Widespread existence of Cytosine methylation in yeast DNA measured by gas chromatography/mass spectrometry

DNA methylation is one of the major epigenetic modifications and has been involved in a number of biological processes in mammalian cells. Yeast is widely used as a model organism for studying cell metabolism, cell cycle regulation, and signal transduction. However, it remains controversial whether methylated cytosine (5-methylcytosine, 5mC) exists in the yeast genome. In the current study, we developed a highly sensitive method based on gas chromatography/mass spectrometry (GC/MS) and systematically examined the incidence of 5mC in 19 yeast strains, which represent 16 yeast species. Our results showed that DNA methylation is widespread in yeast and the genome-wide DNA methylation of the studied yeast strains ranged from 0.014 to 0.364%, which were 1 to 2 orders of magnitude lower than that in mammalian cells (i.e., 3-8%). Furthermore, we found that the 5mC content in yeast varied considerably at different growth stages and DNA methylation inhibitor 5-azacytidine could induce a decrease in genome-wide DNA methylation as that in mammalian cells. The demonstration of the universal presence of DNA cytosine methylation in yeast constituted the first and essential step toward understanding the functions of this methylation in yeast.     

Evaluating the global CpG methylation status of native DNA utilizing a bipartite split-luciferase sensor

Epigenetic modifications play an essential role in the regulation of gene expression and ultimately cell fate. Methylation of cytosine at CpG dinucleotides (mCpG) is an important epigenetic mark that has been correlated with cancer when present at promoter sites of tumor suppressor genes. To develop a rapid methodology for the direct assessment of global levels of DNA methylation, we first interrogated the methyl-CpG binding domains (MBDs), the Kaiso family of Cys(2)-His(2) zinc fingers, and an SET- and RING-associated domain using a split-luciferase reassembly methodology. We identified MBD1 as the most selective domain for the discrimination between mCpG and CpG sites with over 90-fold selectivity. Utilizing a bipartite strategy, we constructed a purely methylation-dependent bipartite sensor for the direct detection of global levels of DNA methylation by attaching MBD1 domains to each of the split-luciferase halves. This new sensor was validated for the direct determination of genomic DNA methylation levels in in vitro studies without any intervening chemical or enzymatic processing of DNA. Finally, we demonstrated that this bipartite sensor can be utilized for monitoring dose-dependent changes in global levels of methylation in DNA from HeLa cells challenged with 5-aza-2'-deoxycytidine, a DNA methyltransferase inhibitor.     

Signal amplification of graphene oxide combining with restriction endonuclease for site-specific determination of DNA methylation and assay of methyltransferase activity

Site-specific identification of DNA methylation and assay of MTase activity are important in determining specific cancer types, providing insights into the mechanism of gene repression, and developing novel drugs to treat methylation-related diseases. This work reports an electrochemical method for gene-specific methylation detection and MTase activity assay using HpaII endonuclease to improve selectivity and employing signal amplification of graphene oxide (GO) to enhance the assay sensitivity. The method was developed by designing a probe DNA, which was immobilized on electrode surface, to hybridize with target DNA (one 137 mer DNA from exon 8 promoter region of the Homo sapiens p53 gene, was extracted from HCT116 cells). The assay is based on the electrochemical responses of the reporter (thionine), which was conjugated to 3'-terminus of the probe DNA via GO, after the DNA hybrid was methylated (under catalysis of M.SssI MTase) and cleaved by HpaII endonuclease (a site-specific endonuclease recognizing the duplex symmetrical sequence of 5'-CCGG-3' and catalyzing cleavage between the cytosines). This model can determine DNA methylation at the site of CpG and has an ability to discriminate the target DNA sequence from even single-base mismatched sequence. The electrochemical signal has a linear relationship with M.SssI activities ranging from 0.1 to 450 U/mL with a detection limit of ～(0.05 ± 0.02) U/mL at a signal/noise of 3. The advantages of this assay are ease of performance having a good specificity and selectivity. In addition, we also demonstrate the method can be used for rapid evaluation and screening of the inhibitors of MTase and has a potential application in discovery of new anticancer drugs.     

Electrochemical DNA sensors based on enzyme dendritic architectures: an approach for enhanced sensitivity

The modification of enzymes with multiple single-stranded oligonucleotides opens up a new concept for the development of DNA sensors with enhanced sensitivity. This work describes the generation of reporter sequences labeled with an enzyme for the demonstration of their ability to specifically hybridize and to permit signal amplification by successive hybridization steps. The synthetic pathway for the labeling of GOx with oligonucleotide sequences is based on the oxidation of the glycosidic residues of the enzyme and their covalent binding with 5'-end amine-modified oligonucleotides. Spectrophotometric characterization of these functionalized sequences results in an average number of three linked oligonucleotides per enzyme molecule. Their specificity is demonstrated in both a direct and a sandwich-type hybridization assay. The transduction of the enzyme-linked DNA sensors is based on self-assembled multilayers, including a chemically modified anionic horseradish peroxidase electrochemically connected to a water-soluble cationic poly[(vinylpyridine)Os(bpy)(2)Cl] redox polymer in an electrostatic ordered assembly. The sensing layer is constructed by the covalent binding of the DNA probe over the redox polymer through the 3'-phosphate group, enabling the capture of the target sequence. Upon addition of glucose, hybridization results in the production of H(2)O(2), which readily diffuses to the electrocatalytic assembly, giving rise to a cathodic current at 100 mV vs Ag/AgCl. Hybridization is always performed at room temperature, and after 30 min of incubation, an amperometric response is obtained that is proportional to DNA concentration. The simultaneous sandwich assay enables the quantification of a free-label 44-mer oligonucleotide at 1 nM concentration. Signal amplification is realized by a new hybridization step over the free sequences, giving rise to a dendritic architecture that accumulates enzyme molecules per hybridization event.     

Hairpin fluorescence DNA probe for real-time monitoring of DNA methylation

DNA methylation catalyzed by methylase plays an important role in many biological events. However, traditional methods of methylase activity analysis by gel electrophoresis were laborious and discontinuous. In this paper, we report a new strategy to study methylase activity using fluorescent probes coupled with enzyme-linkage reactions. A hairpin DNA probe is prepared with a fluorophore and a quencher linked at the 5'- and 3'-terminus of the probe. A disturbance of the stem sequence by DNA methylation would cause the separation of the fluorophore and the quencher, resulting in the restoration of the fluorescence. We used DNA adenine methylation (Dam) methyltransferase (MTase) and Dpn I endonuclease, both having a 5'-G-A-T-C-3' recognition sequence. Dam MTase catalyzed the methylation of the sequence of 5'-GATC-3', and Dpn I cut the sequence of 5'-G-Am-T-C-3'. The fluorescence of the hairpin probe was restored when it was cleaved by Dpn I endonuclease during the course of methylation. Unlike traditional methods, this assay was done in real time and could be used to monitor the dynamic process of methylation. Our method is easy, simple, and nonradioactive, yet as efficient as gel electrophoresis in detecting the activity of methylase. It also had the potential to screen suitable inhibitor drugs for Dam methylase.     

Voltammetric determination of underivatized oligonucleotides on graphite electrodes based on their oxidation products

A new electrochemical method to determine underivatized oligonucleotides is developed. The electro-oxidation of the adenine moieties of adsorbed oligonucleotides at elevated potentials on pyrolytic graphite electrodes (PGE) in neutral or alkaline media gives rise to electroactive products strongly adsorbed on the electrode surface. The extent of the redox processes of these products, with formal potential close to 0 V (vs Ag /AgCl) at pH 10, correlates well with the amount of parent oligonucleotide. Various electrochemical techniques have been compared and applied to the detection of specific DNA sequences and synthetic homopolynucleotides. Detection limits of 2 and 10 ng for (dA)20 and a 21-mer sequence of HIV-1, respectively, have been achieved using sample volumes of 10 microL. Moreover, the adsorbed oxidized oligonucleotide shows electrocatalytic activity toward the oxidation of NADH. The capability of the new method to detect DNA hybridization is discussed.     

One-step label-free optical genosensing system for sequence-specific DNA related to the human immunodeficiency virus based on the measurements of light scattering signals of gold nanorods

A one-step label-free optical genosensing method has been developed in this contribution by taking short DNA target with its sequence related to the human immunodeficiency virus type 1 (HIV-1) as an example. By employing anisotropic nonspherical and positively charged gold nanorods (Au-NRs) as the recognition platform, which show high stability against aggregation under high ionic strength conditions without any additional stable reagent, we found that the addition of target DNA to the mixture of nonmodified Au-NRs suspension and label-free probe DNA in high ionic strength buffer leads to a color change from red to light purple in less than 5 min, displaying strong plasmon resonance light scattering (PRLS) signals. Mechanism investigations showed that the strong PRLS signals should be ascribed to the aggregation of Au-NRs induced by the formed double-stranded oligonucleotides (dsDNA) from the hybridization of target DNA with probe DNA. With the PRLS signals, we monitored the hybridization process of a 21-mer single-stranded oligonucleotide (ssDNA) from the HIV-1 U5 long terminal repeat (LTR) sequence with its complementary oligonucleotide and detected the effect of single-base-pair mismatches. Two polymerase chain reaction (PCR) amplicon artificial samples derived from Mycobacterium tuberculosis glmS and genes encoding for Bacillus glucanase and an HIV-1 LTR sample isolated from HIV-1-positive blood were detected with satisfactory results, showing that the present method has simplicity, sensitivity, specificity, and reliability for sequence-specific DNA detection related to the HIV gene.     

A fluorescence-based method for determining the surface coverage and hybridization efficiency of thiol-capped oligonucleotides bound to gold thin films and nanoparticles

Using a fluorescence-based method, we have determined the number of thiol-derivatized single-stranded oligonucleotides bound to gold nanoparticles and their extent of hybridization with complementary oligonucleotides in solution. Oligonucleotide surface coverages of hexanethiol 12-mer oligonucleotides on gold nanoparticles (34 +/- 1 pmol/cm2) were significantly higher than on planar gold thin films (18 +/- 3 pmol/cm2), while the percentage of hybridizable strands on the gold nanoparticles (1.3 +/- 0.3 pmol/cm2, 4%) was lower than for gold thin films (6 +/- 2 pmol/cm2, 33%). A gradual increase in electrolyte concentration over the course of oligonucleotide deposition significantly increases surface coverage and consequently particle stability. In addition, oligonucleotide spacer sequences improve the hybridization efficiency of oligonucleotide-modified nanoparticles from approximately 4 to 44%. The surface coverage of recognition strands can be tailored using coadsorbed diluent oligonucleotides. This provides a means of indirectly controlling the average number of hybridized strands per nanoparticle. The work presented here has important implications with regard to understanding interactions between modified oligonucleotides and metal nanoparticles, as well as optimizing the sensitivity of gold nanoparticle-based oligonucleotide detection methods.     

Split beta-lactamase sensor for the sequence-specific detection of DNA methylation

The methylation pattern of genes at CpG dinucleotide sites is an emerging area in epigenetics. Furthermore, the hypermethylation profiles of tumor suppressor genes are linked to specific tumor types. Thus, new molecular approaches for the rapid determination of the methylation status of these genes could provide a powerful method for early cancer diagnosis as well as insight into mechanisms of epigenetic regulation of genetic information. Toward this end, we have recently reported the first design of a split-protein sensor for the site-specific detection of DNA methylation. In this approach a split green fluorescent protein reporter provided a sequence-specific readout of CpG methylation. In the present work, we describe a sensitive second-generation methylation detection system that utilizes the split enzymatic reporter, TEM-1 beta-lactamase, attached to specific DNA binding elements. This system, termed mCpG-SEER-beta-Lac, shows a greater than 40-fold specificity for methylated versus nonmethylated CpG target sites. Importantly, the resulting signal enhancement afforded by the catalytic activity of split-beta-lactamase allowed for the sensitive detection of 2.5 fmol of methylated target dsDNA in 5 min. Thus, this new sensor geometry represents a 250-fold enhancement in assay time and a 2000-fold enhancement in sensitivity over our first-generation system for the detection of specific sites of DNA methylation.     

Assembly fabrication of oligonucleotide arrays

In this paper, a simple, reliable and flexible method for fabricating oligonucleotide arrays integrating in in-situ synthesis with a spotting technique is described. In this approach, different oligonucleotide sequences were synthesized on coded modification glass slides using combinatorial chemistry and a mature phosphoramidite chemistry protocol. The slides were then sliced into smaller pieces. Finally, an oligonucleotide array was fabricated by arbitrarily assembling the different coded pieces onto another solid support. A 5 x 5 array including four different sequences of the P16 gene and a control (blank) was successfully assembled. The results indicated that the hybridization fluorescence intensities from the same sequences located at different places on the array were homogeneous and uniform. Background fluorescence was much lower. The fluorescence intensity ratio of a matched sequence to a one-base mismatched sequence, a two-base mismatched sequence and a three-base mismatched sequence was 0.499, 0.236 and 0.04, respectively. The results for the same sequence at different spots in the chip were reproducible with the relative standard deviation ranging from 6.64% to 10.2% (n = 5). This method has the advantages of high probe-density of in-situ synthesis, and off-chip flexibility. Moreover, it does not need any immobilization process to bond oligonucleotides on the substrate.     

Detection of DNA hybridization using the near-infrared band-gap fluorescence of single-walled carbon nanotubes

We demonstrate the optical detection of DNA hybridization on the surface of solution suspended single-walled carbon nanotubes (SWNTs) through a SWNT band gap fluorescence modulation. Hybridization of a 24-mer oligonucleotide sequence with its complement produces a hypsochromic shift of 2 meV, with a detection sensitivity of 6 nM. The energy shift is modeled by correlating the surface coverage of DNA on SWNT to the exciton binding energy, yielding an estimated initial fractional coverage of 0.25 and a final coverage of 0.5. Hybridization on the nanotube surface is confirmed using Forster resonance energy transfer of fluorophore-labeled DNA oligonucleotides. This detection is enabled through a new technique to suspend SWNTs using adsorption of single-stranded DNA and subsequent removal of free DNA from solution. While the kinetics of free DNA hybridization are relatively fast (<10 min), the kinetics of the process on SWNTs are slower under comparable conditions, reaching steady state after 13 h at 25 degrees C. A second-order kinetic model yields a rate constant of k = 4.33 x 10(5) (M h)(-1). This optical, selective detection of specific DNA sequences may have applications in the life sciences and medicine as in vitro or in vivo detectors of oligonucleotides.     

Effect of oligonucleotide truncation on single-nucleotide distinction by solid-phase hybridization.

Oligonucleotide microarrays are used to analyze target sequences on the basis of differences in hybridization stability between matched and mismatched probe-target duplexes. DNA microarray manufacture via photolithographic synthesis generates a minority of full-length oligonucleotide probes along with a series of 5'-truncated contaminants. In a model experiment, we now investigate the effect of truncated oligonucleotides on the ability to distinguish target sequence variants that differ in a single nucleotide position. A series of oligonucleotides, mixed in proportions simulating stepwise synthetic yields of between 82 and 100%, were bound to a solid support and allowed to hybridize to a target molecule. The extent of hybridization was monitored over a range of temperatures via the fluorescence of a double-strand-specific dye. The discriminatory power of pure oligonucleotide probes was found to be significantly greater than that of a population of truncated probes, but only over a limited temperature interval. We conclude that at optimal temperatures greater oligonucleotide quality can improve the performance of oligonucleotide hybridization microarrays.     

Oligonucleotide mixture analysis via electrospray and ion/ion reactions in a quadrupole ion trap

Electrospray ionization combined with ion/ion reactions in a quadrupole ion trap can be used for the direct analysis of oligonucleotide mixtures. Elements to the success of this approach include factors related to ionization, ion/ion reactions, and mass analysis. This paper deals with issues regarding the ion polarity combination, viz., positive oligonucleotides/negative charge-transfer agent versus negative oligonucleotides/positive charge-transfer agent. Anions derived from perfluorocarbons appear to be directly applicable to mixtures of positive ions derived from electrospray of oligonucleotides, in direct analogy with positive protein ions. Conditions for forming positive oligonucleotide ions devoid of adducts were more difficult to establish than for forming relatively clean negative oligonucleotide ions. A new approach for manipulating negative ion charge states in the ion trap is described and is based on use of the electric field of the positive charge-transfer agent for storage of high-mass negative ions formed during the ion/ion reaction period. Oxygen cations are shown to be acceptable for charge-state manipulation of mixed-base oligomers but induce fragmentation in polyadenylate homopolymers. Protonated isobutylene (C4H9+), on the other hand, is shown to induce significantly less fragmentation of polyadenylate homopolymers.     

Determination of DNA methylation using electrochemiluminescence with surface accumulable coreactant

Cytosine methylation in DNA was determined by an enzyme linked immunosorbent assay (ELISA) with electrochemiluminescence (ECL) detection and employed for the DNA methylation assay of a long and real genomic sample for the first time. The developed method employed an antimethyl cytosine antibody labeled with acetylcholinesterase, which was added to recognize single methylated cytosine in a DNA oligomer. The acetylcholinesterase converted acetylthiocholine (substrate) to thiocholine (product), which was accumulated on a gold electrode surface via gold-thiol binding. This surface accumulated preconcentration made it possible to observe bright and distinctive ECL by applying a potential to the gold electrode in the presence of a tris(2,2-bipyridyl)ruthenium complex luminophore when the analyte DNA contained a methylation region. Methyl-cytosine was measured quantitatively in the 1-100 pmol range, which exhibits sufficiently high sensitivity to achieve real DNA measurements without amplification by a polymerase chain reaction (PCR). The proposed ECL method also exhibited high selectivity for methyl-cytosine against nonmethylated cytosine, guanine, thymine, and adenine nucleotides. Finally, original and methylated DNA samples were clearly distinguished with our method using a real DNA bacteriophage sample (48,502 base pairs).     

MALDI MS analysis of oligonucleotides: desalting by functional magnetite beads using microwave-assisted extraction

The presence of alkali cation adductions of oligonucleotides commonly deteriorates matrix-assisted laser desorption/ionization (MALDI) mass spectra. Thus, desalting is required for oligonucleotide samples prior to MALDI MS analysis in order to prevent the mass spectra from developing poor quality. In this paper, we demonstrate a new approach to extract traces of oligonucleotides from aqueous solutions containing high concentrations of salts using microwave-assisted extraction. The C18-presenting magnetite beads, capable of absorbing microwave irradiation, are used as affinity probes for oligonucleotides with the addition of triethylammonium acetate as the counterions. This new microwave-assisted extraction approach using magnetite beads as the trapping agents and as microwave-absorbers has been demonstrated to be very effective in the selective binding of oligonucleotides from aqueous solutions. The extraction of oligonucleotides from solutions onto the C18-presenting magnetite beads takes only 30 s to enrich oligonucleotides in sufficient quantities for MALDI MS analysis. After using this desalting approach, alkali cation adductions of oligonucleotides are dramatically reduced in the MALDI mass spectra. The presence of saturated NaCl (approximately 6 M) in the oligonucleotide sample is tolerated without degrading the mass spectra. The detection limit for d(A)6 is approximately 2.8 fmol.     

Steric factors controlling the surface hybridization of PCR amplified sequences

This study elucidated the hybridization behavior of surface-bound oligonucleotides to their longer PCR-amplified targets. The screen-printed gold surface of disposable electrodes was the platform onto which thiol-tethered oligonucleotides (21-mer) were immobilized by chemisorption. As a model case, approximately 600-bp amplicons were studied. Surface hybridization was monitored by means of an enzyme-linked assay with electrochemical detection. Use of different surface-tethered probe sequences over a wide range of surface densities was explored to achieve the highest duplex yield. Both the surface coverage by the probe and its relative position on the target strand were found to control the efficiency of capture of the target sequence. Interfacial hybridization occurred with the highest efficiency for a probe coverage of approximately 2.9 x 10(12) molecules/cm2 and when the 3' end of the amplicon was involved. An unusual (bell-shaped) response/amplicon concentration profile was additionally found. It was hypothesised that when the amount of solution-phase target is relatively high, random collisions make reannealing of the approximately 600-bp strands favored over formation of the surface-tethered probe-amplicon complex. This paper also describes a strategy to enhance the sensitivity of enzyme-linked hybridization assays. Such a strategy relies on formation, around the long target sequence, of dendritic-like structures, which could offer multiple anchoring points for the enzyme conjugate. The results shown in this work might have great significance for the practical application of hybridization to oligonucleotide chips.     

Selective derivatization of cytosine and methylcytosine moieties with 2-bromoacetophenone for submicrogram DNA methylation analysis by reversed phase HPLC with spectrofluorimetric detection

In eukaryotes, actual DNA methylation patterns provide biologically important information, for which both, genome-wide and locus-specific methylation at cytosine residues have been extensively studied. The original contribution of this work relies on the selective derivatization of cytosine moieties with 2-bromoacetophenone for the determination of global DNA methylation by reversed phase high performance liquid chromatography with spectrofluorimetric detection. The important features of the proposed procedure are as follows: (1) no need for the elimination of RNA, (2) detection limits for cytidine, 2'-deoxycytidine, 5-methylcytidine, and 5-methyl-2'-deoxycytidine in the range of 14.4-22.7 fmol, (3) feasibility for the detection of 0.06% of methylation in a low amount of DNA (80 ng), (4) potential viability for the evaluation of RNA methylation, and (5) relative simplicity in terms of analytical instrumentation and personnel training. The results obtained in the analysis of salmon testes DNA and nucleic acids from plant, human blood, and earthworms demonstrate the utility of the proposed procedure in biological studies and, in particular, for evaluation of the potential effect of environmental factors on actual DNA methylation in different types of living organisms.     

Selective interactions of ethidiums with G-quadruplex DNA revealed by surface-enhanced Raman scattering

Complexes formed between G-quadruplex (G4)-conformed oligonucleotides and four ethidium derivatives were studied by surface-enhanced Raman spectroscopy (SERS) to detail the topology of complexes that support a G4 stabilization. Ethidium bromide (EB), which presents a weak ability to stabilize oligonucleotides in G4 conformation, displayed no SERS intensity modification when bound to G4, as compared with the free EB. Three ethidium derivatives have been selected due to their higher ability to stabilize G4 than EB. Bound with G4-conformed oligonucleotides, SERS intensity of these three ethidiums decreased by factors of about 6, 3.5, and 15. The high SERS quenching was interpreted as a loss of accessibility of silver colloids for G4-bound ethidiums. This could represent a new selective parameter useful to identify G4-stabilizing molecules. To apraise the role of the oligonucleotide sequence on the interaction mode, complexes were formed with eight G4-conformed oligonucleotides in which the three loops were either 5'-TTA-3' or 5'-AAA-3'. Spectra of ethidiums were sensitive to both lateral loops, opposite to the 3' and 5' G4 ends. The sequence of these loops are believed to be selective in the interaction mode of ethidiums for G4.