Design of a New Fluorescent Cofactor for DNA Methyltransferases and Sequence-specific Labeling of DNA

Journal of the American Chemical Society. Mar, 2003  |  Pubmed ID: 12643710

Sequence-specific labeling of DNA is of immense interest for analytical and functional studies of DNA. We present a novel approach for sequence-specific labeling of DNA using a newly designed fluorescent cofactor for the DNA methyltransferase from Thermus aquaticus (M.TaqI). Naturally, M.TaqI catalyzes the nucleophilic attack of the exocyclic amino group of adenine within the double-stranded 5'-TCGA-3' DNA sequence onto the methyl group of the cofactor S-adenosyl-L-methionine (AdoMet) leading to methyl group transfer. The design of a new fluorescent cofactor for covalent labeling of DNA was based on three criteria: (1) Replacement of the methionine side chain of the natural cofactor AdoMet by an aziridinyl residue leads to M.TaqI-catalyzed nucleophilic ring opening and coupling of the whole nucleoside to DNA. (2) The adenosyl moiety is the molecular anchor for cofactor binding. (3) Attachment of a fluorophore via a flexible linker to the 8-position of the adenosyl moiety does not block cofactor binding. According to these criteria the new fluorescent cofactor 8-amino[1''-(N''-dansyl)-4''-aminobutyl]-5'-(1-aziridinyl)-5'-deoxyadenosine (3) was synthesized. 3 binds about 4-fold better than the natural cofactor AdoMet to M.TaqI and is coupled with a short duplex oligodeoxynucleotide by M.TaqI. The identity of the expected modified nucleoside was verified by electrospray ionization mass spectrometry after enzymatic fragmentation of the product duplex. In addition, the new cofactor 3 was used to sequence-specifically label plasmid DNA in a M.TaqI-catalyzed reaction.

Polycyclic Aromatic DNA-base Surrogates: High-affinity Binding to an Adenine-specific Base-flipping DNA Methyltransferase

Angewandte Chemie (International Ed. in English). Aug, 2003  |  Pubmed ID: 12949880

The Stability of Pseudopeptides Bearing Sulfoximines As Chiral Backbone Modifying Element Towards Proteinase K

Bioorganic & Medicinal Chemistry Letters. Oct, 2003  |  Pubmed ID: 12951094

Incorporation of sulfoximines as backbone modifying element results in two new pseudopeptide bonds which display enhanced (bond A) and strongly reduced reactivity (bond B) towards hydrolysis by Proteinase K.

Convenient Synthesis of Oligodeoxynucleotides Containing 2'-deoxy-6-thioinosine

Nucleosides, Nucleotides & Nucleic Acids. May-Aug, 2003  |  Pubmed ID: 14565242

A facile synthesis of oligodeoxynucleotides (ODN) containing 2'-deoxy-6-thioinosine (dI6S) based on the convertible nucleoside O6-phenyl-2'-deoxyinosine is presented. After standard solid-phase DNA synthesis and removal of the cyanoethyl protecting groups with DBU treatment with aqueous sodium hydrogen sulfide introduces the sulfur functionality, deprotects the other nucleobases and cleaves the ODN from the solid support in a one-pot reaction. In addition, the extinction coefficient of 2'-deoxy-6-thioinosine is determined by enzymatic fragmentation of the resulting ODN in the presence of adenosine deaminase.

DNA Mismatch-specific Base Flipping by a Bisacridine Macrocycle

Chembiochem : a European Journal of Chemical Biology. Dec, 2003  |  Pubmed ID: 14661275

Most, if not all, enzymes that chemically modify nucleobases in DNA flip their target base from the inside of the double helix into an extrahelical position. This energetically unfavorable conformation is partly stabilized by specific binding of the apparent abasic site being formed. Thus, DNA base-flipping enzymes, like DNA methyltransferases and DNA glycosylases, generally bind very strongly to DNA containing abasic sites or abasic-site analogues. The macrocyclic bisacridine BisA has previously been shown to bind abasic sites. Herein we demonstrate that it is able to specifically recognize DNA base mismatches and most likely induces base flipping. Specific binding of BisA to DNA mismatches was studied by thermal denaturation experiments by using short duplex oligodeoxynucleotides containing central TT, TC, or TG mismatches or a TA match. In the presence of the macrocycle a strong increase in the melting temperature of up to 7.1 degrees C was observed for the mismatch-containing duplexes, whereas the melting temperature of the fully matched duplex was unaffected. Furthermore, BisA binding induced an enhanced reactivity of the mispaired thymine residue in the DNA toward potassium permanganate oxidation. A comparable reactivity has previously been observed for a TT target base mismatch in the presence of DNA methyltransferase M.TaqI. This similarity to a known base-flipping enzyme suggests that insertion of BisA into the DNA helix displaces the mispaired thymine residue into an extrahelical position, where it should be more prone to chemical oxidation. Thus, DNA base flipping does not appear to be limited to DNA-modifying enzymes but it is likely to also be induced by a small synthetic molecule binding to a thermodynamically weakened site in DNA.

Sequence-specific Methyltransferase-induced Labeling of DNA (SMILing DNA)

Chembiochem : a European Journal of Chemical Biology. Mar, 2004  |  Pubmed ID: 14997517

A new concept for sequence-specific labeling of DNA by using chemically modified cofactors for DNA methyltransferases is presented. Replacement of the amino acid side chain of the natural cofactor S-adenosyl-L-methionine with an aziridine group leads to a cofactor suitable for DNA methyltransferase-catalyzed sequence-specific coupling with DNA. Sequence-specifically fluorescently labeled plasmid DNA was obtained by using the DNA methyltransferase from Thermus aquaticus (M.TaqI) as catalyst and attaching a fluorophore to the aziridine cofactor. First results suggest that all classes of DNA methyltransferases with different recognition sequences can be used. In addition, this novel method for DNA labeling should be applicable to a wide variety of reporter groups.

Sequence-specific DNA Labeling Using Methyltransferases

Methods in Molecular Biology (Clifton, N.J.). 2004  |  Pubmed ID: 15197308

Sequence-specific labeling of native deoxyribonucleic acid (DNA) still represents a more-or-less unsolved problem. Difficulties mainly arise from the necessity to combine two different functions: sequence-specific recognition of DNA and covalent bond formation between the label and DNA. DNA methyltransferases (MTases) naturally possess these two functions and transfer a methyl group from the cofactor S-adenosyl-L-methionine (AdoMet) to adenine or cytosine residues within specific DNA sequences, typically ranging from two to eight base pairs. Unfortunately, the methyl group itself is a very limited reporter group and it would be desirable to transfer larger chemical entities with DNA MTases. Replacement of the methionine side chain of the natural cofactor AdoMet by an aziridinyl residue leads to the synthetic cofactor N-adenosylaziridine, which is quantitatively, base- and sequence-specifically coupled with DNA in a DNA MTase-catalyzed reaction. By attaching interesting reporter groups to a suitable position of N-adenosylaziridine a large variety of new synthetic cofactors are obtained for sequence-specific labeling of DNA. This method is illustrated by coupling primary amino groups and biotin to short duplex oligodeoxynucleotides or plasmid DNA using the DNA MTase M.TaqI.

Direct Transfer of Extended Groups from Synthetic Cofactors by DNA Methyltransferases

Nature Chemical Biology. Jan, 2006  |  Pubmed ID: 16408089

S-Adenosyl-L-methionine (AdoMet) is the major methyl donor for biological methylation reactions catalyzed by methyltransferases. We report the first chemical synthesis of AdoMet analogs with extended carbon chains replacing the methyl group and their evaluation as cofactors for all three classes of DNA methyltransferases. Extended groups containing a double or triple bond in the beta position to the sulfonium center were transferred onto DNA in a catalytic and sequence-specific manner, demonstrating a high utility of such synthetic cofactors for targeted functionalization of biopolymers.

Synthesis of S-adenosyl-L-methionine Analogs and Their Use for Sequence-specific Transalkylation of DNA by Methyltransferases

Nature Protocols. 2006  |  Pubmed ID: 17487172

Here we describe a one-step synthetic procedure for the preparation of S-adenosyl-L-methionine (AdoMet) analogs with extended carbon chains replacing the methyl group. These AdoMet analogs function as efficient cofactors for DNA methyltransferases (MTases), and we provide a protocol for sequence-specific transfer of extended side chains from these AdoMet analogs to DNA by DNA MTases. Direct chemoselective allylation or propargylation of S-adenosyl-L-homocysteine (AdoHcy) at sulfur is achieved under the acidic conditions needed to protect other nucleophilic positions in AdoHcy. The unsaturated bonds in beta position to the sulfonium center of the resulting AdoMet analogs are designed to stabilize the transition state formed upon DNA MTase-catalyzed nucleophilic attack at the carbon next to the sulfonium center and lead to efficient transfer of the extended side chains to DNA. Using these protocols, sequence-specific functionalized DNA can be obtained within one to two weeks.

Quantitative Labeling of Long Plasmid DNA with Nanometer Precision

Chembiochem : a European Journal of Chemical Biology. Sep, 2007  |  Pubmed ID: 17654629

Serum Insensitive, Intranuclear Protein Delivery by the Multipurpose Cationic Lipid SAINT-2

Journal of Controlled Release : Official Journal of the Controlled Release Society. Nov, 2007  |  Pubmed ID: 17884225

Cationic liposomal compounds are widely used to introduce DNA and siRNA into viable cells, but none of these compounds are also capable of introducing proteins. Here we describe the use of a cationic amphiphilic lipid SAINT-2:DOPE for the efficient delivery of proteins into cells (profection). Labeling studies demonstrated equal delivery efficiency for protein as for DNA and siRNA. Moreover, proteins complexed with Saint-2:DOPE were successfully delivered, irrespective of the presence of serum, and the profection efficiency was not influenced by the size or the charge of the protein:cationic liposomal complex. Using beta-galactosidase as a reporter protein, enzymatic activity was detected in up to 98% of the adherent cells, up to 83% of the suspension cells and up to 70% of the primary cells after profection. A delivered antibody was detected in the cytoplasm for up to 7 days after profection. Delivery of the methyltransferase M.SssI resulted in DNA methylation, leading to a decrease in E-cadherin expression. The lipid-mediated multipurpose transport system reported here can introduce proteins into the cell with an equal delivery efficiency as for nucleotides. Delivery is irrespective of the presence of serum, and the protein can exert its function both in the cytoplasm and in the nucleus. Furthermore, DNA methylation by M.SssI delivery as a novel tool for gene silencing has potential applications in basic research and therapy.

A New Tool for Biotechnology: AdoMet-dependent Methyltransferases

Trends in Biotechnology. Mar, 2007  |  Pubmed ID: 17254657

AdoMet-dependent methyltransferases catalyze highly specific methyl group transfers from the ubiquitous cofactor S-adenosyl-L-methionine to a multitude of biological targets in the cell. Recently, DNA methyltransferases have been used for the sequence-specific, covalent attachment of larger chemical groups to plasmid and bacteriophage DNA using two classes of synthetic AdoMet analogs. These synthetic cofactors, in combination with the myriad AdoMet-dependent methyltransferases available in nature, provide new molecular tools for precise, targeted functionalization and labeling of large natural DNAs and, in all likelihood, RNAs and proteins. This paves the way for numerous novel applications in the functional analysis of biological methylation, biotechnology and medical diagnostics.

Targeted Labeling of DNA by Methyltransferase-directed Transfer of Activated Groups (mTAG)

Journal of the American Chemical Society. Mar, 2007  |  Pubmed ID: 17309265

2-Aminopurine Flipped into the Active Site of the Adenine-specific DNA Methyltransferase M.TaqI: Crystal Structures and Time-resolved Fluorescence

Journal of the American Chemical Society. May, 2007  |  Pubmed ID: 17455934

We report the crystal structure of the DNA adenine-N6 methyltransferase, M.TaqI, complexed with DNA, showing the fluorescent adenine analog, 2-aminopurine, flipped out of the DNA helix and occupying virtually the same position in the active site as the natural target adenine. Time-resolved fluorescence spectroscopy of the crystalline complex faithfully reports this state: base flipping is accompanied by the loss of the very short ( approximately 50 ps) lifetime component associated with fully base-stacked 2-aminopurine in DNA, and 2-aminopurine is subject to considerable quenching by pi-stacking interactions with Tyr108 in the catalytic motif IV (NPPY). This proves 2-aminopurine to be an excellent probe for studying base flipping by M.TaqI and suggests similar quenching in the active sites of DNA and RNA adenine-N6 as well as DNA cytosine-N4 methyltransferases sharing the conserved motif IV. In solution, the same distinctive fluorescence response confirms complete destacking from DNA and is also observed when the proposed key residue for base flipping by M.TaqI, the target base partner thymine, is substituted by an abasic site analog. The corresponding cocrystal structure shows 2-aminopurine in the active site of M.TaqI, demonstrating that the partner thymine is not essential for base flipping. However, in this structure, a shift of the 3' neighbor of the target base into the vacancy left after base flipping is observed, apparently replicating a stabilizing role of the missing partner thymine. Time-resolved fluorescence and acrylamide quenching measurements of M.TaqI complexes in solution provide evidence for an alternative binding site for the extra-helical target base within M.TaqI and suggest that the partner thymine assists in delivering the target base into the active site.

DNA Labelling Topologies for Monitoring DNA-protein Complex Formation by Fluorescence Anisotropy

Nucleosides, Nucleotides & Nucleic Acids. 2007  |  Pubmed ID: 18066831

In this work, fluorescence anisotropy was used to study DNA binding of the DNA methyltransferase M.TaqI. For this purpose short DNA molecules labelled with three different fluorophores (Cy3, thiazole orange, and ethidium bromide) were prepared in various topologies and their suitability for detection of DNA-protein complex formation was investigated.

Molecular Scale Architecture: Engineered Three- and Four-way Junctions

Bioconjugate Chemistry. Feb, 2008  |  Pubmed ID: 18069780

Biomolecular self-assembly provides a basis for the bottom-up construction of useful and diverse nanoscale architectures. DNA is commonly used to create these assemblies and is often exploited as a lattice or an array. Although geometrically rigid and highly predictable, these sheets of repetitive constructs often lack the ability to be enzymatically manipulated or elongated by standard biochemical techniques. Here, we describe two approaches for the construction of position-controlled, molecular-scale, discrete, three- and four-way DNA junctions. The first approach for constructing these junctions relies on the use of nonmigrating cruciforms generated from synthetic oligonucleotides to which large, biologically generated, double-stranded DNA segments are enzymatically ligated. The second approach utilitizes the DNA methyltransferase-based SMILing (sequence-specific methyltransferase-induced labeling of DNA) method to site-specifically incorporate a biotin within biologically derived DNA. Streptavidin is then used to form junctions between unique DNA strands. The resultant assemblies have precise and predetermined connections with lengths that can be varied by enzymatic or hybridization techniques, or geometrically controlled with standard DNA functionalization methods. These junctions are positioned with single nucleotide resolution on large, micrometer-length templates. Both approaches generate DNA assemblies which are fully compatible with standard recombinant methods and thus provide a novel basis for nanoengineering applications.

Enzyme-directed Positioning of Nanoparticles on Large DNA Templates

Bioconjugate Chemistry. Feb, 2008  |  Pubmed ID: 18088085

A method to position nanoparticles onto DNA with high resolution using an enzyme-based approach is described. This provides a convenient route to assemble multiple nanoparticles (e.g., Au and CdSe) to specific positions with a high level of control and expandability to more complex assemblies. Atomic force microscopy is used to analyze the nanostructures, which have potential interest for biosensor, optical waveguide, molecular electronics, and energy transfer studies.

Functional Reassembly of Split Enzymes On-site: a Novel Approach for Highly Sequence-specific Targeted DNA Methylation

Chembiochem : a European Journal of Chemical Biology. Feb, 2008  |  Pubmed ID: 18189249

6-Thioguanine in DNA As CD-spectroscopic Probe to Study Local Structural Changes Upon Protein Binding

Chirality. Sep, 2008  |  Pubmed ID: 18293364

A combination of experimental and theoretical circular dichroism (CD) spectroscopy was used to study local deformations of DNA caused by binding of the base flipping DNA methyltransferase M.TaqI. To selectively study the structural changes within the DNA, we replaced single guanine residues at six different positions in duplex DNA with 6-thioguanine (s(6)G), which absorbs at 342 nm where unmodified DNA and the enzyme are transparent. The shape and the transition wavelength of a CD signal around 340 nm in the spectra of the free DNA and the M.TaqI-bound DNA were found to depend on the position of the s(6)G probe. Theoretical rotational strengths were calculated employing the matrix method which is frequently used to model the CD of large biomolecules. The only chromophores in these calculations were the nucleic acid bases. Comparison of the measured and the calculated CD spectra showed that the applied computational method qualitatively reproduces the dominant band observed around 340 nm in all cases. From our results we conclude that the spectral changes observed upon binding of the enzyme to the DNA are indeed predominantly due to structural changes within the DNA and not to other effects caused by the presence of the enzyme.

Persistent Downregulation of the Pancarcinoma-associated Epithelial Cell Adhesion Molecule Via Active Intranuclear Methylation

International Journal of Cancer. Journal International Du Cancer. Jul, 2008  |  Pubmed ID: 18398839

The epithelial cell adhesion molecule (EpCAM) is expressed at high levels on the surface of most carcinoma cells. SiRNA silencing of EpCAM expression leads to reduced metastatic potential of tumor cells demonstrating its importance in oncogenesis and tumor progression. However, siRNA therapy requires either sequential delivery or integration into the host cell genome. Hence we set out to explore a more definite form to influence EpCAM gene expression. The mechanisms underlying the transcriptional activation of the EpCAM gene, both in normal epithelial tissue as well as in carcinogenesis, are poorly understood. We show that DNA methylation plays a crucial role in EpCAM expression, and moreover, active silencing of endogenous EpCAM via methylation of the EpCAM promoter results in a persistent downregulation of EpCAM expression. In a panel of carcinoma derived cell lines, bisulfite analyses showed a correlation between the methylation status of the EpCAM promoter and EpCAM expression. Treatment of EpCAM-negative cell lines with a demethylating agent induced EpCAM expression, both on mRNA and protein level, and caused upregulation of EpCAM expression in an EpCAM-positive cell line. After delivery of the DNA methyltransferase M.SssI into EpCAM-positive ovarian carcinoma cells, methylation of the EpCAM promoter resulted in silencing of EpCAM expression. SiRNA-mediated silencing remained for 4 days, after which EpCAM re-expression increased in time, while M.SssI-mediated downregulation of EpCAM maintained through successive cell divisions as the repression persisted for at least 17 days. This is the first study showing that active DNA methylation leads to sustained silencing of endogenous EpCAM expression.

Selective Recognition of Pyrimidine-pyrimidine DNA Mismatches by Distance-constrained Macrocyclic Bis-intercalators

Nucleic Acids Research. Sep, 2008  |  Pubmed ID: 18658249

Binding of three macrocyclic bis-intercalators, derivatives of acridine and naphthalene, and two acyclic model compounds to mismatch-containing and matched duplex oligodeoxynucleotides was analyzed by thermal denaturation experiments, electrospray ionization mass spectrometry studies (ESI-MS) and fluorescent intercalator displacement (FID) titrations. The macrocyclic bis-intercalators bind to duplexes containing mismatched thymine bases with high selectivity over the fully matched ones, whereas the acyclic model compounds are much less selective and strongly bind to the matched DNA. Moreover, the results from thermal denaturation experiments are in very good agreement with the binding affinities obtained by ESI-MS and FID measurements. The FID results also demonstrate that the macrocyclic naphthalene derivative BisNP preferentially binds to pyrimidine-pyrimidine mismatches compared to all other possible base mismatches. This ligand also efficiently competes with a DNA enzyme (M.TaqI) for binding to a duplex with a TT-mismatch, as shown by competitive fluorescence titrations. Altogether, our results demonstrate that macrocyclic distance-constrained bis-intercalators are efficient and selective mismatch-binding ligands that can interfere with mismatch-binding enzymes.

Recognition of Homopyrimidine Mismatches by Distance-constrained Macrocyclic Bisintercalators

Nucleic Acids Symposium Series (2004). 2008  |  Pubmed ID: 18776277

Binding of three macrocyclic bisintercalators to mismatch-containing duplexes was analyzed by thermal denaturation experiments, electrospray mass spectrometry studies (ESI-MS) and fluorescent intercalator displacement (FID) titrations. The macrocyclic bisintercalators bind to duplexes containing mismatched thymine bases with high selectivity over the fully matched one and affinity in the submicromolar range (Kd). The FID results also demonstrate that the macrocyclic naphthalene derivative BisNP preferentially binds to pyrimidine-pyrimidine mismatches compared to all other possible base mismatches. This ligand also efficiently competes with a DNA enzyme (M.TaqI) for binding to a duplex with a TT-mismatch.

Sequence-specific Methyltransferase-Induced Labelling (SMILing) of Plasmid DNA for Studying Cell Transfection

Bioorganic & Medicinal Chemistry. Jan, 2008  |  Pubmed ID: 17977734

Plasmid DNA (pUC19 and pBR322) was sequence-specifically, covalently labelled with Cy3 fluorophores using a newly synthesised N-adenosylaziridine cofactor and the DNA methyltransferase M.TaqI. The fluorescently labelled plasmids were used for transfection of mammalian cells and their intracellular distribution was visualised by epifluorescence and confocal fluorescence microscopy. Although these prokaryotic plasmids do not contain nuclear import sequences, translocation into the nuclei was observed.

Synthesis of S-adenosyl-L-homocysteine Capture Compounds for Selective Photoinduced Isolation of Methyltransferases

Chembiochem : a European Journal of Chemical Biology. Jan, 2010  |  Pubmed ID: 20049756

Understanding the interplay of different cellular proteins and their substrates is of major interest in the postgenomic era. For this purpose, selective isolation and identification of proteins from complex biological samples is necessary and targeted isolation of enzyme families is a challenging task. Over the last years, methods like activity-based protein profiling (ABPP) and capture compound mass spectrometry (CCMS) have been developed to reduce the complexity of the proteome by means of protein function in contrast to standard approaches, which utilize differences in physical properties for protein separation. To isolate and identify the subproteome consisting of S-adenosyl-L-methionine (SAM or AdoMet)-dependent methyltransferases (methylome), we developed and synthesized trifunctional capture compounds containing the chemically stable cofactor product S-adenosyl-L-homocysteine (SAH or AdoHcy) as selectivity function. SAH analogues with amino linkers at the N6 or C8 positions were synthesized and attached to scaffolds containing different photocrosslinking groups for covalent protein modification and biotin for affinity isolation. The utility of these SAH capture compounds for selective photoinduced protein isolation is demonstrated for various methyltransferases (MTases) acting on DNA, RNA and proteins as well as with Escherichia coli cell lysate. In addition, they can be used to determine dissociation constants for MTase-cofactor complexes.

Enzymatic Site-specific Functionalization of Protein Methyltransferase Substrates with Alkynes for Click Labeling

Angewandte Chemie (International Ed. in English). Jul, 2010  |  Pubmed ID: 20572224

Targeted DNA Methylation by a DNA Methyltransferase Coupled to a Triple Helix Forming Oligonucleotide to Down-regulate the Epithelial Cell Adhesion Molecule

Bioconjugate Chemistry. Jul, 2010  |  Pubmed ID: 20593890

The epithelial cell adhesion molecule (EpCAM) is a membrane glycoprotein that has been identified as a marker of cancer-initiating cells. EpCAM is highly expressed on most carcinomas, and transient silencing of EpCAM expression leads to reduced oncogenic potential. To silence the EpCAM gene in a persistent manner via targeted DNA methylation, a low activity mutant (C141S) of the CpG-specific DNA methyltransferase M.SssI was coupled to a triple-helix-forming oligonucleotide (TFO-C141S) specifically designed for the EpCAM gene. Reporter plasmids encoding the green fluorescent protein under control of different EpCAM promoter fragments were treated with the TFO-C141S conjugate to determine the specificity of targeted DNA methylation in the context of a functional EpCAM promoter. Treatment of the plasmids with TFO-C141S resulted in efficient and specific methylation of the targeted CpG located directly downstream of the triple helix forming site (TFS). No background DNA methylation was observed neither in a 700 bp region of the EpCAM promoter nor in a 400 bp region of the reporter gene downstream of the TFS. Methylation of the target CpG did not have a detectable effect on promoter activity. This study shows that the combination of a specific TFO and a reduced activity methyltransferase variant can be used to target DNA methylation to predetermined sites with high specificity, allowing determination of crucial CpGs for promoter activity.

Expanding the Chemical Scope of RNA:methyltransferases to Site-specific Alkynylation of RNA for Click Labeling

Nucleic Acids Research. Mar, 2011  |  Pubmed ID: 21037259

This work identifies the combination of enzymatic transfer and click labeling as an efficient method for the site-specific tagging of RNA molecules for biophysical studies. A double-activated analog of the ubiquitous co-substrate S-adenosyl-l-methionine was employed to enzymatically transfer a five carbon chain containing a terminal alkynyl moiety onto RNA. The tRNA:methyltransferase Trm1 transferred the extended alkynyl moiety to its natural target, the N2 of guanosine 26 in tRNA(Phe). LC/MS and LC/MS/MS techniques were used to detect and characterize the modified nucleoside as well as its cycloaddition product with a fluorescent azide. The latter resulted from a labeling reaction via Cu(I)-catalyzed azide-alkyne 1,3-cycloaddition click chemistry, producing site-specifically labeled RNA whose suitability for single molecule fluorescence experiments was verified in fluorescence correlation spectroscopy experiments.

Sequence-specific Covalent Labelling of DNA

Biochemical Society Transactions. Apr, 2011  |  Pubmed ID: 21428951

Sequence-specific DNA modification is of significance for applications in bio- and nano-technology, medical diagnostics and fundamental life sciences research. Preferentially, labelling should be performed covalently, which avoids doubts about label dissociation from the DNA under various conditions. Several methods to label native DNA have been developed in the last two decades. Triple-helix-forming oligodeoxynucleotides and hairpin polyamides that bind DNA sequences specifically in the major and minor groove respectively were used as targeting devices for subsequent covalent labelling. In addition, enzyme-directed labelling approaches utilizing nicking endonucleases in combination with DNA polymerases or DNA methyltransferases have been employed. This review summarizes various techniques useful for functionalization of long native DNA.

Profiling of Methyltransferases and Other S-Adenosyl-L-homocysteine-binding Proteins by Capture Compound Mass Spectrometry

Methods in Molecular Biology (Clifton, N.J.). 2012  |  Pubmed ID: 22065221

There is a variety of approaches to reduce the complexity of the proteome on the basis of functional small molecule-protein interactions. We describe a generic approach based on trifunctional Capture Compounds, in which the initial equilibrium-driven interaction between a small molecule probe and target proteins is irreversibly fixed upon photo-crosslinking between an independent photo-activable reactivity function of the Capture Compound and the surface of the target protein(s). Subsequently, Capture Compound - protein conjugates are isolated from complex biological mixtures via the sorting function of the Capture Compound. Here, we describe the application of a trifunctional Capture Compound that carries the methyltransferase product inhibitor S-Adenosyl-L -homocysteine as the selectivity function for the isolation of methyltransferases from a complex lysate of Escherichia coli DH5α cells. Photo-activated crosslinking enhances yield and sensitivity of the experiment, and the specificity can be readily tested for in competition experiments using an excess of free S-Adenosyl-L -homocysteine.

Enzymatically Incorporated Genomic Tags for Optical Mapping of DNA-Binding Proteins

Angewandte Chemie (International Ed. in English). Feb, 2012  |  Pubmed ID: 22331600

The genome of the T7 bacteriophage can be mapped by using sequence-specific methyltransferase-induced labeling of DNA. In their Communication (DOI: 10.1002/anie.201107714), E. Weinhold, S. Weiss, Y. Ebenstein, and co-workers show that the location of RNA polymerases that are bound to DNA can be visualized as a linear optical barcode, which allows structural variations in genomic DNA to be analyzed and provides an extra layer of contextual information about the genome at the single-molecule level.