Strain-promoted "click" chemistry for terminal labeling of DNA

1,3-Dipolar [3 + 2] cycloaddition between azides and alkynes--an archetypal "click" chemistry--has been used increasingly for the functionalization of nucleic acids. Copper(I)-catalyzed 1,3-dipolar cycloaddition reactions between alkyne-tagged DNA molecules and azides work well, but they require optimization of multiple reagents, and Cu ions are known to mediate DNA cleavage. For many applications, it would be preferable to eliminate the Cu(I) catalyst from these reactions. Here, we describe the solid-phase synthesis and characterization of 5'-dibenzocyclooctyne (DIBO)-modified oligonucleotides, using a new DIBO phosphoramidite, which react with azides via copper-free, strain-promoted alkyne-azide cycloaddition (SPAAC). We found that the DIBO group not only survived the standard acidic and oxidative reactions of solid-phase oligonucleotide synthesis (SPOS), but that it also survived the thermal cycling and standard conditions of the polymerase chain reaction (PCR). As a result, PCR with DIBO-modified primers yielded "clickable" amplicons that could be tagged with azide-modified fluorophores or immobilized on azide-modified surfaces. Given its simplicity, SPAAC on DNA could streamline the bioconjugate chemistry of nucleic acids in a number of modern biotechnologies.     

Induction of DNA damage signaling by oxidative stress in relation to DNA replication as detected using "click chemistry"

Induction of DNA damage by oxidants such as H(2) O(2) activates the complex network of DNA damage response (DDR) pathways present in cells to initiate DNA repair, halt cell cycle progression, and prepare an apoptotic reaction. We have previously reported that activation of Ataxia Telangiectasia Mutated protein kinase (ATM) and induction of γH2AX are among the early events of the DDR induced by exposure of cells to H(2) O(2) , and in human pulmonary carcinoma A549 cells, both events were expressed predominantly during S-phase. This study was designed to further explore a correlation between these events and DNA replication. Toward this end, we utilized 5-ethynyl-2'deoxyuridine (EdU) and the "click chemistry" approach to label DNA during replication, followed by exposure of A549 cells to H(2) O(2) . Multiparameter laser scanning cytometric analysis of these cells made it possible to identify DNA replicating cells and directly correlate H(2) O(2) -induced ATM activation and induction of γH2AX with DNA replication on a cell by cell basis. After pulse-labeling with EdU and exposure to H(2) O(2) , confocal microscopy was also used to examine the localization of DNA replication sites ("replication factories") versus the H2AX phosphorylation sites (γH2AX foci) in nuclear chromatin in an attempt to observe the absence or presence of colocalization. The data indicate a close association between DNA replication and H2AX phosphorylation in A549 cells, suggesting that these DNA damage response events may be triggered by stalled replication forks and perhaps also by induction of DNA double-strand breaks at the primary DNA lesions induced by H(2) O(2) .     

Super-resolution optical DNA Mapping via DNA methyltransferase-directed click chemistry

We demonstrate an approach to optical DNA mapping, which enables near single-molecule characterization of whole bacteriophage genomes. Our approach uses a DNA methyltransferase enzyme to target labelling to specific sites and copper-catalysed azide-alkyne cycloaddition to couple a fluorophore to the DNA. We achieve a labelling efficiency of ∼70% with an average labelling density approaching one site every 500 bp. Such labelling density bridges the gap between the output of a typical DNA sequencing experiment and the long-range information derived from traditional optical DNA mapping. We lay the foundations for a wider-scale adoption of DNA mapping by screening 11 methyltransferases for their ability to direct sequence-specific DNA transalkylation; the first step of the DNA labelling process and by optimizing reaction conditions for fluorophore coupling via a click reaction. Three of 11 enzymes transalkylate DNA with the cofactor we tested (a readily prepared s-adenosyl-l-methionine analogue).     

Human placental DNA methyltransferase: DNA substrate and DNA binding specificity

We have partially purified a DNA methyltransferase from human placenta using a novel substrate for a highly sensitive assay of methylation of hemimethylated DNA. This substrate was prepared by extensive nick translation of bacteriophage XP12 DNA, which normally has virtually all of its cytosine residues replaced by 5-methylcytosine (m5C). Micrococcus luteus DNA was just as good a substrate if it was first similarly nick translated with m5dCTP instead of dCTP in the polymerization mixture. At different stages in purification and under various conditions (including in the presence or absence of high mobility group proteins), the methylation of m5C-deficient DNA and that of hemimethylated DNA were compared. Although hemimethylated , m5C-rich DNAs were much better substrates than were m5C-deficient DNAs and normal XP12 DNA could not be methylated, all of these DNAs were bound equally well by the enzyme. In contrast, from the same placental extract, a DNA-binding protein of unknown function was isolated which binds to m5C-rich DNA in preference to the analogous m5C-poor DNA.     

A rapid and versatile method to label receptor ligands using "click" chemistry: Validation with the muscarinic M1 antagonist pirenzepine

Tagged biologically active molecules represent powerful pharmacological tools to study and characterize ligand-receptor interactions. However, the labeling of such molecules is not trivial, especially when poorly soluble tags have to be incorporated. The classical method of coupling usually necessitates a tedious final purification step to remove the excess of reagents and to isolate tagged molecules. To overcome this limitation, Cu(I)-catalyzed 1,3-dipolar cycloaddition, referred to as "click" chemistry, was evaluated as a tool to facilitate the access to labeled molecules. In order to validate the approach, we focused our attention on the incorporation of a fluorophore (Lissamine Rhodamine B), a nonfluorescent dye (Patent Blue VF), or biotin into a muscarinic antagonist scaffold derived from pirenzepine. The reaction performed in acetonitrile/water, in the presence of CuSO4 and Cu wire, allowed us to obtain three novel pirenzepine derivatives with high purity and in good yield. No coupling reagents were needed, and the quasi-stoichiometric conditions of the reaction enabled the straightforward isolation of the final product by simple precipitation and its use in bioassays. The affinity of the compounds for the human M1 muscarinic receptor fused to EGFP was checked under classical radioligand and FRET binding conditions. The three pirenzepine constructs display a nanomolar affinity for the M1 receptor. In addition, both dye-labeled derivatives behave as potent acceptors of energy from excited EGFP with a very high quenching efficiency.     

Detection of transglutaminase activity using click chemistry

Transglutaminase 2 (TG2) is a Ca(2+)-dependent enzyme able to catalyze the formation of ε(γ-glutamyl)-lysine crosslinks between polypeptides, resulting in high molecular mass multimers. We have developed a bioorthogonal chemical method for the labeling of TG2 glutamine-donor proteins. As amine-donor substrates we used a set of azide- and alkyne-containing primary alkylamines that allow, after being crosslinked to glutamine-donor proteins, specific labeling of these proteins via the azide-alkyne cycloaddition. We demonstrate that these azide- and alkyne-functionalized TG2 substrates are cell permeable and suitable for specific labeling of TG2 glutamine-donor substrates in HeLa and Movas cells. Both the Cu(I)-catalyzed and strain promoted azide-alkyne cycloaddition proved applicable for subsequent derivatization of the TG2 substrate proteins with the desired probe. This new method for labeling TG2 substrate proteins introduces flexibility in the detection and/or purification of crosslinked proteins, allowing differential labeling of cellular proteins.     

Targeted liposomes: convenient coupling of ligands to preformed vesicles using "click chemistry"

An efficient and convenient chemoselective conjugation method based on "click chemistry" was developed for coupling ligands to the surface of preformed liposomes. It can be performed under mild conditions in aqueous buffers; the use of a water soluble Cu(I) chelator, such as bathophenanthrolinedisulfonate, was essential to obtain good yields in reasonable reaction times. A model reaction was achieved in which, in a single step, an unprotected alpha-D-mannosyl derivative carrying a spacer arm functionalized with an azide group was conjugated to the surface of vesicles presenting a synthetic lipid carrying a terminal alkyne function. When liposomes composed of saturated phospholipids were used, the reaction conditions developed in the present work did not damage the membranes as measured by the absence of leakage of entrapped 5,6-carboxyfluorescein. Moreover, as assessed by agglutination experiments using concanavalin A, the mannose residues were perfectly accessible on the surface of the targeted vesicles.     

Supercoiling-dependent sequence specificity of mammalian DNA methyltransferase.

Negative supercoiling of substrate DNA dramatically alters the in vitro sequence specificity of mammalian DNA methyltransferase (DNA MeTase). This result suggests that in vivo site selection by DNA MeTase could be regulated by conformational information in the form of alternative secondary structures induced in DNA by local supercoiling or by the binding of specific nuclear proteins. DNA in the left-handed Z-form is shown not to be a substrate for mammalian DNA MeTase. The sensitivity of DNA MeTase to DNA structure may also make it useful as a probe for sequences which undergo supercoiling-dependent structural transitions in vitro.     

In vitro specificity of EcoRI DNA methyltransferase.

The sequence selectivity of enzyme-DNA interactions was analyzed by comparing discrimination between synthetic oligonucleotides containing the canonical site GAATTC and altered DNA sequences with the EcoRI DNA methyltransferase. The specificities (kcat/KmDNA) are decreased from 5- to 23,000-fold relative to the unmodified site. For several substrates the decrease in kcat makes a disproportionate contribution to the specificity difference, suggesting that discrimination is mediated by the placement of critical catalytic residues rather than binding interactions. This is supported by our observation that specificity changes are generally not followed by changes in the stability of the methyltransferase-DNA complexes. Also, base pair substitutions near the site of methylation result in greater decreases in complex stability, suggesting that recognition and catalytic mechanisms overlap.     

In vivo specificity of EcoRI DNA methyltransferase.

The EcoRI adenine DNA methyltransferase forms part of a bacterial restriction/modification system; the methyltransferase modifies the second adenine within the canonical site GAATTC, thereby preventing the EcoRI endonuclease from cleaving this site. We show that five noncanonical EcoRI sites (TAATTC, CAATTC, GTATTC, GGATTC and GAGTTC) are not methylated in vivo under conditions when the canonical site is methylated. Only when the methyltransferase is overexpressed is partial in vivo methylation of the five sites detected. Our results suggest that the methyltransferase does not protect host DNA against potential endonuclease-mediated cleavage at noncanonical sites. Our related in vitro analysis of the methyltransferase reveals a low level of sequence-discrimination. We propose that the high in vivo specificity may be due to the active removal of methylated sequences by DNA repair enzymes (J. Bacteriology (1987), 169 3243-3250).     

An improved method for genomic DNA extraction from cyanobacteria

We present an improved method for genomic DNA extraction from cyanobacteria by updating the earlier method from our group (Sinha et al. 2001) that does not require lysozyme treatment or sonication to lyse the cells. This method use lysis buffer to lyse the cells and also skips the initial treatments to remove the exopolysaccharides or to break the clumps. To test the efficacy of the method DNA was extracted from the freshwater cyanobacteria Anabaena variabilis PCC 7937, Anabaena sp. PCC 7120, Synechocystis sp. PCC 6803, Synechococcus sp. PCC 6301 and Rivularia sp. HKAR-4 (Accession number: FJ939128). The spectrophotometric and gel electrophoresis analysis revealed high yield and high quality of genomic DNA extracted by this method. Furthermore, the RAPD resulted in the amplification of unidentified genomic regions of various lengths; however, rDNA amplification gave only one band of 1.5 kb in all studied cyanobacteria. Thymine dimer detection study revealed that thymine dimers are induced only by UV-B radiation in A. variabilis PCC 7937 and there is no effect of PAR and UV-A on its genome. Collectively, all these findings put forward the applicability of this method in different studies and purposes.     

DNA-templated click chemistry for creation of novel DNA binding molecules

We have developed a new methodology for producing new molecules that bind to dsDNA using DNA-templated click chemistry. The click reactions between the minor groove binding peptide and acridine intercalators were accelerated by the addition of dsDNA. Furthermore, the resulting peptide–acridine conjugate showed a slightly stronger binding to dsDNA. These results indicate that the DNA-templated click chemistry is applicable for screening new binding molecules.     

Sequential and parallel dual labeling of nanoparticles using click chemistry

Bioorthogonal ‘click’ reactions have recently emerged as promising tools for chemistry and biological applications. By using a combination of two different ‘click’ reactions, ‘double-click’ strategies have been developed to attach multiple labels onto biomacromolecules. These strategies require multi-step modifications of the biomacromolecules that can lead to heterogeneity in the final conjugates. Herein, we report the synthesis and characterization of a set of three trifunctional linkers. The linkers having alkyne and cyclooctyne moieties that are capable of participating in sequential copper(I)-catalyzed and copper-free cycloaddition reactions with azides. We have also prepared a linker comprised of an alkyne and a 1,2,4,5-terazine moiety that allows for simultaneous cycloaddition reactions with azides and trans-cyclooctenes, respectively. These linkers can be attached to synthetic or biological macromolecules to create a platform capable of sequential or parallel ‘double-click’ labeling in biological systems. We show this potential using a generation 5 (G5) polyamidoamine (PAMAM) dendrimer in combination with the clickable linkers. The dendrimers were successfully modified with these linkers and we demonstrate both sequential and parallel ‘double-click’ labeling with fluorescent reporters. We anticipate that these linkers will have a variety of application including molecular imaging and monitoring of macromolecule interactions in biological systems.     

Direct and nondestructive verification of PNA immobilization using click chemistry

The fluorogenic 1,3-Huisgen dipolar cycloaddition reaction was used as part of a novel immobilization strategy of PNA capture probes on a microarray. By using this click chemistry, azidocoumarin-anchored PNA probes were immobilized on phenyl acetylene-modified glass slides with the simultaneous generation of the fluorescent triazolylcoumarin moiety. Since the emitting moieties are generated in the immobilization reaction itself, fluorescent signals can be used to directly monitor the integrity of immobilization in a nondestructive manner. By using this strategy, PNA microarrays were prepared and successfully employed to perform microarray-based diagnosis of selected mutations in the breast cancer susceptibility gene BRCA1.     

Biotinylated anisomycin: a comparison of classical and "click" chemistry approaches

Two approaches to the synthesis of biotinylated derivatives of the stress-activated protein kinase (SAPK) pathway activator anisomycin have been investigated. Attachment of the biotin moiety to the central core was achieved either through the use of a classical displacement reaction on alpha-halo carbonyl derivatives of biotin or through a copper(I)-catalyzed 1,3-dipolar Huisgen cycloaddition ("click") coupling of biotinylated azides to propargyl-marked analogues of anisomycin. In each case, the resultant N-linked molecular probes were found to be active in SAPK pathway immunoblot assays, while their O-linked counterparts were inactive. However, in sharp contrast to the classical coupling approach which results in low coupling yields, the aqueous "click" coupling process was found to deliver high yields of biotinylated probes, making it the conjugation method of choice. A survey of the available methods for the addition of a propargyl marker onto a range of chemical functionalities strongly suggests that this copper(I)-catalyzed 1,3-dipolar Huisgen cycloaddition approach to biotinylation may be generally applied.     

Construction and assembly of branched Y-shaped DNA: "click" chemistry performed on dendronized 8-aza-7-deazaguanine oligonucleotides

Branched DNA was synthesized from tripropargylated oligonucleotides by the Huisgen-Meldal-Sharpless cycloaddition using "stepwise and double click" chemistry. Dendronized oligonucleotides decorated with 7-tripropargylamine side chains carrying two terminal triple bonds were further functionalized with bis-azides to give derivatives with two terminal azido groups. Then, the branched side chains with two azido groups or two triple bonds were combined with DNA-fragments providing the corresponding clickable function. Both concepts afforded branched (Y-shaped) three-armed DNA. Annealing of branched DNA with complementary oligonucleotides yielded supramolecular assemblies. The concept of "stepwise and double click" chemistry combined with selective hybridization represents a flexible tool to generate DNA nanostructures useful for various purposes in DNA diagnostics, delivery, and material science applications.     

DNA bending by EcoRI DNA methyltransferase accelerates base flipping but compromises specificity.

EcoRI DNA methyltransferase was previously shown to bend its cognate DNA sequence by 52 degrees and stabilize the target adenine in an extrahelical orientation. We describe the characterization of an EcoRI DNA methyltransferase mutant in which histidine 235 was selectively replaced with asparagine. Steady-state kinetic and thermodynamic parameters for the H235N mutant revealed only minor functional consequences: DNA binding affinity (KDDNA) was reduced 10-fold, and kcat was decreased 30%. However, in direct contrast to the wild type enzyme, DNA bending within the mutant enzyme-DNA complexes was not observed by scanning force microscopy. The bending-deficient mutant showed enhanced discrimination against the methylation at nontarget sequence DNA. This enhancement of enzyme discrimination was accompanied by a change in the rate-limiting catalytic step. No presteady-state burst of product formation was observed, indicating that the chemistry step (or prior event) had become rate-limiting for methylation. Direct observation of the base flipping transition showed that the lack of burst kinetics was entirely due to slower base flipping. The combined data show that DNA bending contributes to the correct assembly of the enzyme-DNA complex to accelerate base flipping and that slowing the rate of this precatalytic isomerization can enhance specificity.     

Convenient determination of DNA extraction efficiency using an external DNA recovery standard and quantitative-competitive PCR

Molecular biology techniques have advanced the field of microbial ecology through the analysis of nucleic acids. Most techniques that use DNA or RNA require their extraction from environmental matrices, which can be tedious and inefficient. While a number of extraction methods, both laboratory-based and commercially available, have been developed, none of these include a convenient method to determine extraction efficiency. We have developed an external DNA recovery standard, Lambda DNA (target DNA) contained within pBR322, allowing routine determinations of DNA recovery efficiency. Target DNA was added to sediments as whole cells, total DNA extracted using commercial DNA extraction/purification kits and the amount of target DNA recovered quantified by quantitative-competitive PCR (QC-PCR). Three commercially available kits (UltraClean Soil DNA, FastDNA SPIN and Soil Master DNA Extraction) were evaluated for recovery efficiency. Recoveries for the three kits ranged from undetectable to 43.3% with average recoveries of 14.9+/-16.0%, 28.3+/-10.5% and 2.4+/-0.1% (UltraClean, FastDNA and Soil Master, respectively). Quantification of target DNA proved robust in sediments heavily polluted with polycyclic aromatic hydrocarbons and the external recovery standard could be detected following extraction and amplification from as few as 1 x 10(3) cells added to 0.5 g sediment (wet weight). The external DNA recovery standard was also added directly to the sediment as purified plasmid DNA prior to extraction. It was recovered with similar efficiency as when added as whole cells, suggesting its usefulness in estimating DNA recovery in ribosomal DNA studies. These results show that, while the commercial kits offer expedited sample processing, the extraction efficiencies vary on a sample-by-sample basis and were <100%. Therefore, quantitative DNA studies require an estimation of DNA recovery.     

Interaction specificity of violamycin BI and BII with DNA using the hyperchromic spectra method

Interaction specificity of the anthracycline antibiotics violamycin BI and violamycin BII in respect to A.T and G.C pairs was investigated. For comparison denaturation of complexes with A.T and G.C specific ligands distamycin A and actinomycin D are presented. Making use of the least squares hyperchromic spectra measured in the course of thermal denaturation were partitioned into the components corresponding to the melting of A.T and G.C base pairs and dissociation of ligand. The mutual dependence of AT and GC denaturation allows one to draw conclusions about specificity of interaction. In case of both violamycins only slight preference of interaction with AT-rich regions was detected. The dissociation of violamycin BII in the latest stage of thermal denaturation was found to be cooperative.