A sensitive signal-on assay for MTase activity based on methylation-responsive hairpin-capture DNA probe

This work develops a simple, sensitive and signal-on electrochemical sensor for methyltransferase (MTase) activity analysis. The sensor is composed of a methylene blue-modi?ed "signaling DNA probe" and a "capture DNA probe" tethered methylation-responsive hairpin DNA (hairpin-capture DNA probe). The thiol- modified hairpin-capture DNA probe at 5' end was firstly self-assembled on gold electrode via Au-S bonding. Methylation-induced scission of hairpin-capture DNA probe would displace the hairpin section and remain the "capture DNA probe" section on the gold electrode. Subsequently, the remained "capture DNA probe" on the gold electrode can hybridize with the methylene blue-modi?ed "signaling DNA probe", mediating methylene blue onto the gold electrode surface to generate redox current. It was eT on state. The developed facile signal-on electrochemical sensing system showed a linear response to concentration of Dam MTase range from 0.1 to 1.0 U/mL. The detection limit of Dam MTase activity was determined to be 0.07 U/mL and the total detection time is 7h. The sensor also has the ability to provide information about the dynamics of methylation process. Furthermore, we demonstrated that this sensor could be utilized to screen inhibitors or drugs for Dam MTase.     

A sensitive signal-on electrochemical assay for MTase activity using AuNPs amplification

A sensitive and simple signal-on electrochemical assay for detection of Dam methyltransferase (MTase) activity based on DNA-functionalized gold nanoparticles (AuNPs) amplification coupled with enzyme-linkage reactions is presented. This new assay takes advantage of the steric hindrance of AuNPs and the electrostatic repulsion between the negative-charge phosphate backbones of DNA modified on the AuNPs and redox probe [Fe(CN)(6)](3-/4-). In this method, the self-assembled ssDNA on the electrode is hybridized with its complement ssDNA modified on AuNPs to form dsDNA AuNPs bioconjugates containing specific recognition sequence of Dam MTase and methylation-sensitive restriction endonuclease Dpn I. Then, the AuNPs approach to the electrode and result in blockage of electronic transmission. It is eT OFF state. In the presence of Dam MTase and Dpn I, the specific sequence is methylated and cleavaged, which in turn release the DNA modified AuNPs from the electrode surface allowing free exchange of electrons. It generates a measurable electrochemical signal (eT ON). Differential pulse voltammetry (DPV) is employed to detect the recover current, which is related to the concentration of the Dam MTase. This method is simple, sensitive, nonradioactive and without use of gel-electrophoresis, PCR or chromatographic separation. Under optimized conditions, a linear response to concentration of Dam MTase range from 0.2U/mL to 10 U/mL and a detection limit of 0.12 U/mL are obtained. Furthermore, our new assay is a promising method to detect Dam MTase in the Luria-Bertani (LB) medium, as well as to screen inhibitors or drugs for Dam MTase.     

De novo methylation of CpG island sequences in human fibroblasts overexpressing DNA (cytosine-5-)-methyltransferase.

Recent studies showing a correlation between the levels of DNA (cytosine-5-)-methyltransferase (DNA MTase) enzyme activity and tumorigenicity have implicated this enzyme in the carcinogenic process. Moreover, hypermethylation of CpG island-containing promoters is associated with the inactivation of genes important to tumor initiation and progression. One proposed role for DNA MTase in tumorigenesis is therefore a direct role in the de novo methylation of these otherwise unmethylated CpG islands. In this study, we sought to determine whether increased levels of DNA MTase could directly affect CpG island methylation. A full-length cDNA for human DNA MTase driven by the cytomegalovirus promoter was constitutively expressed in human fibroblasts. Individual clones derived from cells transfected with DNA MTase (HMT) expressed 1- to 50-fold the level of DNA MTase protein and enzyme activity of the parental cell line or clones transfected with the control vector alone (Neo). To determine the effects of DNA MTase overexpression on CpG island methylation, we examined 12 endogenous CpG island loci in the HMT clones. HMT clones expressing > or = 9-fold the parental levels of DNA MTase activity were significantly hypermethylated relative to at least 11 Neo clones at five CpG island loci. In the HMT clones, methylation reached nearly 100% at susceptible CpG island loci with time in culture. In contrast, there was little change in the methylation status in the Neo clones over the same time frame. Taken together, the data indicate that overexpression of DNA MTase can drive the de novo methylation of susceptible CpG island loci, thus providing support for the idea that DNA MTase can contribute to tumor progression through CpG island methylation-mediated gene inactivation.     

Structure of the bacteriophage T4 DNA adenine methyltransferase

DNA-adenine methylation at certain GATC sites plays a pivotal role in bacterial and phage gene expression as well as bacterial virulence. We report here the crystal structures of the bacteriophage T4Dam DNA adenine methyltransferase (MTase) in a binary complex with the methyl-donor product S-adenosyl-L-homocysteine (AdoHcy) and in a ternary complex with a synthetic 12-bp DNA duplex and AdoHcy. T4Dam contains two domains: a seven-stranded catalytic domain that harbors the binding site for AdoHcy and a DNA binding domain consisting of a five-helix bundle and a beta-hairpin that is conserved in the family of GATC-related MTase orthologs. Unexpectedly, the sequence-specific T4Dam bound to DNA in a nonspecific mode that contained two Dam monomers per synthetic duplex, even though the DNA contains a single GATC site. The ternary structure provides a rare snapshot of an enzyme poised for linear diffusion along the DNA.     

A simple and rapid method to obtain substitution mutations in Escherichia coli: isolation of a dam deletion/insertion mutation

We describe the isolation of a strain of Escherichia coli bearing a deletion/insertion (i.e., a substitution mutation) in the dam gene (dam-16). The mutagenesis protocol used should be applicable to any cloned non-essential gene of E. coli. The substitution mutation confers resistance to kanamycin and can easily be transferred to other strains by standard genetic techniques. The amount of Dam methyltransferase (MTase) in dam-16 strains as determined either in vitro or in vivo is below the level of detection. We conclude that the Dam MTase is not required for viability of E. coli.     

Comparative studies of the phage T2 and T4 DNA (N6-adenine)methyltransferases: amino acid changes that affect catalytic activity.

The bacteriophage T2 and T4 dam genes code for a DNA (N6-adenine)methyltransferase (MTase). Nonglucosylated, hydroxymethylcytosine-containing T2gt- virion DNA has a higher level of methylation than T4gt- virion DNA does. To investigate the basis for this difference, we compared the intracellular enzyme levels following phage infection as well as the in vitro intrinsic methylation capabilities of purified T2 and T4 Dam MTases. Results from Western blotting (immunoblotting) showed that the same amounts of MTase protein were produced after infection with T2 and T4. Kinetic analyses with purified homogeneous enzymes showed that the two MTases had similar Km values for the methyl donor, S-adenosyl-L-methionine, and for substrate DNA. In contrast, they had different k(cat) values (twofold higher for T2 Dam MTase). We suggest that this difference can account for the ability of T2 Dam to methylate viral DNA in vivo to a higher level than does T4 Dam. Since the T2 and T4 MTases differ at only three amino acid residues (at positions 20 [T4, Ser; T2, Pro], 26 [T4, Asn; T2, Asp], and 188 [T4, Asp; T2, Glu]), we have produced hybrid proteins to determine which residue(s) is responsible for increased catalytic activity. The results of these analyses showed that the residues at positions 20 and 26 are responsible for the different k(cat) values of the two MTases for both canonical and noncanonical sites. Moreover, a single substitution of either residue 20 or 26 was sufficient to increase the k(cat) of T4 Dam.     

Bacteriophage T4 Dam DNA-(N6-adenine)-methyltransferase. Processivity and orientation to the methylation target

We carried out steady state and pre-steady state (burst) kinetic analyses of the bacteriophage T4 Dam DNA-(N(6)-adenine)-methyltransferase (MTase)-mediated methyl group transfer from S-adenosyl-l-methionine (AdoMet) to Ade in oligonucleotide duplexes containing one or two specific GATC sites with different combinations of methylated and unmodified targets. We compared the results for ligated 40-mer duplexes with those of the mixtures of the two unligated duplexes used to generate the 40-mers. The salient results are as follows: (i) T4 Dam MTase modifies 40-mer duplexes in a processive fashion. (ii) During processive movement, T4 Dam rapidly exchanges product S-adenosyl-l-homocysteine (AdoHcy) for substrate AdoMet without dissociating from the DNA duplex. (iii) T4 Dam processivity is consistent with an ordered bi-bi mechanism AdoMet downward arrow DNA downward arrow DNA(Me) upward arrow AdoHcy upward arrow. However, in contrast to the steady state, here DNA(Me) upward arrow signifies departure from a methylated site GMTC upward arrow without physically dissociating from the DNA. (iv) Following methyl transfer at one site and linear diffusion to a hemimethylated site, a reconstituted T4 Dam-AdoMet complex rapidly reorients itself to the (productive) unmethylated strand. T4 Dam-AdoHcy cannot reorient at an enzymatically created GMTC site. (v) The inhibition potential of fully methylated sites 5'-GMTC/5'-GMTC is much lower for a long DNA molecule compared with short single-site duplexes.     

Identification and preliminary characterization of an O6-methylguanine DNA repair methyltransferase in the yeast Saccharomyces cerevisiae

Saccharomyces cerevisiae contains a DNA repair methyltransferase (MTase) that repairs O6-methylguanine. Methyl groups are irreversibly transferred from O6-methylguanine in DNA to a 25-kilodalton protein in S. cerevisiae cell extracts, and methyl transfer is accompanied by the formation of S-methylcysteine. The yeast MTase is expressed at approximately 150 molecules/cell in exponentially growing yeast cultures but is not detectable in stationary phase cells. Unlike mammalian and bacterial MTases, the yeast MTase is very temperature-sensitive, having a half-life of about 4 min at 37 degrees C, which may explain why others have failed to detect it. Like other DNA repair MTases, the S. cerevisiae MTase repairs O6-methylguanine more efficiently in double-stranded DNA than in single-stranded DNA. Synthesis of the yeast DNA MTase is apparently not inducible by sublethal exposures to alkylating agent, but rather MTase activity is depleted in cells exposed to low doses of alkylating agent. Judging from its molecular weight and substrate specificity, the yeast DNA MTase is more closely related to mammalian MTases than to Escherichia coli MTases.     

Sequence-structure-function studies of tRNA:m5C methyltransferase Trm4p and its relationship to DNA:m5C and RNA:m5U methyltransferases

Three types of methyltransferases (MTases) generate 5-methylpyrimidine in nucleic acids, forming m5U in RNA, m5C in RNA and m5C in DNA. The DNA:m5C MTases have been extensively studied by crystallographic, biophysical, biochemical and computational methods. On the other hand, the sequence-structure-function relationships of RNA:m5C MTases remain obscure, as do the potential evolutionary relationships between the three types of 5-methylpyrimidine-generating enzymes. Sequence analyses and homology modeling of the yeast tRNA:m5C MTase Trm4p (also called Ncl1p) provided a structural and evolutionary platform for identification of catalytic residues and modeling of the architecture of the RNA:m5C MTase active site. The analysis led to the identification of two invariant residues that are important for Trm4p activity in addition to the conserved Cys residues in motif IV and motif VI that were previously found to be critical. The newly identified residues include a Lys residue in motif I and an Asp in motif IV. A conserved Gln found in motif X was found to be dispensable for MTase activity. Locations of essential residues in the model of Trm4p are in very good agreement with the X-ray structure of an RNA:m5C MTase homolog PH1374. Theoretical and experimental analyses revealed that RNA:m5C MTases share a number of features with either RNA:m5U MTases or DNA:m5C MTases, which suggested a tentative phylogenetic model of relationships between these three classes of 5-methylpyrimidine MTases. We infer that RNA:m5C MTases evolved from RNA:m5U MTases by acquiring an additional Cys residue in motif IV, which was adapted to function as the nucleophilic catalyst only later in DNA:m5C MTases, accompanied by loss of the original Cys from motif VI, transfer of a conserved carboxylate from motif IV to motif VI and sequence permutation.     

Multiple domains are involved in the targeting of the mouse DNA methyltransferase to the DNA replication foci.

It has been shown that, during the S-phase of the cell cycle, the mouse DNA methyltransferase (DNA MTase) is targeted to sites of DNA replication by an amino acid sequence (aa 207-455) lying in the N-terminal domain of the enzyme [Leonhardt, H., Page, A. W., Weier, H. U. and Bestor, T. H. (1992) Cell , 71, 865-873]. In this paper it is shown, by using enhanced green fluorescent protein (EGFP) fusions, that other peptide sequences of DNA MTase are also involved in this targeting. The work focuses on a sequence, downstream of the reported targeting sequence (TS), which is homologous to the Polybromo-1 protein. This motif (designated as PBHD) is separated from the reported targeting sequence by a zinc-binding motif [Bestor , T. H. (1992) EMBO J , 11, 2611-2617]. Primed in situ extension using centromeric-specific primers was used to show that both the host DNA MTase and EGFP fusion proteins containing the targeting sequences were localized to centromeric, but not telomeric, regions during late S-phase and mitosis. Also found was that, in approximately 10% of the S-phase cells, the EGFP fusions did not co-localize with the centromeric regions. Mutants containing either, or both, of these targeting sequences could act as dominant negative mutants against the host DNA MTase. EGFP fusion proteins, containing the reported TS (aa 207-455), were targeted to centromeric regions throughout the mitotic stage which lead to the discovery of a similar behavior of the endogenous DNA MTase although the host MTase showed much less intense staining than in S-phase cells. The biological role of the centromeric localization of DNA MTase during mitosis is currently unknown.     

Electrogenerated chemiluminescence biosensing method for the detection of DNA methylation and assay of the methyltransferase activity

A novel electrogenerated chemiluminescence (ECL) biosensing method for highly sensitive detection of DNA methylation and assay of the CpG methyltransferase (M. SssI) activity was developed on basis of enzyme-linkage reactions and ruthenium complex served as an ECL tag. The ECL biosensing electrode was fabricated by self-assembling 5'-thiol modified 32-mer single-strand DNA (ss-DNA)-tagged with ruthenium bis (2,2'-bipyridine) (2,2'-bipyridine-4,4'-dicarboxylic acid)-ethylenediamine on the surface of a gold electrode, and then hybridized with complementary ss-DNA to form duplex DNA (ds-DNA). When M. SssI and S-adenosylmethionine were introduced, all cytosine residues within 5'-CG-3' of ds-DNA on the biosensing electrode were methylated. After the methylated biosensing electrode was treated by HpaII endonuclease, the un-methylated cytosines were cleaved, thus led to decrease ECL signal. The ECL intensity of ECL biosensing electrode is related to the methylation level and M. SssI activity in a fixed concentration HpaII endonuclease. The increased ECL intensity was direct proportion to M. SssI activity in the range from 0.05 to 100 U/mL with a detection limit of 0.02 U/mL. This work demonstrates that the combination of the enzyme-linkage reactions with a highly sensitive ECL technique is a great promising approach for the detection of DNA methylation level, assay of the activity of MTase, and evaluation of the capability of inhibitors for the methyltransferase.     

Functional analysis of an acid adaptive DNA adenine methyltransferase from Helicobacter pylori 26695

HP0593 DNA-(N(6)-adenine)-methyltransferase (HP0593 MTase) is a member of a Type III restriction-modification system in Helicobacter pylori strain 26695. HP0593 MTase has been cloned, overexpressed and purified heterologously in Escherichia coli. The recognition sequence of the purified MTase was determined as 5'-GCAG-3'and the site of methylation was found to be adenine. The activity of HP0593 MTase was found to be optimal at pH 5.5. This is a unique property in context of natural adaptation of H. pylori in its acidic niche. Dot-blot assay using antibodies that react specifically with DNA containing m6A modification confirmed that HP0593 MTase is an adenine-specific MTase. HP0593 MTase occurred as both monomer and dimer in solution as determined by gel-filtration chromatography and chemical-crosslinking studies. The nonlinear dependence of methylation activity on enzyme concentration indicated that more than one molecule of enzyme was required for its activity. Analysis of initial velocity with AdoMet as a substrate showed that two molecules of AdoMet bind to HP0593 MTase, which is the first example in case of Type III MTases. Interestingly, metal ion cofactors such as Co(2+), Mn(2+), and also Mg(2+) stimulated the HP0593 MTase activity. Preincubation and isotope partitioning analyses clearly indicated that HP0593 MTase-DNA complex is catalytically competent, and suggested that DNA binds to the MTase first followed by AdoMet. HP0593 MTase shows a distributive mechanism of methylation on DNA having more than one recognition site. Considering the occurrence of GCAG sequence in the potential promoter regions of physiologically important genes in H. pylori, our results provide impetus for exploring the role of this DNA MTase in the cellular processes of H. pylori.     

Methylation by a mutant T2 DNA [N(6)-adenine] methyltransferase expands the usage of RecA-assisted endonuclease (RARE) cleavage

Properties of a mutant bacteriophage T2 DNA [N:(6)-adenine] methyltransferase (T2 Dam MTase) have been investigated for its potential utilization in RecA-assisted restriction endonuclease (RARE) cleavage. Steady-state kinetic analyses with oligonucleotide duplexes revealed that, compared to wild-type T4 Dam, both wild-type T2 Dam and mutant T2 Dam P126S had a 1.5-fold higher k(cat) in methylating canonical GATC sites. Additionally, T2 Dam P126S showed increased efficiencies in methylation of non-canonical GAY sites relative to the wild-type enzymes. In agreement with these steady-state kinetic data, when bacteriophage lambda DNA was used as a substrate, maximal protection from restriction nuclease cleavage in vitro was achieved on the sequences GATC, GATN and GACY, while protection of GACR sequences was less efficient. Collectively, our data suggest that T2 Dam P126S can modify 28 recognition sequences. The feasibility of using the mutant enzyme in RARE cleavage with BCL:I and ECO:RV endonucleases has been shown on phage lambda DNA and with BCL:I and DPN:II endonucleases on yeast chromosomal DNA embedded in agarose.     

Pre-steady state kinetics of bacteriophage T4 dam DNA-[N(6)-adenine] methyltransferase: interaction with native (GATC) or modified sites

The DNA methyltransferase of bacteriophage T4 (T4 Dam MTase) recognizes the palindromic sequence GATC, and catalyzes transfer of the methyl group from S:-adenosyl-L-methionine (AdoMet) to the N(6)-position of adenine [generating N(6)-methyladenine and S:-adenosyl-L-homocysteine (AdoHcy)]. Pre-steady state kinetic analysis revealed that the methylation rate constant k(meth) for unmethylated and hemimethylated substrates (0.56 and 0.47 s(-1), respectively) was at least 20-fold larger than the overall reaction rate constant k(cat) (0.023 s(-1)). This indicates that the release of products is the rate-limiting step in the reaction. Destabilization of the target-base pair did not alter the methylation rate, indicating that the rate of target nucleoside flipping does not limit k(meth). Preformed T4 Dam MTase-DNA complexes are less efficient than preformed T4 Dam MTase-AdoMet complexes in the first round of catalysis. Thus, this data is consistent with a preferred route of reaction for T4 Dam MTase in which AdoMet is bound first; this preferred reaction route is not observed with the DNA-[C5-cytosine]-MTases.     

Gene transfer to suppress bone marrow alkylation sensitivity

Alkylating agents represent a highly cytotoxic class of chemotherapeutic compounds that are extremely effective anti-tumor agents. Unfortunately, alkylating agents damage both malignant and non-malignant tissues. Bone marrow is especially sensitive to damage by alkylating agent chemotherapy, and is a dose-limiting tissue when treating cancer patients. One strategy to overcome bone marrow sensitivity to alkylating agent exposure involves gene transfer of the DNA repair protein O(6)-methylguanine DNA methyltransferase (O(6)MeG DNA MTase) into bone marrow cells. O(6)MeG DNA MTase is of particular interest because it functions to protect against the mutagenic, clastogenic and cytotoxic effects of many chemotherapeutic alkylating agents. By increasing the O(6)MeG DNA MTase repair capacity of bone marrow cells, it is hoped that this tissue will become alkylation resistant, thereby increasing the therapeutic window for the selective destruction of malignant tissue. In this review, the field of O(6)MeG DNA MTase gene transfer into bone marrow cells will be summarized with an emphasis placed on strategies used for suppressing the deleterious side effects of chemotherapeutic alkylating agent treatment.     

Symmetry elements in DNA structure important for recognition/methylation by DNA [amino]-methyltransferases

The phage T4Dam and EcoDam DNA-[adenine-N6] methyltransferases (MTases) methylate GATC palindromic sequences, while the BamHI DNA-[cytosine-N4] MTase methylates the GGATCC palindrome (which contains GATC) at the internal cytosine residue. We compared the ability of these enzymes to interact productively with defective duplexes in which individual elements were deleted on one chain. A sharp decrease in k_cat was observed for all three enzymes if a particular element of structural symmetry was disrupted. For the BamHI MTase, integrity of the ATCC was critical, while an intact GAT sequence was necessary for the activity of T4Dam, and an intact GA was necessary for EcoDam. Theoretical alignment of the region of best contacts between the protein and DNA showed that in the case of a palindromic interaction site, a zone covering the 5′-symmetric residues is located in the major groove versus a zone of contact covering the 3′-symmetric residues in the minor groove. Our data fit a simple rule of thumb that the most important contacts are aligned around the methylation target base: if the target base is in the 5′ half of the palindrome, the interaction between the enzyme and the DNA occurs mainly in the major groove; if it is in the 3′ half, the interaction occurs mainly in the minor groove.     

Development of a PCR method for mycoplasma testing of Chinese hamster ovary cell cultures used in the manufacture of recombinant therapeutic proteins

Chinese hamster ovary (CHO) cell cultures used to produce biopharmaceuticals are tested for mycoplasma contamination as part of the ensurance of a safe and pure product. The current U.S. Food and Drug Administration (FDA) regulatory guideline recommends using two procedures: broth/agar cultures and DNA staining of indicator cell cultures. Although these culture methods are relatively sensitive to most species, theoretically capable of detecting as few as 1-10 cfu/ml of most species, the overall procedure is lengthy (28 d), costly and less sensitive to noncultivable species. The detection of mycoplasma using the polymerase chain reaction (PCR) method has been considered an alternative method because it is relatively fast (1-2 d), inexpensive, and independent of culture conditions, however, limitations in sensitivity (limit of detection >/=1000 cfu/ml) and the risk of false positive and false negative results have prevented PCR from replacing the traditional culture methods in the industrial setting. In this report, we describe a new PCR assay for mycoplasma detection that appears to resolve these issues while being sufficiently simple and inexpensive for routine use. This assay applies readily available techniques in DNA extraction together with a modified single-step PCR using a previously characterized primer pair that is homologous to a broad spectrum of mycoplasma species known to infect mammalian cell cultures. Analysis is made easy by the detection of only a single amplification product within a narrow size range, 438-470 bp. A high sensitivity and specificity for mycoplasma detection in CHO cell production cultures is made possible through the combination of three key techniques: 8-methoxypsoralen and UV light treatment to decontaminate PCR reagents of DNA; hot-start Taq DNA polymerase to reduce nonspecific priming events; and touchdown- (TD-) PCR to increase sensitivity while also reducing nonspecific priming events. In extracts of mycoplasma DNA, the limit of detection for eight different mycoplasma species is 10 genomic copies. In CHO cell production cultures containing gentamicin, the limit of detection for a model organism, gentamicin-resistant M. hyorhinis, is 1 cfu/ml. The sensitivity and specificity of this PCR assay for mycoplasma detection in CHO cell production cultures appear similar to the currently used culture methods and thus should be considered as an alternative method by the biopharmaceutical industry.     

Surface plasmon resonance sensor for heparin measurements in blood plasma

Surface plasmon resonance (SPR) was used as an affinity biosensor to determine absolute heparin concentrations in human blood plasma samples. Protamine and polyethylene imine (PEI) were evaluated as heparin affinity surfaces. Heparin adsorption onto protamine in blood plasma was specific with a lowest detection limit of 0.2 U/ml and a linear window of 0.2–2 U/ml. Although heparin adsorption onto PEI in buffer solution had indicated superior sensitivity to that on protamine, in blood plasma it was not specific for heparin and adsorbed plasma species to a steady-state equilibrium. By reducing the incubation time and diluting the plasma samples with buffer to 50%, the non-specific adsorption of plasma could be controlled and a PEI pre-treated with blood plasma could be used successfully for heparin determination. Heparin adsorption in 50% plasma was linear between 0.05 and 1 U/ml so that heparin plasma levels of 0.1–2 U/ml could be determined within a relative error of 11% and an accuracy of 0.05 U/ml.