly controlled by means of cluster and interstrand wedge motifs. We then discuss novel artificial base pairs that can suppress the interaction between fluorophores and nucleobases. We incorporated a cyclohexane moiety into DNA, and showed that these artificial base pairs suppressed the electron-hole transfer between fluorophores and nucleobases and enhanced the quantum yields of fluorophores. These base pairs can potentially be used to accumulate fluorophores inside DNA duplexes without decreasing quantum yields.     

Gas-Phase Hydration Thermochemistry of Sodiated and Potassiated Nucleic Acid Bases

Hydration reactions of sodiated and potassiated nucleic acid bases (uracil, thymine, cytosine, and adenine) produced by electrospray have been studied in a gas phase using the pulsed ion-beam high-pressure mass spectrometer. The thermochemical properties, ΔH ( o ) ( n ), ΔS ( o ) ( n ), and ΔG ( o ) ( n ), for the hydrated systems were obtained from hydration equilibrium measurement. The structural aspects of the hydrated complexes are discussed in conjunction with available literature data. The correlation between water binding energies in the hydrated complexes and the corresponding metal ion affinities of nucleobases suggests that a significant (if not dominant) amount of the canonical structure of cytosine undergoes tautomerization during electrospray ionization, and the thermochemical values for cationized cytosine probably correspond to a mixture of tautomeric complexes.