Enzymatic sequence-specific spin labeling of a DNA fragment containing the recognition sequence of EcoRI endonuclease

Deoxyuridine analogs spin labeled in position 5 have been enzymatically incorporated sequence specifically into an oligodeoxyribonucleotide to form a spin-labeled 26-mer. The 26-mer contains the EcoRI-binding site and two labels which are located symmetrically close to the binding site. The labels are separated from one another far beyond the Heisenberg spin-exchange distance. The local base motion as determined by ESR spectroscopy is of the order of 4 ns in the oligonucleotide duplex. This is the same value as reported earlier for local T motions in polynucleotide duplexes, thereby providing direct experimental evidence that the ESR line shape of spin levels covalently attached to nucleic acids depends primarily on the local dynamics of the nucleic acid building blocks.     

不同G的四链体结构对DNAzyme活性的影响

富含鸟嘌呤的DNA序列在金属离子（通常是钠、钾离子）存在的条件下,可以形成稳定的G-四链体（G-quadruplex）。该G 四链体能够结合hemin（氯高铁血红素）形成具有过氧化物酶的活性的G四链体-hemin复合物DNAzyme。将这一原理联合滚环扩增技术可以对核酸进行可视化的检测。本研究旨在探索G-四链体-hemin复合物中,G-四链体结构以及两个G-四链体之间的链接长度与DNAzyme过氧化物酶活性之间的关系。实验分别选取了平行、反平行和混合结构的G-四链体,通过热差异光谱、紫外光谱、圆二色光谱对结构进行分析,不断加长链接序列并测定3种结构形成的DNAzyme活性,发现正平行结构的G-四链体具有更高的DNAzyme活性和更明显的可视化效果。综上所述,平行G-四链体结构可以用来满足裸眼可视化检测的需求,为无需复杂仪器的核酸检测奠定了方法基础。     

Influence of the incorporation of a cyclohexenyl nucleic acid (CeNA) residue onto the sequence d(CGCGAATTCGCG)

Cyclohexene nucleic acids (CeNA), which are characterized by the presence of a cyclohexene moiety instead of a natural (deoxy)ribose sugar, are known to increase the thermal and enzymatic stability when incorporated in RNA oligonucleotides. As it has been demonstrated that even a single cyclohexenyl nucleoside, when incorporated in an oligonucleotide, can have a profound effect on the biological activity of the oligonucleotide, further research is warranted to study the complex of such oligonucleotides with target proteins. In order to analyse the influence of CeNA residues onto the helix conformation and hydration of natural nucleic acid structures, a cyclohexenyl-adenine building block (xAr) was incorporated into the Dickerson sequence CGCGA(xAr)TTCGCG. The crystal structure of this sequence determined to a resolution of 1.90 Å. The global helix belongs to the B-type family and shows a water spine, which is partially broken up by the apolar cyclohexene residue. The cyclohexene ring adopts the ²E-conformation allowing a better incorporation of the residue in the dodecamer sequence. The crystal packing is stabilized by cobalt hexamine residues and belongs to space group P222₁, never before reported for nucleic acids.     

同步辐射圆二色谱及其在糖生物学及生物分子中的应用

同步辐射圆二色谱与普通圆二色谱相比,特点在于向真空紫外波段（〈200nm）拓展,以及同步辐射所提供的高强度紫外和真空紫外光源。糖的圆二色谱结构主要在200nm以下。蛋白质和核酸在200nm以下的真空紫外范围,也具有丰富的光谱结构。因此向真空紫外拓展,伴随新的电子跃迁,对应新的光谱结构,包含更丰富的结构信息,确定的结构种类就越多和越精确。同步辐射高强度的真空紫外光源,是获得高质量真空紫外圆二色谱数据的保证,为糖及糖蛋白、蛋白质和核酸研究提供了溶液中结构探测新的实验方法。综述同步辐射圆二色谱特点及其在结构生物学中的应用,以及新发展的蛋白质圆二色谱数据库（PCDDB）。介绍已对外开放的北京同步辐射实验室同步辐射圆二色谱探测,及其在蛋白质、糖和核酸研究中的应用,以及基于微流控混合芯片的亚毫秒动态探测发展。     

Recognition schemes for protein-nucleic acid interactions

The molecular forces involved in protein-nucleic acid interaction are electrostatic, stacking and hydrogen-bonding. These interactions have a certain amount of specificity due to the directional nature of such interactions and the spatial contributions of the steric effects of different substituent groups. Quantum chemical calculations on these interactions have been reported which clearly bring out such features. While the binding energies for electrostatic interactions are an order of magnitude higher, the differences in interaction energies for structures stabilised by hydrogen-bonding and stacking are relatively small. Thus, the molecular interactions alone cannot explain the highly specific nature of binding observed in certain segments of proteins and nucleic acids. It is therefore logical to assume that the sequence dependent three dimensional structures of these molecules help to place the functional groups in the correct geometry for a favourable interaction between the two molecules. We have carried out 2D-FT nuclear magnetic resonance studies on the oligonucleotide d-GGATCCGGATCC. This oligonucleotide sequence has two binding sites for the restriction enzyme Bam H1. Our studies indicate that the conformation of this DNA fragment is predominantly B-type except near the binding sites where the ribose ring prefers a³E conformation. This interesting finding raises the general question about the presence of specificity in the inherent backbone structures of proteins and nucleic acids as opposed to specific intermolecular interactions which may induce conformational changes to facilitate such binding.     

Characterization of the nucleic acid-binding activities of the isolated amino-terminal head domain of the intermediate filament protein vimentin reveals its close relationship to the DNA-binding regions of some prokaryotic single-stranded DNA-binding proteins.

In order to demonstrate that the nucleic acid-binding activities of vimentin are dictated by its Arg-rich N-terminal head domain, this was cut off at position Lys96 with lysine-specific endoproteinase and analysed for its capacity to associate with a variety of synthetic and naturally occurring nucleic acids. The isolated polypeptide (vim NT) showed a preference for single-stranded (ss) polynucleotides, particularly for ssDNAs of high G-content. A comparison of the sequence and predicted secondary structure of vim NT with that of two prokaryotic ssDNA-binding proteins, G5P and G32P of bacteriophages fd and T4, respectively, revealed that the nucleic acid-binding region of all three polypeptides is almost entirely in the beta-conformation and characterized by a very similar distribution of aromatic amino acid residues. A partial sequence of vim NT can be folded into the same beta-loop structure as the DNA-binding wing of G5P of bacteriophage fd and related viruses. As in the case of G5P, nitration of the Tyr residues with tetranitromethane was blocked by single-stranded nucleic acids. This and spectroscopic data indicate intercalation of the Tyr aromatic ring systems between the bases of the nucleic acids and thus the contribution of a stacking component to the binding reaction. The binding was accompanied by significant changes in the ultraviolet absorption spectra of both vim NT and single-stranded nucleic acids. Upon mixing of vim NT with nucleic acids, massive precipitation of the reactants occurred, followed by the quick rearrangement of the aggregates with the formation of specific and soluble association products. Even at very high ionic strengths, at which no electrostatic reaction should be expected, a distinct fraction of vim NT incorporated naturally occurring ssRNAs and ssDNAs into fast sedimenting complexes, suggesting co-operative interaction of the polypeptide with the nucleic acids. In electron microscopy, the complexes obtained from 28 S rRNA appeared as networks of extended nucleic acid strands densely covered with vim NT, in contrast to the compact random coils of uncomplexed RNA. The networks produced from fd DNA were heterogeneous in appearance and their nucleoprotein strands in rare cases were very similar to the rod-like structures of G5P-fd DNA complexes.     

Structural analysis of nucleic acids by labeled oligonucleotides

In this report, the characterization of labeled oligonucleotides was discussed from the view points of base sequence analysis and structural analysis of nucleic acids in solution. Oligonucleotides site specifically spin labeled with TEMPO and fluorescent labeled with fluorescein were prepared and used for those analyses. The changes of ESR lines and rotational correlation time (tau) of the spin labeled oligonucleotide (S-probe) were dependent on the base sequence of S-probe, diastereoisomers, and the manner of hybridization. These results suggest that the conformation of the hybrid largely affected the local mobility of TEMPO and that tau value of S-probe reflected the local structure of the hybrid. When S-probe which was complementary to a single strand region of 5S RNA, was mixed with 5S RNA, tau value largely changed, indicating that the S-probe could form hybrid with 5S RNA in solution. Similar results were also obtained in the fluorescence depolarization analysis using fluorescent labeled oligonucleotide (F-probe). These results suggest that S-probe and F-probe are capable for the recognition of the secondary structure of 5S RNA in solution and useful for the analysis of the secondary structure of other nucleic acids in solution.     

The 16S rRNA nucleotide sequence of Mycobacterium leprae: phylogenetic position and development of DNA probes

The almost complete 16S rRNA sequence from Mycobacterium leprae was determined by direct sequencing of the chromosomal gene amplified by the polymerase chain reaction. The primary sequence revealed an insertion of 12 nucleotides at the 5' end of the 16S rRNA gene, which consists of an A-T stretch and appears to be unique for M. leprae. Within the mycobacteria M. leprae branches off with a group of slow-growing species comprising M. scrofulaceum, M. kansasii, M. szulgai, M. malmoense, M. intracellulare and M. avium. A systematic comparison of the nucleotide sequence resulted in the characterization of oligonucleotide probes which are highly specific for M. leprae. The probes hybridized exclusively to 16S rRNA nucleic acids from M. leprae, but not to nucleic acids from 20 cultivable fast- and slow-growing mycobacteria.     

A simple nucleic acid hybridization/latex agglutination assay for the rapid detection of polymerase chain reaction amplicons

We have developed a new method for the detection of nucleic acid hybridization, based on a simple latex agglutination test that can be evaluated by the unaided eye. Nucleic acid, e.g., a polymerase chain reaction (PCR) product, is denatured and incubated with polystyrene beads carrying covalently bound complementary oligonucleotide sequences. Hybridization of the nucleic acids leads to aggregation of the latex particles, thereby verifying the presence of target sequence. The test is performed at room temperature, and results are available within 10 min. As a proof of principle, the hybridization/latex agglutination assay was applied to the detection of purified PCR fragments either specific for Salmonella spp. or a synthetic sequence, and to the detection of Salmonella enterica in artificially contaminated chicken samples. A few nanograms of purified PCR fragments were detectable. In artificially contaminated chicken samples, 3 colony-forming units (cfu)/25 g were detected in one of three replicates, and 30 cfu/25 g were detected in both of two replicates when samples for PCR were taken directly from primary enrichment, demonstrating the practical applicability of this test system. Even multiplex detection might be achievable. This novel kind of assay could be useful for a range of applications where hybridization of nucleic acids, e.g., PCR fragments, is to be detected.     

NMR studies of dynamics in RNA and DNA by 13C relaxation

RNA and DNA molecules experience motions on a wide range of time scales, ranging from rapid localized motions to much slower collective motions of entire helical domains. The many functions of RNA in biology very often require this molecule to change its conformation in response to biological signals in the form of small molecules, proteins or other nucleic acids, whereas local motions in DNA may facilitate protein recognition and allow enzymes acting on DNA to access functional groups on the bases that would otherwise be buried in Watson-Crick base pairs. Although these statements make a compelling case to study the sequence dependent dynamics in nucleic acids, there are few residue-specific studies of nucleic acid dynamics. Fortunately, NMR studies of dynamics of nucleic acids and nucleic acids-protein complexes are gaining increased attention. The aim of this review is to provide an update of the recent progress in studies of nucleic acid dynamics by NMR based on the application of solution relaxation techniques.     

Interactions of the 26-39 fragment of the cro protein from lambda bacteriophage with nucleic acids

A tetradecapeptide with a sequence identical to residues 26-39 of the cro protein from bacteriophage lambda has been synthesized. This peptide has no secondary structure in an aqueous buffer but adopts an alpha-helical conformation in the presence of 20% hexafluoroisopropanol. The fluorescence of the single tyrosyl residue of the cro protein fragment is quenched upon binding to nucleic acids. Proton magnetic resonance has been used to investigate complex formation of the cro protein fragment with a self-complementary decadeoxynucleotide d(AATTGCAATT). Changes in resonance positions and linewidths have been observed for both partners in the 4 complexes which are obtained when either the single-stranded or double-stranded oligonucleotide is mixed with either the random coil or the alpha-helical peptide. These studies are presently extended to the specific complex formed by the cro protein fragment with the OR3 operator sequence.     

DNA conformation and dynamics

Nucleotide conformation and dynamics are important for the study of radiation damage to DNA at the atomic level. It is necessary to study not only normal oligonucleotide structure but also those containing modified bases which result from interaction with OH-radicals. There are now over 8000 atomic coordinate entries in the Brookhaven Protein Data Bank, of which over 900 relate to experimentally determined structures of nucleic acids and nucleic acid/protein complexes. We review some of these data which have led to the elucidation of novel DNA conformations, insight into DNA sequence specificity and knowledge of protein/DNA interactions. Further understanding of the conformation, stability and dynamics of nucleic acids has come from molecular modelling. We have used such techniques to study chemical modifications to bases such as alkylation of thymine and guanine and the effects of curvature in longer sequences. Recent improvements in this area include the inclusions of explicit counter-ions and solvent molecules, the use of Particle Mesh Ewald methods to incorporate the long-range electrostatic interactions and the use of longer time scale simulations. We have employed these methods to analyse the effects of incorporation of 8-oxodeoxyguanosine into duplex DNA. This lesion is a common result of radiation damage and is known to have important effects in mutagenesis, cancer and ageing. Received: 7 October 1998 / Accepted in revised form: 18 January 1999     

Synthesis of protein, nucleosides and other organic compounds from cyanamide and potassium nitrite under possible primitive earth conditions.

The mixing of cyanamide and KNO2 produced changes from white solids to yellow liquid and then to orange solid. The gases cyanogen and ammonia were formed. No external energy was used. The reactions were carried out with a small amount of O2. The presence of proteins in the reaction product formed 13 months after the mixing was indicated by the positive reactions of the cyanamide-KNO2 reaction product with ninhydrin, microbiuret, and Folin reagent; the ultraviolet absorption at about 280 nm; the yield of 24% of 15 amino acids; and molecular weight measurements of more than 160,000. The presence of nucleosides, nucleic acid bases, hydrocarbons, and organic esters in the reaction product formed 2 months after the mixing was indicated by ultraviolet absorption at about 260 nm, and the results of ligand-exchange chromatography, paper chromatography, infrared analysis, mass spectral analysis, and NMR spectroscopy. Possible cyanamide-mediated dehydration reactions and mechanisms are discussed.     

Peptide nucleic acid-assisted topological labeling of duplex dna

Peptide nucleic acids (PNAs) are a family of synthetic polyamide mimics of nucleic acids that offer a variety of applications. Pyrimidine bis-PNAs can be used for rational design of novel interlocked DNA nanostructures, earring labels, representing locked pseudorotaxanes or locked catenanes. These structures are created through DNA ligase-mediated catenation of duplex DNA with a circularized oligonucleotide tag at a designated DNA site. The assembly is performed via formation of the PD-loop consisting of a pair of bis-PNA openers and the probe oligonucleotide. The openers locally expose one of the two strands of duplex DNA for hybridizing the probe, whose termini are complementary to the displaced DNA strand. After hybridization, they are in juxtaposition and can subsequently be linked by DNA ligase. As a result, a true topological link forms at a precise position on the DNA double helix yielding locked, earring-like label. DNA topological labeling can be done both in solution and, for longer templates, within the agarose gel plug. Accordingly, highly localized DNA detection with rolling circle amplification of hybridization signal and effective micromanipulations with DNA duplexes become possible through precise spatial positioning of various ligands on the DNA scaffold.     

The effect of nonenzymatic glycation on the stability and conformation of two deoxyoligonucleotide duplexes: a spectroscopic analysis by circular dichroism

Advanced glycation end products (AGEs) play a significant role in the pathophysiology of diabetes leading to such conditions as atherosclerosis, cataract formation, and renal dysfunction. While the formation of nucleoside AGEs was previously demonstrated, no extensive studies have been performed to assess the effect of AGEs on DNA structure and folding. The objective of this study was to investigate the nonenzymatic glycation of two DNA oligonucleotide duplexes with one duplex consisting of deoxy-poly(A)15 and deoxy-poly(T)15 and the other consisting of deoxy-poly(GA)15 and deoxy-poly(CT)15. With D-glucose, D-galactose, D/L-glyceraldehyde, and D-glucosamine serving as the model glycating carbohydrates, D-glucosamine was found to exhibit the greatest effect on the stability and structure of the oligonucleotide duplexes, a finding that was confirmed by circular dichroism. The nonenzymatic glycation of deoxy-poly(AT) by D-glucosamine destabilized the deoxy-poly(AT) structure and changed its conformation from A form to X form. D-glucosamine also altered the conformation of deoxy-poly(GA)15 and deoxy-poly(CT)15 from A form to B form. Capillary electrophoresis and ultraviolet and fluorescence spectroscopy revealed that, of the various purines and pyrimidines, 2'-deoxyguanosine and guanine were most reactive with D-glucosamine. The nonenzymatic modification of nucleic acids warrants further investigation because this phenomenon may occur in vivo, altering DNA structure and/or function.     

A versatile method for the preparation of conjugates of peptides with DNA/PNA/analog by employing chemo-selective click reaction in water

The specific 1,3 dipolar Hüisgen cycloaddition reaction known as ‘click-reaction’ between azide and alkyne groups is employed for the synthesis of peptide–oligonucleotide conjugates. The peptide nucleic acids (PNA)/DNA and peptides may be appended either by azide or alkyne groups. The cycloaddition reaction between the azide and alkyne appended substrates allows the synthesis of the desired conjugates in high purity and yields irrespective of the sequence and functional groups on either of the two substrates. The versatile approach could also be employed to generate the conjugates of peptides with thioacetamido nucleic acid (TANA) analog. The click reaction is catalyzed by Cu (I) in either water or in organic medium. In water, ~3-fold excess of the peptide-alkyne/azide drives the reaction to completion in 2 h with no side products.     

Synthesis of protein,nucleosides and other organic compounds from cyanamide and potassium nitrite under possible primitive earth conditions

The mixing of cyanamide and KNO₂ produced changes from white solids to yellow liquid and then to orange solid. The gases cyanogen and ammonia were formed. No external energy was used. The reactions were carried out with a small amount of O₂. The presence of proteins in the reaction product formed 13 months after the mixing was indicated by the positive reactions of the cyanamide-KNO₂ reaction product with ninhydrin, microbiuret, and Folin reagent; the ultraviolet absorption at about 280 nm; the yield of 24% of 15 amino acids; and molecular weight measurements of more than 160 000. The presence of nucleosides, nucleic acid bases, hydrocarbons, and organic esters in the reaction product formed 2 months after the mixing was indicated by ultraviolet absorption at about 260 nm, and the results of ligand-exchange chromatography, paper chromatography, infrared analysis, mass spectral analysis, and NMR spectroscopy. Possible cyanamide-mediated dehydration reactions and mechanisms are discussed.     

Nucleic acid junctions and lattices

It is possible to generate sequences of oligomeric nucleic acids which will preferentially associate to form migrationally immobile junctions, rather than linear duplexes, as they usually do. These structures are predicated on the maximization of Watson-Crick base pairing and the lack of sequence symmetry customarily found in their analogs in living systems. Criteria are presented which oligonucleotide sequences must fulfill in order to yield these junction structures. The generable junctions are nexi, from which 3 to 8 double helices may emanate. Each junction may be treated as a macromolecular “valence cluster”, and the individual clusters may be linked together directly, or with pieces of linear DNA interspersed between them. This covalent linkage can be done with enormous specificity, using the sticky-ended ligation techniques currently employed in genetic engineering studies. It appears to be possible to generate covalently joined three-dimensional networks of nucleic acids which are periodic in connectivity and perhaps in space.     

Proteins that shape DNA

During the last five years, considerable accumulation of data on nucleic acids metabolism leads to the discovery of a number of proteins designed to change the conformation of DNA and to "shape" it. Experimental results emphasize the importance of the conformation and the flexibility of DNA itself in such interactions. The mutual recognition of nucleic acids by proteins may be or not dependent on the nnucleotide sequence and in most cases is accompanied by conformational changes in the proteins involved. Among these are proteins that bind in stoichiometric amounts to DNA, proteins that promote the separation of the two strands in a duplex, and finally proteins that change the topology of DNA.     

Interactive Fluorophore and Quencher Pairs for Labeling Fluorescent Nucleic Acid Hybridization Probes

The use of fluorescent nucleic acid hybridization probes that generate a fluorescence signal only when they bind to their target enables real-time monitoring of nucleic acid amplification assays. Real-time nucleic acid amplification assays markedly improves the ability to obtain qualitative and quantitative results. Furthermore, these assays can be carried out in sealed tubes, eliminating carryover contamination. Fluorescent nucleic acid hybridization probes are available in a wide range of different fluorophore and quencher pairs. Multiple hybridization probes, each designed for the detection of a different nucleic acid sequence and each labeled with a differently colored fluorophore, can be added to the same nucleic acid amplification reaction, enabling the development of high-throughput multiplex assays. In order to develop robust, highly sensitive and specific real-time nucleic acid amplification assays it is important to carefully select the fluorophore and quencher labels of hybridization probes. Selection criteria are based on the type of hybridization probe used in the assay, the number of targets to be detected, and the type of apparatus available to perform the assay. This article provides an overview of different aspects of choosing appropriate labels for the different types of fluorescent hybridization probes used with different types of spectrofluorometric thermal cyclers currently available.