Base Flip in DNA Studied by Molecular Dynamics Simulations of Differently-Oxidized Forms of Methyl-Cytosine

Distortions in the DNA sequence, such as damage or mispairs, are specifically recognized and processed by DNA repair enzymes. Many repair proteins and, in particular, glycosylases flip the target base out of the DNA helix into the enzyme’s active site. Our molecular dynamics simulations of DNA with intact and damaged (oxidized) methyl-cytosine show that the probability of being flipped is similar for damaged and intact methyl-cytosine. However, the accessibility of the different 5-methyl groups allows direct discrimination of the oxidized forms. Hydrogen-bonded patterns that vary between methyl-cytosine forms carrying a carbonyl oxygen atom are likely to be detected by the repair enzymes and may thus help target site recognition.     

Base‐Pairing Behavior of a Carbocyclic Janus‐AT Nucleoside Analogue Capable of Recognizing A and T within a DNA Duplex

Janus‐type nucleosides are heterocycles with two faces, each of which is designed to complement the H‐bonding interactions of natural nucleosides comprising a canonical Watson–Crick base pair. By intercepting all of the hydrogen bonds contained within the base pair, oligomeric Janus nucleosides are expected to achieve sequence‐specific DNA recognition through the formation of J‐loops that will be more stable than D‐loops, which simply replaces one base‐pair with another. Herein, we report the synthesis of a novel Janus‐AT nucleoside analogue, J_AT, affixed on a carbocyclic analogue of deoxyribose that was converted to the corresponding phosphoramidite. A single J_AT was successfully incorporated into a DNA strand by solid phase for targeting both A and T bases, and characterized through biophysical and computational methods. Experimental UV‐melting and circular dichroism data demonstrated that within the context of a standard duplex, J_AT associates preferentially with T over A, and much more poorly with C and G. Density functional theory calculations confirm that the J_AT structure is well suited to associate only with A and T thereby highlighting the importance of the electronic structure in terms of H‐bonding. Finally, molecular dynamics simulations validated the observation that J_AT can substitute more effectively as an A‐analogue than as a T‐analogue without substantial distortion of the B‐helix. Overall, this new Janus nucleotide is a promising tool for the targeting of A–T base pairs in DNA, and will lead to the development of oligo‐Janus‐nucleotide strands for sequence‐specific DNA recognition.     

An Isocytidine Derivative with a 2‐Amino‐6‐methylpyridine Unit for Selective Recognition of the CG Interrupting Site in an Antiparallel Triplex DNA

Sequence‐specific recognition of duplex DNA mediated by triple helix formation offers a potential basis for oligonucleotide therapy and biotechnology. However, triplex formation is limited mostly to homopurine strands, due to poor stabilization at CG or TA base pairs in the target duplex DNA sequences. Several non‐natural nucleosides have been designed for the recognition of CG or TA base pairs within an antiparallel triplex DNA. Nevertheless, problems including low selectivity and high dependence on the neighboring bases remain unsolved. We thus synthesized N²‐arylmethyl isodC derivatives and incorporated them into triplex‐forming oligonucleotides (TFOs) for the selective recognition of the CG base pair within antiparallel triplex DNA. It was shown that an isodC derivative bearing a 2‐amino‐6‐methylpyridine moiety (AP‐isodC) recognizes the CG base pair with high selectivity in antiparallel triplex DNA irrespective of the flanking base pairs.     

Stereospecific Effects of Oxygen‐to‐Sulfur Substitution in DNA Phosphate on Ion Pair Dynamics and Protein–DNA Affinity

Oxygen‐to‐sulfur substitutions in DNA phosphate often enhance affinity for DNA‐binding proteins. Our previous studies have suggested that this effect of sulfur substitution of both O_P1 and O_P2 atoms is due to an entropic gain associated with enhanced ion pair dynamics. In this work, we studied stereospecific effects of single sulfur substitution of either the O_P1 or O_P2 atom in DNA phosphate at the Lys57 interaction site of the Antennapedia homeodomain–DNA complex. Using crystallography, we obtained structural information on the R_P and S_P diastereomers of the phosphoromonothioate and their interaction with Lys57. Using fluorescence‐based assays, we found significant affinity enhancement upon sulfur substitution of the O_P2 atom. Using NMR spectroscopy, we found significant mobilization of the Lys57 side‐chain NH₃⁺ group upon sulfur substitution of the O_P2 atom. These data provide further mechanistic insights into the affinity enhancement by oxygen‐to‐sulfur substitution in DNA phosphate.     

低燃速低燃温双基推进剂燃烧性能的调节

为调节低燃速燃温双基推进剂的燃烧性能(燃速及压强指数)，探索铅、铜盐和碳黑等燃烧催化剂在该类推进剂中的催化效果，从理论燃温在900～1700K的低燃速双基推进剂中选出4种作为基础配方，分别加入不同种类的铅盐、铜盐及碳黑等燃烧催化剂，改变催化剂的加入量及搭配关系，进行了一系列试验研究。同时还研究了辅助增塑剂对推进剂燃烧性能的影响。结果表明，常规的铅、铜盐和碳黑等催化剂在低燃速低燃温推进剂中仍能发挥催化作用，作用效果与催化剂的品种及加入量相关，特别是使用复合催化剂时，对燃烧性能的调节更为有效。不同品种的辅助增塑剂对燃烧性能也有影响。     

The CAR–mRNA Interaction Surface Is a Zipper Extension of the Ribosome A Site

The ribosome CAR interaction surface behaves as an extension of the decoding center A site and has H-bond interactions with the +1 codon, which is next in line to enter the A site. Through molecular dynamic simulations, we investigated the codon sequence specificity of this CAR–mRNA interaction and discovered a strong preference for GCN codons, suggesting that there may be a sequence-dependent layer of translational regulation dependent on the CAR interaction surface. Dissection of the CAR–mRNA interaction through nucleotide substitution experiments showed that the first nucleotide of the +1 codon dominates over the second nucleotide position, consistent with an energetically favorable zipper-like activity that emanates from the A site through the CAR–mRNA interface. Moreover, the CAR/+1 codon interaction is affected by the identity of nucleotide 3 of +1 GCN codons, which influences the stacking of G and C. Clustering analysis suggests that the A-site decoding center adopts different neighborhood substates that depend on the identity of the +1 codon.     

The Effect of C-Terminal Helix on the Stability of FF Domain Studied by Molecular Dynamics Simulation

To investigate the effect of C-terminal helix on the stability of the FF domain, we studied the native domain FF3-71 from human HYPA/FBP11 and the truncated version FF3-60 with C-terminal helix being deleted by molecular dynamics simulations with GROMACS package and GROMOS 43A1 force field. The results indicated that the structures of truncated version FF3-60 were evident different from those of native partner FF3-71. Compared with FF3-71, the FF3-60 lost some native contacts and exhibited some similar structural characters to those of intermediate state. The C-terminal helix played a major role in stabilizing the FF3-71 domain. To a certain degree, the FF domain had a tendency to form an intermediate state without the C-terminal helix. In our knowledge, this was the first study to examine the role of C-terminal helix of FF domain in detail by molecular dynamics simulations, which was useful to understand the three-state folding mechanism of the small FF domain.     

Mechanism‐Based Inhibitor of DNA Cytosine‐5 Methyltransferase by a SNAr Reaction with an Oligodeoxyribonucleotide Containing a 2‐Amino‐4‐Halopyridine‐C‐Nucleoside

In chromatin, 5‐methylcytosine (mC), which represents the fifth nucleobase in genomic DNA, plays a role as an inducer of epigenetic changes. Tumor cells exhibit aberrant DNA methylation patterns, and inhibition of human DNA cytosine‐5 methyltransferase (DNMT), which is responsible for generating mC in CpG sequences, is an effective strategy to treat various cancers. Here, we describe the design, synthesis, and evaluation of the properties of 2‐amino‐4‐halopyridine‐C‐nucleosides (d^XP) and oligodeoxyribonucleotides (ODNs) containing d^XP as a novel mechanism‐based inhibitor of DNMTs. The designed ODN containing ^XPpG forms a complex with DNMTs by covalent bonding through a nucleophilic aromatic substitution (S_NAr) reaction, and its cell proliferation activity is investigated. This study suggests that d^XP in a CpG sequence of DNA could serve as a potential nucleic acid drug lead in cancer chemotherapy and a useful chemical probe for studies of epigenetics. Our molecular design using a S_NAr reaction would be useful for DNMTs and other protein–DNA interactions.     

Synthesis of cytidine ribonucleotides by stepwise assembly of the heterocycle on a sugar phosphate

Although various syntheses of the nucleic acid bases exist and ribose is a product of the formose reaction, no prebiotically plausible methods for attaching pyrimidine bases to ribose to give nucleosides have been described. Kinetic and thermodynamic factors are thought to mitigate against such condensation reactions in aqueous solution. This inability to produce pyrimidine nucleosides and hence nucleotides is a major stumbling block of the "RNA World" hypothesis and has led to suggestions of alternative nucleic acids as evolutionary precursors to RNA. Here, we show that a process in which the base is assembled in stages on a sugar phosphate can produce cytidine nucleotides. The sequential action of cyanamide and cyanoacetylene on arabinose-3-phosphate produces cytidine-2',3'-cyclophosphate and arabinocytidine-3'-phosphate.     

Synthesis of C8‐N‐Arylamine‐Modified 2′‐Deoxyguanosine‐5′‐Triphosphates and Their Effects on Primer Extension by DNA Polymerases

C8‐N‐arylamine adducts of 2′‐deoxyguanosine (2′‐dG) play an important role in the induction of the chemical carcinogenesis caused by aromatic amines. C8‐N‐acetyl‐N‐arylamine dG adducts that differ in their substitution pattern in the aniline moiety were converted by cycloSal technology into the corresponding C8‐N‐acetyl‐N‐arylamine‐2′‐deoxyguanosine‐5′‐triphosphates and C8‐NH‐arylamine‐2′‐deoxyguanosine‐5′‐triphosphates. Their conformation preference has been investigated by NOE spectroscopy and DFT calculations. The substrate properties of the C8‐dG adducts were studied in primer‐extension assays by using Klenow fragment exo^? of Escherichia coli DNA polymerase I and human DNA polymerase β. It was shown that the incorporation was independent of the substitution pattern in the aryl moiety and the N‐acetyl group. Although the triphosphates were poor substrates for the human polymerases, they were incorporated twice before the termination of the elongation process occurred; this might demonstrate the importance of C8‐N‐arylamine‐2′‐deoxyguanosine‐5′‐triphosphates in chemical carcinogenesis.     

Molecular Design of an Environmentally Sensitive Fluorescent Nucleoside, 3‐Deaza‐2′‐Deoxyadenosine Derivative: Distinguishing Thymine by Probing the DNA Minor Groove

An environmentally sensitive fluorescent nucleoside containing a 3‐deazaadenine skeleton has been developed, and its photophysical properties were investigated. Newly developed C3‐naphthylethynylated 3‐deaza‐2′‐deoxyadenosine (^3nzA, 1 ) exhibited dual fluorescence emission from an intramolecular charge‐transfer state and a locally excited state, depending upon molecular coplanarity. DNA probes containing 1 clearly discriminated a perfectly matched thymine base on the complementary strand by a distinct change in emission wavelength.     

The role of interfacial interactions on the crystallinity and nanomechanical properties of clay–polymer nanocomposites: A molecular dynamics study

Polymer clay nanocomposites (PCN) show enhanced mechanical, thermal, liquid or gas barrier properties in comparison to pure polymer. However, the mechanisms for enhancement of these physical properties of PCN are not well understood. This knowledge is important for tailoring the properties of PCN to desired specifications. Our earlier study showed that organic modifiers have significant influence on the crystallinity and nanomechanical properties of PCN. For quantitative evaluation of the influence of organic modifiers on the crystallinity and nanomechanical properties of PCN, molecular models of three intercalated PCNs containing same polymer and clay but with three different organic modifiers are constructed in this work. Using molecular dynamics simulations, the interaction energies among the different constituents of PCNs are evaluated. This study reveals that the interactions between polymer, organic modifiers, and intercalated clay are critical factors in controlling the crystallinity and enhancement of nanomechanical properties of PCN. We have described the possible mechanisms leading to change in crystallinity and nanomechanical properties. © 2007 Wiley Periodicals, Inc. J Appl Polym Sci, 2008     

Assessing Carbohydrate–Carbohydrate Interactions by NMR Spectroscopy: The Trisaccharide Epitope from the Marine Sponge Microciona prolifera

Weak recognition processes : Weak calcium‐mediated carbohydrate–carbohydrate interactions have been detected by DOSY and TRNOESY NMR methods by employing a gold glyconanoparticle as a multivalent system. In addition, 3D models of trisaccharide‐Ca^II‐trisaccharide complexes based on results from molecular dynamics simulations are proposed.

     

The ATP/ADP Substrate Specificity Switch between Toxoplasma gondii NTPDase1 and NTPDase3 is Caused by an Altered Mode of Binding of the Substrate Base

Two nucleoside triphosphate diphosphohydrolase isoforms (NTPDase1 and NTPDase3) are responsible for the hydrolysis of nucleotides by the intracellular protozoan Toxoplasma gondii. They constitute about 3 % of the total parasite protein. Despite sharing 97 % sequence identity they exhibit opposite ATP versus ADP substrate discrimination ratios. Here we show by mutagenesis that the residues G492/G493 in NTPDase3 and R492/E493 in NTPDase1 are predominantly responsible for the differences in substrate specificity. Crystal structures of NTPDase1 in complexation with analogues of ATP and ADP reveal that the inverted substrate specificity of NTPDase1 relative to NTPDase3 is achieved by switching from the canonical substrate binding mode to a very different alternative one. Instead of being stacked on top of a helix of the C‐terminal domain the nucleotide base is positioned in the interdomain space between the side chains of R108 and R492, recruited from both domains. Furthermore, we show that the NTPDase1 substrate specificity is mainly dependent on the presence of the side chain of E493, which causes repositioning of the ribose component of the nucleotide. All in all, binding by the flexible side chains in the alternative binding mode in NTPDase1 allows for equally good positioning of ATP and ADP with increased activity toward ADP relative to what is seen in the case of NTPDase3.     

Influence of the Nucleophile on the Candida antarctica Lipase B‐Catalysed Resolution of a Chiral Acyl Donor

The resolution of methyl (±)‐3‐hydroxypentanoate catalysed by Candida antarctica lipase B has been performed by using ammonia and benzyl amine as nucleophiles. In all cases, the lipase reacts faster with the R enantiomer of the ester, but when benzyl amine is used, the enantiomeric ratio is approximately three times as high as that measured for ammonia. The analysis of the molecular dynamics simulations carried out over the corresponding deacylation transition state analogues indicated specular binding modes between enantiomers that vary greatly upon the nucleophile used. For the case of ammonia, an intramolecular hydrogen bond between the β‐hydroxyl group and the protons of the nucleophile is established. However, the presence of the substituent in benzyl amine disrupts this interaction. Instead, the acyl chain binds to a more restrictive area of the protein where the higher number of contacts established with the side chains of Thr40, Gln157 and Ile189 have been identified as the reason for the higher enantioselectivity observed in the aminolysis reaction.