Methylation-specific loop-mediated isothermal amplification for detecting hypermethylated DNA in simplex and multiplex formats.

BACKGROUND: Aberrant DNA methylation of gene promoters and the associated silencing of tumor suppressor genes are recognized as mechanisms contributing to tumor development. Therefore, detection of promoter hypermethylation is becoming important for diagnosis, prognosis, and aiding the design of cancer therapies. We describe a novel isothermal method for the detection of DNA hypermethylation. METHODS: Methylation-specific loop-mediated isothermal amplification (MS-LAMP) is a novel adaptation of LAMP. MS-LAMP was used for the highly specific detection of hypermethylated CpGs in the promoters of the CDKN2A [cyclin-dependent kinase inhibitor 2A (melanoma, p16, inhibits CDK4)], GATA5 (GATA binding protein 5), and DAPK1 (death-associated protein kinase 1) genes. The reactions occurred under isothermal conditions with 3 primer sets specific for methylated promoters. Both turbidimetry and fluorescence were used for detection. The MS-LAMP assay was validated with bisulfite-treated plasmid and genomic DNA controls of known methylation status and was applied to detect hypermethylation in 18 clinical tumor samples. A multiplex MS-LAMP for CDKN2A, GATA5, and DAPK1 was also validated with the aid of synthetic positive and negative controls. RESULTS: The MS-LAMP assay showed high specificity with plasmid and genomic DNA targets in reactions carried out in <1 h. The assay had a detection limit of approximately 30 copies of methylated target sequence and a selectivity of 0.5% methylated DNA in a mixture with unmethylated DNA. Compared with methylation-specific PCR, the MS-LAMP assay detected lower rates of methylation in lung adenocarcinoma samples. Simultaneous multiplex detection of hypermethylation in the 3 targets (CDKN2A, GATA5, and DAPK1) was readily achieved with the MS-LAMP assay in both the turbidimetric and fluorescence detection formats. CONCLUSIONS: MS-LAMP provides a highly specific isothermal method for methylation detection and is well suited for multiplex approaches.

FLAG assay as a novel method for real-time signal generation during PCR: application to detection and genotyping of KRAS codon 12 mutations.

Real-time signal generation methods for detection and characterization of low-abundance mutations in genomic DNA are powerful tools for cancer diagnosis and prognosis. Mutations in codon 12 of the oncogene KRAS, for example, are frequently found in several types of human cancers. We have developed a novel real-time PCR technology, FLAG (FLuorescent Amplicon Generation) and adapted it for simultaneously (i) amplifying mutated codon 12 KRAS sequences, (ii) monitoring in real-time the amplification and (iii) genotyping the exact nucleotide alteration. FLAG utilizes the exceptionally thermostable endonuclease PspGI for real-time signal generation by cleavage of quenched fluorophores from the 5'-end of the PCR products and, concurrently, for selecting KRAS mutations over wild type. By including peptide-nucleic-acid probes in the reaction, simultaneous genotyping is achieved that circumvents the requirement for sequencing. FLAG enables high-throughput, closed-tube KRAS mutation detection down to approximately 0.1% mutant-to-wild type. The assay was validated on model systems and compared with allele-specific PCR sequencing for screening 27 cancer specimens. Diverse applications of FLAG for real-time PCR or genotyping applications in cancer, virology or infectious diseases are envisioned.

Anchor-based fluorescent amplicon generation assays (FLAG) for real-time measurement of human cytomegalovirus, Epstein-Barr virus, and varicella-zoster virus viral loads.

BACKGROUND: Monitoring the human cytomegalovirus (HCMV), Epstein-Barr virus (EBV), or varicella-zoster virus (VZV) viral load is an important factor in the management of immunosuppressed patients, such as recipients of solid-organ or bone marrow transplants. The advent of real-time PCR technologies has prompted the widespread development of quantitative PCR assays for the detection of viral loads and other diagnostic purposes. METHODS: The fluorescent amplicon generation (FLAG) technology uses the PspGI restriction enzyme to monitor PCR product generation. We modified the FLAG technology by introducing an accessory oligonucleotide "anchor" that stabilizes the binding of the forward primer to the target sequence (a-FLAG). We developed assays for HCMV, EBV, and VZV that incorporated an internal amplification-control reaction to validate negative results and extensively analyzed the performance of the HCMV a-FLAG assay. RESULTS: The 3 assays performed similarly with respect to reaction efficiency and linear range. Compared with a commercially available kit, the HCMV a-FLAG assay results showed good correlation with calculated concentrations (r = 0.9617), excellent diagnostic sensitivity and specificity (99% and 95%, respectively), and similar values for the linear range (1-10(7) copies/microL), analytical sensitivity (0.420 copies/microL), and intra- and interassay imprecision. CONCLUSIONS: The a-FLAG assay is an alternative real-time PCR technology suitable for detecting and quantifying target-DNA sequences. For clinical applications such as the measurement of viral load, a-FLAG assays provide multiplex capability, internal amplification control, and high diagnostic sensitivity and specificity.

Exploring hyperthermophilic proteins under pressure: theoretical aspects and experimental findings.

Proteins from hyperthermophilic microorganisms are generally capable of withstanding temperatures close to, or even higher than the boiling point. As a rule, these proteins are strongly piezostable as well, although exceptions have been also reported. This observation has a theoretical relevance, as the understanding of the effects of pressure and temperature on protein stability is equally important to develop a comprehensive model for their thermodynamic stability. Nevertheless, the structural features justifying the correlation between heat resistance and pressure resistance are poorly understood. Actually, most reports do not exceed the phenomenological level. Only in the case of the small protein Sso7d from Sulfolobus solfataricus, characterisation of wild-type and some mutants showed that both properties are largely accounted for by a network of aromatic residues found in the hydrophobic core of the molecule. Current knowledge, however, does not allow to establish to what extent this finding may be generalised. In a biotechnological perspective, hyperthermophilic enzymes seem to be more suitable for bioprocesses at high pressure with respect to their mesophilic counterparts. Indeed, thanks to their higher resistance towards pressure and temperature, they may be exploited in a much broader range of working conditions for tuning activity and specificity. Furthermore, they are often activated by increasing pressure, although it cannot be established, to date, to what extent this is a common feature.

Guanidine-induced unfolding of the Sso7d protein from the hyperthermophilic archaeon Sulfolobus solfataricus.

The unfolding induced by guanidine hydrochloride of the small protein Sso7d from the hyperthermophilic archaeon Sulfolobus solfataricus has been investigated by means of circular dichroism and fluorescence measurements. At neutral pH and room temperature the midpoint of the transition occurred at 4M guanidine hydrochloride. Thermodynamic information was obtained by means of both the linear extrapolation model and the denaturant binding model, in the assumption of a two-state N<==>D transition. A comparison with thermodynamic data determined from the thermal unfolding of Sso7d indicated that the denaturant binding model has to be preferred. Finally, it is shown that Sso7d is the most stable against both temperature and guanidine hydrochloride among a set of globular proteins possessing a very similar 3D structure.

Genetic score based on high-risk genetic polymorphisms and early onset of ischemic heart disease in an Italian cohort of ischemic patients.

Several single-nucleotide polymorphisms (SNPs) have been recognized as associated with ischemic heart disease (IHD) although the optimal set of risk genotypes has not be identified. This study aimed to examine whether identified high-risk SNPs are associated with early onset of IHD. In the GENOCOR study, 44 high-risk SNPs were genotyped in 114 patients with early onset of IHD (46.2 ± 5.1 years) and 384 patients with late onset of IHD (60.7 ± 5.9 years). The associations between individual SNPs and early onset IHD were assessed. A multilocus genetic risk score (GRS) for each associated risk genetic markers was constructed by summing the number of risk alleles. The SNPs significantly associated with IHD were: -482C>T of Apolipoprotein C III gene (ApoC3, p=0.02); 1171 5A>6A of Matrix metalloproteinase 3 stromelisine I gene (p=0.01); G98T of Selectin E gene (p=0.05); C/G of 9p21.3 locus (p=0.01). Likelihood ratio test showed a strong interaction for increasing risk of early IHD between the presence of ApoC3 and 9p21.3 locus with hypertriglyceridemia (p=0.0008, 0.0011) as well as between 9p21.3 locus and smoking (p=0.0010) after correction for multiple testing. The OR for premature IHD for GRS unit was 1.3 (95% CI 1.1-1.6, p=0.001). Patients in the top tertile of GRS were estimated to have a 3.2-fold (95% CI 1.5-6.8; p=0.001) increased risk of early IHD compared with those in the bottom tertile. The results show that currently identified high-risk SNPs confer an additive biomarker for cardiovascular events. GRS may provide important incremental information on the genetic component of IHD.

Individual and summed effects of high-risk genetic polymorphisms on recurrent cardiovascular events following ischemic heart disease.

AIMS: High-risk single nucleotide polymorphisms (SNPs) have been recently identified as risk factors for ischemic heart disease in large epidemiological and genome-wide association studies. However, their influence on prognosis remains uncertain. The aim of the study was to investigate the impact of previously identified SNPs and their joint effects in a genetic score (GS) on Major Adverse Cardiac Events (MACEs). METHODS AND RESULTS: High-throughput genotyping for 48 high-risk SNPs was performed in 498 patients (432 males; 57.4 ± 8.3 years) who were followed-up for 6.9 ± 3.4 years. First MACE-coronary-related death, nonfatal myocardial infarction, or myocardial revascularization- was the endpoint taken into consideration. A GS was obtained by summing the number of significant high-risk alleles associated to MACEs. One-hundred and nineteen patients (24%) had a MACE. The hazard ratio (HR) for SNPs with a significant difference in cumulative survival were: APOC3 -482C > T (HR = 1.7, 95% CI 1.01-3.0), MTHFR (HR = 1.5, 95% CI 1.02-2.2), NADHPH oxidase- p22-PHOX C242T (HR = 1.9, 95% CI 1.2-2.8), PON-2 (HR = 0.2, 95% CI 0.1-0.8), and SELP (HR = 0.6, 95% CI 0.4-0.8). The resulting GS predicted a 25% risk for MACEs per risk allele (HR = 1.25, 95% CI 1.1-1.4, p = 0.001). The highest HR for MACEs was found in patients in the top tertile (HR = 3.0, 95% CI 1.4-6.7, p = 0.0005) of the GS compared with those in the bottom tertile. CONCLUSION: Our findings show that high-risk SNPs may be used to create a useful GS that predicts MACEs in a secondary prevention setting, which in turn allows a better risk stratification.

MS-FLAG, a novel real-time signal generation method for methylation-specific PCR.

BACKGROUND: Aberrant promoter methylation is a major mechanism for silencing tumor suppressor genes in cancer. Detection of hypermethylation is used as a molecular marker for early cancer diagnosis, as a prognostic index, or to define therapeutic targets for reversion of aberrant methylation. We report on a novel signal generation technology for real-time PCR to detect gene promoter methylation. METHODS: FLAG (fluorescent amplicon generation) is a homogeneous signal generation technology based on the exceptionally thermostable endonuclease PspGI. FLAG provides real-time signal generation during PCR by PspGI-mediated cleavage of quenched fluorophores at the 5' end of double-stranded PCR products. Methylation-specific PCR (MSP) applied on bisulfite-treated DNA was adapted to a real-time format (methylation-specific FLAG; MS-FLAG) for quantifying methylation in the promoter of CDKN2A (p16), GATA5, and RASSF1. We validated MS-FLAG on plasmids and genomic DNA with known methylation status and applied it to detection of methylation in a limited number of clinical samples. We also conducted bisulfite sequencing on these samples. RESULTS: Real-time PCR results obtained via MS-FLAG agreed with results obtained via conventional, gel-based MSP. The new technology showed high specificity, sensitivity (2-3 plasmid copies), and selectivity (0.01% of methylated DNA) on control samples. It enabled correct prediction of the methylation status of all 3 gene promoters in 21 lung adenocarcinoma samples, as confirmed by bisulfite sequencing. We also developed a multiplex MS-FLAG assay for GATA5 and RASSF1 promoters. CONCLUSION: MS-FLAG provides a new, quantitative, high-throughput method for detecting gene promoter methylation and is a convenient alternative to agarose gel-based MSP for screening methylation. In addition to methylation, FLAG-based real-time signal generation may have broad applications in DNA diagnostics.

Genotype-specific signal generation based on digestion of 3-way DNA junctions: application to KRAS variation detection.

BACKGROUND: Genotyping methods that reveal single-nucleotide differences are useful for a wide range of applications. We used digestion of 3-way DNA junctions in a novel technology, OneCutEventAmplificatioN (OCEAN) that allows sequence-specific signal generation and amplification. We combined OCEAN with peptide-nucleic-acid (PNA)-based variant enrichment to detect and simultaneously genotype v-Ki-ras2 Kirsten rat sarcoma viral oncogene homolog (KRAS) codon 12 sequence variants in human tissue specimens. MATERIALS AND METHODS: We analyzed KRAS codon 12 sequence variants in 106 lung cancer surgical specimens. We conducted a PNA-PCR reaction that suppresses wild-type KRAS amplification and genotyped the product with a set of OCEAN reactions carried out in fluorescence microplate format. The isothermal OCEAN assay enabled a 3-way DNA junction to form between the specific target nucleic acid, a fluorescently labeled "amplifier", and an "anchor". The amplifier-anchor contact contains the recognition site for a restriction enzyme. Digestion produces a cleaved amplifier and generation of a fluorescent signal. The cleaved amplifier dissociates from the 3-way DNA junction, allowing a new amplifier to bind and propagate the reaction. RESULTS: The system detected and genotyped KRAS sequence variants down to approximately 0.3% variant-to-wild-type alleles. PNA-PCR/OCEAN had a concordance rate with PNA-PCR/sequencing of 93% to 98%, depending on the exact implementation. Concordance rate with restriction endonuclease-mediated selective-PCR/sequencing was 89%. CONCLUSION: OCEAN is a practical and low-cost novel technology for sequence-specific signal generation. Reliable analysis of KRAS sequence alterations in human specimens circumvents the requirement for sequencing. Application is expected in genotyping KRAS codon 12 sequence variants in surgical specimens or in bodily fluids, as well as single-base variations and sequence alterations in other genes.

Investigations of Sso7d catalytic residues by NMR titration shifts and electrostatic calculations.

Sso7d is a small basic protein consisting of 62 amino acids isolated from the thermoacidophilic archeobacterium Sulfolobus solfataricus. The protein is endowed with DNA binding properties, RNase activity, and the capability of rescuing aggregated proteins in the presence of ATP. In this study, the electrostatic properties of Sso7d are investigated by using the Poisson-Boltzmann calculation of the surface potential distribution and following by NMR spectroscopy the proton chemical shift pH titration of acidic residues. Although the details of the catalytic mechanism still have to be defined, the results from NMR experiments confirm the possible involvement of Glu35 as the proton acceptor in the catalytic reaction, as seen by its abnormally high pK(a) value. Poisson-Boltzmann calculations and NMR titration shifts suggest the presence of a possible hydrogen bond between Glu35 and Tyr33, with a consequent rather rigid arrangement at these positions. Comparison with RNase T1 suggests that Tyr7 may be a good candidate for acting as a proton donor in the active site of Sso7d as shown by its low phenolic pK(a) of approximately 9.3. Titration experiments performed with the UpA, a RNA dinucleotide model, showed that the protein residues affected by the interaction are mainly located in a different region with respect to the surface affected by DNA recognition, in good agreement with the surface potential distribution found with electrostatic calculations.

Temperature-dependent, irreversible formation of amyloid fibrils by a soluble human ataxin-3 carrying a moderately expanded polyglutamine stretch (Q36).

The protein ataxin-3 is responsible for Machado-Joseph disease/spinocerebellar ataxia type 3, a neurodegenerative disorder caused by the presence of an expanded polyglutamine tract. A previous investigation [Bevivino, A. E., and Loll, P. J. (2001) Proc. Natl. Acad. Sci. U.S.A. 98, 11955-11960] showed that a nonexpanded ataxin-3 (Q27) was fully soluble, whereas an expanded form (Q78) gave rise to amyloid fibrils. Here, we report investigations on three forms of ataxin-3 (i.e., human nonexpanded (Q26), moderately expanded (Q36) ataxins-3, and the murine protein (Q6)). Far-UV circular dichroism spectra at room temperature were substantially similar, with a relatively high helical content. On heating to 96 degrees C, human Q26 and murine proteins did not display large structural changes, nor did they undergo any precipitation, which highlights their amazing heat-resistance. In contrast, human Q36 ataxin-3 underwent a progressive increase in the beta-sheet and a concomitant decrease in helical content when the temperature was shifted from 37 to 80 degrees C, followed by the irreversible formation of aggregates above 80 degrees C. They were shown to consist of amyloid fibrils, as supported by both electron microscopy images and the typical spectral shift displayed by Congo red when it was added to the protein at growing temperatures. We also found that protein precipitation could be prevented by mixing the dye with Q36 ataxin-3 prior to heating, which also confirms that the precipitates do represent authentic amyloid fibrils. In contrast, other compounds structurally related to Congo red did not exert significant effects. Our observations suggest that the temperature of the observed transition is inversely related to the length of the expansion. Finally, we suggest that antiamyloidogenic compounds might be selected on the basis of their ability to block or retard human Q36 ataxin-3 precipitation on heat-treatment.

Structural instability and fibrillar aggregation of non-expanded human ataxin-3 revealed under high pressure and temperature.

Protein misfolding and formation of structured aggregates are considered to be the earliest events in the development of neurodegenerative diseases, but the mechanism of these biological phenomena remains to be elucidated. Here, we report a study of heat- and pressure-induced unfolding of human Q26 and murine Q6 ataxin-3 using spectroscopic methods. UV absorbance and fluorescence revealed that heat and pressure induced a structural transition of both proteins to a molten globule conformation. The unfolding pathway was partly irreversible and led to a protein conformation where tryptophans were more exposed to water. Furthermore, the use of fluorescent probes (8-anilino-1-naphthalenesulfonate and thioflavin T) allowed the identification of different intermediates during the process of pressure-induced unfolding. At high temperature and pressure, human Q26, but not murine Q6, underwent concentration-dependent aggregation. Fourier transform infrared and circular dichroism spectroscopy revealed that these aggregates are characterized by an increased beta-sheet content. As revealed by electron microscopy, heat- and pressure-induced aggregates were different; high temperature treatment led to fibrillar microaggregates (8-10-nm length), whereas high pressure induced oligomeric structures of globular shape (100 nm in diameter), which sometimes aligned to higher order suprastructures. Several intermediate structures were detected in this process. Two factors appear to govern ataxin unfolding and aggregation, the length of the polyglutamine tract and its protein context.

Thermal stability and DNA binding activity of a variant form of the Sso7d protein from the archeon Sulfolobus solfataricus truncated at leucine 54.

Sso7d is a 62-residue, basic protein from the hyperthermophilic archaeon Sulfolobus solfataricus. Around neutral pH, it exhibits a denaturation temperature close to 100 degrees C and a non-sequence-specific DNA binding activity. Here, we report the characterization by circular dichroism and fluorescence measurements of a variant form of Sso7d truncated at leucine 54 (L54Delta). It is shown that L54Delta has a folded conformation at neutral pH and that its thermal unfolding is a reversible process, represented well by the two-state N <=> D transition model, with a denaturation temperature of 53 degrees C. Fluorescence titration experiments indicate that L54Delta binds tightly to calf thymus DNA, even though the binding parameters are smaller than those of the wild-type protein. Therefore, the truncation of eight residues at the C-terminus of Sso7d markedly affects the thermal stability of the protein, which nevertheless retains a folded structure and DNA binding activity.