Sensitive detection of DNA methyltransferase activity based on rolling circle amplification technology

This work develops a fluorescence approach for sensitive detection of DNA methyltransferase activity based on endonuclease and rolling circle amplification （RCA） technique. In the presence of DNA adenine methylation （Dam） MTase, the methylation-responsive sequence of hairpin probe is methylated and cleaved by the methylation-sensitive restriction endonuclease Dpn 1. The products cleaved by restriction endonuclease Dpn I then function as a signal primer to initiate RCA reaction by hybridizing with the circular DNA template. Each RCA product containing thousands of repeated sequences might hybridize with a large number of molecular beacons （detection probes）, resulting in an enhanced fluorescence signal. In the absence of Dam MTase, neither methylation/cleavage nor RCA reaction can be initiated and no fluorescence signal is observed. The proposed method exhibits a dynamic range from 0.5 U/mL to 30 U/mL and a detection limit of 0.18 U/mL. This method can be used for the screening of antimicrobial drugs and has a great potential to be further applied in early clinical diagnosis.     

Sensitive detection of DNA methyltransferase activity based on supercharged fluorescent protein and template-free DNA polymerization

DNA methylation, catalyzed by DNA methyltransferases(MTases), is a key component of genetic regulation, and DNA MTases have been regarded as potential targets in anticancer therapy. Herein, based on our previously developed DNA-mediated supercharged green fluorescent protein(Sc GFP)/graphene oxide(GO) interaction, coupled with methylation-initiated template-free DNA polymerization, we propose a novel fluorescence assay strategy for sensitive detection of DNA MTase activity. A hairpin DNA with a methylation-sensitive site and an amino-modified 3′-terminal(DNA-1) was designed and worked as a starting molecule. In the presence of DNA MTase, methylation-sensitive restriction endonuclease, and terminal deoxynucleotidyl transferase(Td T), DNA-1 can be sequentially methylated, cleaved, and further elongated. The resulting long DNA fragments quickly bind with Sc GFP and form the Sc GFP/DNA nanocomplex. Such nanocomplex can effectively protect Sc GFP from being adsorbed and quenched by GO. Without the methylation-initiated DNA polymerization, the fluorescence of Sc GFP will be quenched by GO. Thus, the DNA MTase activity, which is proportional to the amount of DNA polymerization products, can be measured by reading the fluorescence of Sc GFP/GO. The method was successfully used to detect the activity of DNA adenine methylation(Dam) MTase with a wide linear range(0.1–100 U/m L) and a low detection limit of 0.1 U/m L. In addition, the method showed high selectivity and the potential to be applied in a complex sample. Furthermore, this study was successfully extended to evaluate the inhibition effect of 5-fluorouracil on Dam MTase activity and detect Td T activity.     

A colorimetric assay of DNA methyltransferase activity based on the keypad lock of duplex DNA modified meso-SiO2@Fe3O4

Abnormal level of DNA methyltransferase (MTase) – mediated DNA methylation is closely related with cancer and bacterial diseases. Herein, a novel strategy based on the keypad lock of duplex DNA modified meso-SiO₂@Fe₃O₄ was developed for colorimetric assay of Dam MTase activity. When the Dam MTase was introduced, the duplex DNA can be methylated at a palindrome sequence of 5′-GATC-3′ and cleaved by the methylation-sensitive restriction endonuclease Dpn I. Due to the instability of the newly formed DNA fragment, the hybrid will separated into a single-stranded DNA. Then the keypad lock will open, and the catalytic reaction of TMB and H₂O₂ can be initiated through the pores of meso-SiO₂@Fe₃O₄, and a high color signal can be clearly observed by the naked eye. Contrarily, without Dam MTase, the catalytic reaction will not be initiated, and result no color signal. The proposed method exhibited a wide dynamic range with a low detection limit of 0.73 U/mL. Additionally, this way can be performed in human serum with satisfying recovery. And the inhibition of Dam MTase can also be well demonstrated by using paclitaxel as a model. Therefore, the designed way not only provides a platform for monitoring Dam MTase activity, but also useful for further application in disease diagnosis and drug discovery.     

Coupling hybridization chain reaction with DNAzyme recycling for enzyme-free and dual amplified sensitive fluorescent detection of methyltransferase activity

Aberrant DNA methylation originated from changes in DNA methyltransferase activity can lead to many genetic diseases and tumor types, and the monitoring of methyltransferase activity is thus of great importance in disease diagnosis and drug screening. In this work, by combing hybridization chain reaction (HCR) and metal ion-dependent DNAzyme recycling, we have developed a convenient enzyme-free signal amplification strategy for highly sensitive detection of DNA adenine methyltransferase (Dam MTase) activity and its inhibitors. The Dam MTase-induced methylation and subsequent cleavage of the methylated hairpin DNA probes by DpnI endonuclease lead to the release of ssDNA triggers for HCR formation of many Mg²⁺-dependent DNAzymes, in which the fluorescently quenched substrate sequences are catalytically and cyclically cleaved by Mg²⁺ to generate remarkably amplified fluorescent signals for highly sensitive detection of Dam MTase at 7.23 × 10⁻⁴ U/mL. In addition, the inhibition of different drugs to Dam MTase activity can also be evaluated with the developed method. With the advantages of simplicity and significant signal amplification over other common methods, the demonstrated biosensing approach thus offers great potential for highly sensitive detection of various methyltransferases and provides a convenient platform for drug screening for therapeutic applications.     

High Sensitive Electrochemiluminescence Biosensor Based on Ru(phen)32+-loaded Double Strand DNA as Signal Tags use to Detect DNA Methyltransferase Activity

DNA methyltransferase (DNA MTase) can act as biomarker for many diseases and it is important to develop some new methods for sensitive detection of DNA MTase. In this work, a highly efficient electrochemiluminescence (ECL) sensor had been designed for detection of DNA MTase based on Ru(phen)₃²⁺ loaded double strand DNA (dsDNA- Ru(phen)₃²⁺) as signal tags. Ru(phen)₃²⁺ had been efficiently embed in the dsDNA produced through a simple hybridization chain reaction. First, a hairpin probe was designed, which can be specifically recognized by Dam MTase and modified with -SH at one end. It was modified on the surface of gold electrode by -SH as an immobilization probe (IP). This IP will be methylated in the present of Dam MTase and digested by DpnI following. Results in the release of capture probe (CP) which remains on the surface of gold electrode. The CP can hybridize with the single stand part of the dsDNA- Ru(phen)₃²⁺ and make the immobilization of ECL tags on the electrode surface, which results in a strong ECL signals detected. However, without the effect of Dam MTase, the hairpin structure of IP remains stable and cannot capture signal tags, and can only detecte weak ECL signals. The biosensor can detect the activity of Dam MTase in the concentration range of 0.01 U/mL to 20 U/mL with the ECL intensity and the logarithm of the concentration have a linear relationship, and the detection limit is calculated to be 7.6 mU/mL. The developed sensor has the ability to specifically detect Dam MTase, which can be differentiated from other types of DNA MTase. In addition, the designed method has good applicability to detect Dam MTase activity in serum samples and been applied to detect its inhibitor with high efficiency.     

Electrochemical strategy for sensing DNA methylation and DNA methyltransferase activity

The present work demonstrates a novel signal-off electrochemical method for the determination of DNA methylation and the assay of methyltransferase activity using the electroactive complex [Ru(NH₃)₆]³⁺ (RuHex) as a signal transducer. The assay exploits the electrostatic interactions between RuHex and DNA strands. Thiolated single strand DNA1 was firstly self-assembled on a gold electrode via Au–S bonding, followed by hybridization with single strand DNA2 to form double strand DNA containing specific recognition sequence of DNA adenine methylation MTase and methylation-responsive restriction endonuclease Dpn I. The double strand DNA may adsorb lots of electrochemical species ([Ru(NH₃)₆]³⁺) via the electrostatic interaction, thus resulting in a high electrochemical signal. In the presence of DNA adenine methylation methyltransferase and S-adenosyl-l-methionine, the formed double strand DNA was methylated by DNA adenine methylation methyltransferase, then the double strand DNA can be cleaved by methylation-responsive restriction endonuclease Dpn I, leading to the dissociation of a large amount of signaling probes from the electrode. As a result, the adsorption amount of RuHex reduced, resulting in a decrease in electrochemical signal. Thus, a sensitive electrochemical method for detection of DNA methylation is proposed. The proposed method yielded a linear response to concentration of Dam MTase ranging from 0.25 to 10 U mL⁻¹ with a detection limit of 0.18 U mL⁻¹ (S/N = 3), which might promise this method as a good candidate for monitoring DNA methylation in the future.     

Sensitive electrochemical assaying of DNA methyltransferase activity based on mimic-hybridization chain reaction amplified strategy

A mimic-hybridization chain reaction (mimic-HCR) amplified strategy was proposed for sensitive electrochemically detection of DNA methylation and methyltransferase (MTase) activity In the presence of methylated DNA, DNA-gold nanoparticles (DNA-AuNPs) were captured on the electrode by sandwich-type assembly. It then triggered mimic-HCR of two hairpin probes to produce many long double-helix chains for numerous hexaammineruthenium (III) chloride ([Ru(NH₃)₆]³⁺, RuHex) inserting. As a result, the signal for electrochemically detection of DNA MTase activity could be amplified. If DNA was non-methylated, however, the sandwich-type assembly would not form because the short double-stranded DNAs (dsDNA) on the Au electrode could be cleaved and digested by restriction endonuclease HpaII (HapII) and exonuclease III (Exo III), resulting in the signal decrement. Based on this, an electrochemical approach for detection of M.SssI MTase activity with high sensitivity was developed. The linear range for M.SssI MTase activity was from 0.05 U mL⁻¹ to 10 U mL⁻¹, with a detection limit down to 0.03 U mL⁻¹. Moreover, this detecting strategy held great promise as an easy-to-use and highly sensitive method for other MTase activity and inhibition detection by exchanging the corresponding DNA sequence.     

Electrochemical immunoassays for the detection the activity of DNA methyltransferase by using the rolling circle amplification technique

We report on an electrochemical method for the determination of the activity of the enzyme methyltransferase (MTase). The methyl-binding domain-1 protein was applied to recognize symmetrically methylated cytosine in CpG (-C-phosphate-G-) islands of ds-DNA which then specifically bind to anti-His tag antibody. Hyperbranched rolling circle amplification (RCA) was used to improve sensitivity. When the dsDNA was treated with M.Sss I methyltransferase, the sequence 5′-CCGG-3′ was methylated and recognized by the methyl binding protein. In turn, the anti-His tag, biotinylated IgG, streptavidin and biotinylated oligonucleotide were captured successively on the surface of an electrode. Subsequently, the RCA reaction was initiated and streptavidin-labeled alkaline phosphatase immobilized on the surface of the electrode. ALP was able to catalyze the hydrolysis of 1-naphthyl phosphate to form 1-naphthol at pH 9.8. The oxidation peak current of 1-naphthol was used to monitor the methylation process. The response obtained by differential pulse voltammetry was linearly related to the concentration of M.Sss I MTase in the range from 0.1 to 40 unit mL^?1, and the detection limit was 0.03 unit mL^?1 (at an SNR of 3). The inhibitory action of paclitaxel on the activity of M.Sss I MTase also was investigated.

Proximity-based electrochemical biosensor for highly sensitive determination of methyltransferase activity using gold nanoparticle-based cooperative signal amplification

We describe a turn-on electrochemical biosensor for the detection of methyltransferases (MTases) causing DNA adenine methylation. This biosensor is based on insertion, methylation-resistant cleavage, signal enrichment caused by gold nanoparticles (AuNPs), and a signal probe-dragging strategy. A double-stranded DNA (dsDNA) containing identical MTase and methylation-resistant endonuclease (Mbo I) sites was immobilized on the surface of a gold electrode via Au-S covalent binding. The surface was subsequently treated with MTase and Mbo I and then washed. Results revealed that the surface of the electrode contains methylated dsDNA and 12-base nucleotides residual. Depending on biotin-streptavidin interactions that enabled signal probes and nucleotide residue hybridization and AuNP enrichment, a large number of signal probes labeled with ferrocene (Fc) are captured by the electrode. Under optimal conditions, the differential pulse voltammetry signals of Fc tags (at a working voltage of 0.24 V vs. Ag/AgCl) are linearly related to the log of the MTase activity in the 0.1 to 40 U·mL⁻¹ range. The dynamic range extends from 0.05 to 50 U·mL⁻¹, and the limit of detection is 0.024 U·mL⁻¹ (at an S/N ratio of 3). The assay is well reproducible and highly selective. In our perception, this strategy provides a promising approach for simple, sensitive and selective detection of Dam MTase and may be extended to the determination of other MTase by exchanging the corresponding DNA.

Proximity-based electrochemical biosensor for highly sensitive detection of DNA adenine methylation methyltransferase (Dam MTase) activity using methylation-resistant cleavage coupled with gold nanoparticle based cooperative signal amplification.

     

DNA-based hybridization chain reaction amplification for assaying the effect of environmental phenolic hormone on DNA methyltransferase activity

In this work, a novel electrochemical protocol with signal amplification for determination of DNA methylation and methyltransferase activity using DNA-based hybridization chain reaction (HCR) was proposed. After the gold electrode was modified with dsDNA, it was treated with M.SssI MTase, HpaII endonuclease, respectively. And then the HCR was initiated by the target DNA and two hairpin helper DNAs, which lead to the formation of extended dsDNA polymers on the electrode surface. The signal was amplified by the labeled biotin on the hairpin probes. As a result, the streptavidin-alkaline phosphatase (S-ALP) conjugated on the electrode surface through the specific interaction between biotin and S-ALP. ALP could convert 1-naphthyl phosphate into 1-naphthol and the latter could be electrochemically oxidized, which was used to monitor the methylation event and MTase activity. The HCR assay presents good electrochemical responses for the determination of M.SssI MTase at a concentration as low as 0.0067 unit mL⁻¹. Moreover, the effects of anti-cancer drug and environmental phenolic hormone on M.SssI MTase activity were also investigated. The results indicated that 5-fluorouracil and daunorubicin hydrochloride could inhibit the activity, and the opposite results were obtained with bisphenol A and nonylphenol. Therefore, this method can not only provide a platform to screen the inhibitors of DNA MTase and develop new anticancer drugs, but also offer a novel technique to investigate the possible carcinogenesis mechanism.     

Cytosine-5 methylation-directed construction of a Au nanoparticle-based nanosensor for simultaneous detection of multiple DNA methyltransferases at the single-molecule level

DNA methylation at cytosine/guanine dinucleotide islands (CpGIs) is the most prominent epigenetic modification in prokaryotic and eukaryotic genomes. DNA methyltransferases (MTases) are responsible for genomic methylation, and their aberrant activities are closely associated with various diseases including cancers. However, the specific and sensitive detection of multiple DNA MTases has remained a great challenge due to the specificity of the methylase substrate and the rareness of methylation-sensitive restriction endonuclease species. Here, we demonstrate for the first time the cytosine-5 methylation-directed construction of a Au nanoparticle (AuNP)-based nanosensor for simultaneous detection of multiple DNA MTases at the single-molecule level. We used the methyl-directed endonuclease GlaI to cleave the site-specific 5-methylcytosine (5-mC). In the presence of CpG and GpC MTases (i.e., M.SssI and M.CviPI), their hairpin substrates are methylated at cytosine-5 to form the catalytic substrates for GlaI, respectively, followed by simultaneous cleavage by GlaI to yield two capture probes. These two capture probes can hybridize with the Cy5/Cy3–signal probes which are assembled on the AuNPs, respectively, to form the double-stranded DNAs (dsDNAs). Each dsDNA with a guanine ribonucleotide can act as the catalytic substrate for ribonuclease (RNase HII), inducing recycling cleavage of signal probes to liberate large numbers of Cy5 and Cy3 molecules from the AuNPs. The released Cy5 and Cy3 molecules can be simply quantified by total internal reflection fluorescence (TIRF)-based single-molecule imaging for simultaneous measurement of M.SssI and M.CviPI MTase activities. This method exhibits good specificity and high sensitivity with a detection limit of 2.01 × 10⁻³ U mL⁻¹ for M.SssI MTase and 3.39 × 10⁻³ U mL⁻¹ for M.CviPI MTase, and it can be further applied for discriminating different kinds of DNA MTases, screening potential inhibitors, and measuring DNA MTase activities in human serum and cell lysate samples, holding great potential in biomedical research, clinical diagnosis, drug discovery and cancer therapeutics.

Cytosine-5 methylation-directed construction of Au nanoparticle-based nanosensors enables specific and sensitive detection of multiple DNA methyltransferases.     

Quantitative analysis of DNA methylation in the promoter region of the methylguanine‐O6‐DNA‐methyltransferase gene by COBRA and subsequent native capillary gel electrophoresis

Along with histone modifications, RNA interference and delayed replication timing, DNA methylation belongs to the key processes in epigenetic regulation of gene expression. Therefore, reliable information about the methylation level of particular DNA fragments is of major interest. Herein the methylation level at two positions of the promoter region of the gene methylguanine‐O⁶‐DNA‐Methyltransferase (MGMT) was investigated. Previously, it was demonstrated that the epigenetic status of this DNA region correlates with response to alkylating anticancer agents. An automated CGE method with LIF detection was established to separate the six DNA fragments resulting from combined bisulfite restriction analysis of the methylated and non‐methylated MGMT promoter. In COBRA, the DNA was treated with bisulfite converting cytosine into uracil. During PCR uracil pairs with adenine, which changes the original recognition site of the restriction enzyme Taql. Artificial probes generated by mixing appropriate amounts of DNA after bisulfite treatment and PCR amplification were used for validation of the method. The methylation levels of these samples could be determined with high accuracy and precision. DNA samples prepared by mixing the corresponding clones first and then performing PCR amplification led to non‐linear correlation between the corrected peak areas and the methylation levels. This effect is explained by slightly different PCR amplification of DNA with different sequences present in the mixture. The superiority of CGE over PAGE was clearly demonstrated. Finally, the established method was used to analyze the methylation levels of human brain tumor tissue samples.     

A facile graphene oxide-based DNA polymerase assay

The DNA polymerase assay is fundamental for related molecular biology investigations and drug screenings, however, the commonly used radioactive method is laborious and restricted. Herein, we report a novel, simple and cost-effective fluorometric DNA polymerase detection method by utilizing graphene oxide (GO) as a signal switch. In this strategy, in the absence of DNA polymerase, the fluorophore-labeled template ssDNA could be strongly adsorbed and almost entirely quenched by GO. However, as DNA polymerase exists, the polymerized dsDNA product might lead to a much lower quenching efficiency after addition of GO due to the much weaker interaction of dsDNA with GO than ssDNA, thus resulting in a much higher fluorescence signal detected. As proof of concept, the quantitative DNA polymerase activity assay was performed using the Klenow fragment exo(-) (KF(-)) as a model. It was confirmed that, after optimization of detection conditions, KF(-) activity could be sensitively detected through facile fluorescence measurements, with a detection limit of 0.05 U mL(-1) and a good linear correlation between 0.05-2.5 U mL(-1) (R(2) = 0.9928). In addition, this GO-based method was further inspected to evaluate the inhibitive behaviors of several drugs toward KF(-) activity, the result of which firmly demonstrated its potential application in polymerization-targeted drug screening.     

G-quadruplex functionalized nano mesoporous silica for assay of the DNA methyltransferase activity

The abnormal level of DNA methyltransferase (MTase) may cause the aberrant DNA methylation, which has been found being associated with a growing number of human diseases, so it is necessary to create a sensitive and selective method to detect DNA MTase activity. In this paper, a new type of DNA functionalized nano mesoporous silica (MSNs) was creatively introduced to the detection of DNA MTase activity with G-quadruplex as a lock for signal molecule to release. The method was carried out by designing a particular DNA which could fold into G-quadruplex and complement with probe DNA. Next, MSNs was prepared before blocking methylene blue (MB) by G-quadruplex. Probe DNA was then fixed on gold nanoparticles modified glass carbon electrode, and the material was able to be transferred to the surface of electrode by DNA hybridization. After methylation of DNA MTase and the cutting of restriction endonuclease, the electrode was transferred to phosphate buffer solution (pH 9.0) for the releasing of MB. The response of differential pulse voltammetry was obtained from the release of MB. Consequently, the difference of signals with or without methylation could prove the assay of M. SssI MTase activity. The results showed that the responses from MB increased linearly with the increasing of the M. SssI MTase concentrations from 0.28 to 50 U mL⁻¹. The limit of detection was 0.28 U mL⁻¹. In addition, Zebularine, a nucleoside analog of cytidine, was utilized for studying the inhibition activity of M. SssI MTase.     

Rapid Electrochemical Assessment of Tumor Suppressor Gene Methylations in Raw Human Serum and Tumor Cells and Tissues Using Immunomagnetic Beads and Selective DNA Hybridization

We report a rapid and sensitive electrochemical strategy for the detection of gene‐specific 5‐methylcytosine DNA methylation. Magnetic beads (MBs) modified with an antibody for 5‐methylcytosines (5‐mC) are used for the capture of any 5‐mC methylated single‐stranded (ss)DNA sequence. A flanking region next to the 5‐mCs of the captured methylated ssDNA is recognized by hybridization with a synthetic biotinylated DNA sequence. Amperometric transduction at disposable screen‐printed carbon electrodes (SPCEs) is employed. The developed biosensor has a dynamic range from 3.9 to 500 pm and a limit of detection of 1.2 pm for the methylated synthetic sequence of the tumor suppressor gene O‐6‐methylguanine‐DNA methyltransferase (MGMT) promoter region. The method is applied in the 45‐min analysis of specific methylation in the MGMT promoter region directly in raw spiked human serum samples and in genomic DNA extracted from U‐87 glioblastoma cells and paraffin‐embedded brain tumor tissues without any amplification and pretreatment step.     

Self-assembled Nanosheets of Perylene Monoamide Derivative as Sensitive Fluorescent Biosensor for Exonuclease III Activity

Enzymes containing 3'→5' exonuclease activities play an important role in various key cellular and physiological processes. The development of fluorescence biosensor is an efficient method to detecting enzyme activity. Herein, a fluorescence resonance energy transfer(FRET) "on" and "off" strategy for detecting exonuclease III(Exo III) activity has been developed. We report here that the double-stranded DNA(dsDNA) enables to bind tightly to self-assembled nanosheets of cationic perylene monoimide derivative(PMI-O7) through electrostatic interaction, and the 6-carboxyfluorescein(FAM)-modified dsDNA could be efficiently quenched via FRET between FAM and PMI-O7. Upon the addition of Exo III, the dsDNA will be digested and the FAM fluorophore will be released, resulting in the fluorescence recovery of FAM. This method provides a simple and sensitive biosensor platform with a low detection limit of 0.077 U/mL for Exo III. Importantly, this method exhibits similar and calibration curves for the detection of Exo III in both buffer and fetal bovine serum samples, indicating that this platform has potential to detect Exo III activity in complex samples.     

DNA Dangling‐End‐Induced Colloidal Stabilization of Gold Nanoparticles for Colorimetric Single‐Nucleotide Polymorphism Genotyping

A single‐nucleotide polymorphism (SNP) detection method was developed by combining single‐base primer extension and salt‐induced aggregation of gold nanoparticles densely functionalized with double‐stranded DNA (dsDNA‐AuNP). The dsDNA‐AuNPs undergo rapid aggregation in a medium of high ionic strength, whereas particles having a single‐base protrusion at the outermost surface disperse stably, allowing detection of a single‐base difference in length by color changes. When SNP typing primers are used as analytes to hybridize to the single‐stranded DNA on the AuNP surface, the resulting dsDNA‐AuNP works as a visual indicator of single‐base extension. A set of four extension reaction mixtures is prepared using each of ddNTPs and subsequently subjected to the aggregation assay. Three mixtures involving ddNTP that is not complementary to the SNP site in the target produce the aggregates that exhibit a purple color. In contrast, one mixture with the complementary ddNTP generates the single‐base protrusion and appears red. This method could potentially be used in clinical diagnostics for personalized medicine.     

Separation‐free single‐base extension assay with fluorescence resonance energy transfer for rapid and convenient determination of DNA methylation status at specific cytosine and guanine dinucleotide sites

A separation‐free single‐base extension (SBE) assay utilizing fluorescence resonance energy transfer (FRET) was developed for rapid and convenient interrogation of DNA methylation status at specific cytosine and guanine dinucleotide sites. In this assay, the SBE was performed in a tube using an allele‐specific oligonucleotide primer (i.e., extension primer) labeled with Cy3 as a FRET donor fluorophore at the 5′‐end, a nucleotide terminator (dideoxynucleotide triphosphate) labeled with Cy5 as a FRET acceptor, a PCR amplicon derived from bisulfite‐converted genomic DNA, and a DNA polymerase. A single base‐extended primer (i.e., SBE product) that was 5′‐Cy3‐ and 3′‐Cy5‐tagged was formed by incorporation of the Cy5‐labeled terminator into the 3′‐end of the extension primer, but only if the terminator added was complementary to the target nucleotide. The resulting SBE product brought the Cy3 donor and the Cy5 acceptor into close proximity. Illumination of the Cy3 donor resulted in successful FRET and excitation of the Cy5 acceptor, generating fluorescence emission from the acceptor. The capacity of the developed assay to discriminate as low as 10% methylation from a mixture of methylated and unmethylated DNA was demonstrated at multiple cytosine and guanine dinucleotide sites.     

Site-specific detection of DNA methylation utilizing mCpG-SEER

Currently there are no direct methods for the sequence-specific detection of DNA-methylation at CpG dinucleotides, which provide a possible diagnostic marker for cancer. Toward this goal, we present a methodology termed mCpG-SEquence Enabled Reassembly (mCpG-SEER) of proteins utilizing a split green fluorescent protein (GFP) tethered to specific DNA recognition elements. Our system, mCpG-SEER, employs a zinc-finger attached to one-half of GFP to target a specific sequence of dsDNA, while a methyl-CpG binding domain protein attached to the complementary half of GFP targets an adjacent methylated CpG dinucleotide site. We demonstrate that the presence of both DNA sites is necessary for the reassembly and concomitant fluorescence of the reassembled GFP. We further show that the GFP-dependent fluorescence reaches a maximum when the methyl-CpG and zinc-finger sites are separated by two base pairs and the fluorescence signal is linear to 5 pmol of methylated target DNA. Finally, the specificity of this reporter system, mCpG-SEER, was found to be >40-fold between a methylated versus a nonmethylated CpG target site.