A pyrosequencing assay for the quantitative methylation analysis of the PCDHB gene cluster, the major factor in neuroblastoma methylator phenotype.

Epigenetic alterations are hallmarks of cancer and powerful biomarkers, whose clinical utilization is made difficult by the absence of standardization and of common methods of data interpretation. The coordinate methylation of many loci in cancer is defined as 'CpG island methylator phenotype' (CIMP) and identifies clinically distinct groups of patients. In neuroblastoma (NB), CIMP is defined by a methylation signature, which includes different loci, but its predictive power on outcome is entirely recapitulated by the PCDHB cluster only. We have developed a robust and cost-effective pyrosequencing-based assay that could facilitate the clinical application of CIMP in NB. This assay permits the unbiased simultaneous amplification and sequencing of 17 out of 19 genes of the PCDHB cluster for quantitative methylation analysis, taking into account all the sequence variations. As some of these variations were at CpG doublets, we bypassed the data interpretation conducted by the methylation analysis software to assign the corrected methylation value at these sites. The final result of the assay is the mean methylation level of 17 gene fragments in the protocadherin B cluster (PCDHB) cluster. We have utilized this assay to compare the methylation levels of the PCDHB cluster between high-risk and very low-risk NB patients, confirming the predictive value of CIMP. Our results demonstrate that the pyrosequencing-based assay herein described is a powerful instrument for the analysis of this gene cluster that may simplify the data comparison between different laboratories and, in perspective, could facilitate its clinical application. Furthermore, our results demonstrate that, in principle, pyrosequencing can be efficiently utilized for the methylation analysis of gene clusters with high internal homologies.

Outcome prediction and risk assessment by quantitative pyrosequencing methylation analysis of the SFN gene in advanced stage, high-risk, neuroblastic tumor patients.

The aim of our study was to identify threshold levels of DNA methylation predictive of the outcome to better define the risk group of stage 4 neuroblastic tumor patients. Quantitative pyrosequencing analysis was applied to a training set of 50 stage 4, high risk patients and to a validation cohort of 72 consecutive patients. Stage 4 patients at lower risk and ganglioneuroma patients were included as control groups. Predictive thresholds of methylation were identified by ROC curve analysis. The prognostic end points of the study were the overall and progression-free survival at 60 months. Data were analyzed with the Cox proportional hazard model. In a multivariate model the methylation threshold identified for the SFN gene (14.3.3sigma) distinguished the patients presenting favorable outcome from those with progressing disease, independently from all known predictors (Training set: Overall Survival HR 8.53, p = 0.001; Validation set: HR 4.07, p = 0.008). The level of methylation in the tumors of high-risk patients surviving more than 60 months was comparable to that of tumors derived from lower risk patients and to that of benign ganglioneuroma. Methylation above the threshold level was associated with reduced SFN expression in comparison with samples below the threshold. Quantitative methylation is a promising tool to predict survival in neuroblastic tumor patients. Our results lead to the hypothesis that a subset of patients considered at high risk-but displaying low levels of methylation-could be assigned at a lower risk group.

Inflammation, HIF-1, and the epigenetics that follows.

We summarize recent findings linking inflammatory hypoxia to chromatin modifications, in particular to repressive histone signatures. We focus on the role of Hypoxia-Induced Factor-1 in promoting the activity of specific histone demethylases thus deeply modifying chromatin configuration. The consequences of these changes are depicted in terms of gene expression and cellular phenotypes. We finally integrate available data to introduce novel speculations on the relationship between inflammation, histones, and DNA function and integrity.

Different intracellular compartmentalization of TA and DeltaNp73 in non-small cell lung cancer.

The p53 homologue p73 is overexpressed in many tumors, including lung cancer. We have evaluated the differential expression and subcellular localization of the functionally distinct apoptotic (TA) and anti-apoptotic (DeltaN) isoforms of p73 in non-small cell lung cancer (NSCLC), their possible association with p53 expression and determined the methylation status of the two p73 gene promoters (P1 and P2) in this tumor type. Immunohistochemical analysis showed that both isoforms are expressed in the majority of cases. However, the oncogenic DeltaN variant, derived from the transcripts DeltaN'p73 (from P1) and/or DeltaNp73 (from P2), is localized mainly in the nucleus, while the anti-oncogenic TAp73 isoform (derived from a P1 transcript) is sequestered in the cytoplasm in almost all cases analyzed. Significant correlation was found between p53 and DeltaNp73 expression (p=0.041). Methylation analysis conducted on 41 tumor samples showed that the P1 promoter is almost invariably unmethylated (39/41 cases) whereas P2 was found completely methylated in 17 cases and partially or totally unmethylated in 24 samples. No correlation was found between the methylation status of P1 and P2 and p73 expression. Our results demonstrate that both isoforms contribute to p73 overexpression in NSCLC and suggest that their different intracellular localization may reflect an alteration of the functional p53-p73 network that might contribute to lung cancer development.

Distinct CpG methylation profiles characterize different clinical groups of neuroblastic tumors.

The hypermethylation of CpG islands within gene promoter regions is an epigenetic phenomenon that is often, but not always, associated with the transcriptional silencing of downstream genes and contributes to carcinogenesis. We have determined the pattern of methylation of several genes involved in distinct biological pathways, including cell proliferation and apoptosis, in neuroblastoma and in the nonmalignant ganglioneuroma. The purpose of this work was to search for epigenetic signatures that could be associated with defined clinical and biological parameters and that, in prospective, could identify specific risk categories among the patients. We have analysed 31 malignant neuroblastoma with or without MYCN amplification and 13 benign ganglioneuroma and we have observed dramatic differences in the methylation pattern of five genes (CASP8, 14.3.3sigma, DeltaN-p73, RASSF1A and DCR2) between these tumors indicating that this phenomenon is not tissue-specific and can be considered as cancer-dependent. Furthermore, the methylation pattern of 14.3.3sigma, RASSF1A and of an intragenic segment of CASP8 was significantly different between MYCN amplified and single copy neuroblastoma suggesting a specific role of epigenetic alterations in aggressive neuroblastoma.

DNA methylation in neuroblastic tumors.

Epigenetic modifications and particularly the methylation of cytosines 5' of guanine residues (CpGs) in gene promoter regions is an essential regulatory mechanism for normal cell development. DNA methylation can inactivate tumor suppressor genes by inducing C > T transitions in somatic and germline cells and by altering gene transcription. On the other hand, hypomethylation of specific sequences may reactivate the expression of potential oncogenes. Thus, aberrant hyper- and hypomethylation are considered crucial steps leading to cancer development. Until recently, differently from most adult tumors, only limited information was available on the methylation aberrations in neuroblastoma. In the last 2 years, however, this situation has drastically changed and many information has been gained on the relevance of methylation in this tumor. In this review, we summarize the latest findings on the role of methylation in neuroblastoma and in particular to its clinical significance.

Caspase-8 gene expression in neuroblastoma.

Neuroblastoma (NB) is a solid tumor of infancy that presents a high rate of spontaneous regression, a phenomenon that likely reflects the activation of an apoptotic/differentiation program. Indeed, the level of expression of molecules involved in the regulation of apoptosis, such as p73 or survivin, is a prognostic factor in NB patients. The caspase-8 gene (CASP8) encodes a key enzyme at the top of the apoptotic cascade. Although methylation of a putative regulatory region of the CASP8 gene reportedly inhibits its transcription in some MYCN-amplified NB, our results indicate that the transcriptional inactivation of caspase-8 occurs in a subset of primary NB independently of MYCN amplification or CpG methylation. In addition, the apoptotic agent fenretinide (4HPR) and interferon-gamma (IFN-gamma) induce caspase-8 expression without modifying the methylation status of this gene. Nevertheless, the methylation level of CASP8 intragenic and promoter regions is higher in MYCN-amplified tumors as compared to nonamplified samples. This phenomenon might reflect the existence of distinct DNA methylation errors in MYCN-amplified and MYCN-single copy tumors. To gain information on the mechanisms that regulate the expression of this crucial apoptotic gene, we searched for potential CASP8 regulatory regions and cloned a DNA element at the 5' terminus of this gene that functionally acts as a promoter only in NB cell lines that express caspase-8. The retinoic acid analogue 4HPR, IFN-gamma, and the demethylating agent 5-aza-cytidine activate this promoter in NB cells that lack endogenous caspase-8, indicating that this element may regulate both constitutive and inducible CASP8 expression. These results indicate also that demethylation of the cellular genome may upregulate CASP8 through the action of trans-acting factors. Our results provide new insights to the regulation of CASP8, a gene with an essential role in a variety of physiologic and pathologic conditions.

HOXA7, 9, and 10 are methylation targets associated with aggressive behavior in meningiomas.

Meningioma is one of the most common intracranial tumors and is graded according to the World Health Organization (WHO) classification system. Although these tumors are often surgically curable, a malignant behavior also may occur in meningiomas with benign histologic profiles (WHO I). Thus, it is mandatory to identify biomolecular parameters useful to improve the classification of these tumors. HOXA genes belong to the HOX gene family that encodes homeodomain-containing transcription factors known to be key regulators of embryonic development, involved in cell growth and differentiation and in the development of the central nervous system. Moreover, altered HOXA gene methylation and expression have prognostic value in many tumors. The purpose of this study was to determine whether the level of HOXA3, 7, 9, and 10 methylation in meningioma could be a biomarker linked to the pathologic characteristics of the tumor. We found that methylation levels of HOXA7, 9, and 10 in 131 meningioma samples were significantly higher in WHO II/III tumors compared with WHO I tumors. Moreover, in newly diagnosed WHO I meningiomas, HOXA7, 9, and 10 methylation was significantly lower than in WHO I samples derived from recurring tumors, and multiple meningiomas presented significantly higher HOXA 10 methylation with respect to solitary meningiomas. This study demonstrates that HOXA7, 9, and 10 are methylation targets in meningioma, associated with histopathology and clinical aggressiveness parameters. Our findings suggest the possibility of detecting the malignancy potential of meningioma by assessing the HOXA methylation level and identifying patients at higher risk who could benefit from closer follow-up or postoperative adjuvant treatments.

Quantitative methylation analysis of HOXA3, 7, 9, and 10 genes in glioma: association with tumor WHO grade and clinical outcome.

PURPOSE: The purpose of this study was to determine whether specific HOXA epigenetic signatures could differentiate glioma with distinct biological, pathological, and clinical characteristics. METHODS: We evaluated HOXA3, 7, 9, and 10 methylation in 63 glioma samples by MassARRAY and pyrosequencing. RESULTS: We demonstrated the direct statistical correlation between the level of methylation of all HOXA genes examined and WHO grading. Moreover, in glioblastoma patients, higher level of HOXA9 and HOXA10 methylation significantly correlated with increased survival probability (HOXA9-HR: 0.36, P = 0.007; HOXA10-HR: 0.46, P = 0.045; combined HOXA9 and 10-HR 0.28, P = 0.004). CONCLUSIONS: This study identifies HOXA3, 7, 9, and 10 as methylation targets mainly in high-grade glioma and hypermethylation of the HOXA9 and 10 as prognostic factor in glioblastoma patients. Our data indicate that these epigenetic changes may be biomarkers of clinically different subgroups of glioma patients that could eventually benefit from personalized therapeutic strategies.

Epigenetic mechanisms regulate ΔNP73 promoter function in human tonsil B cells.

ΔNp73 is an anti-apoptotic product of the TP73 gene whose function in the immune system has not been extensively studied. We analyzed human tonsil B cell subpopulations physically subdivided into resting or activated fractions and found ΔNp73 gene expression essentially in cells bearing features of activation. Moreover, and accordingly, both these fractions proved to be sensitive to treatment in culture with the polyclonal activator TPA that caused substantial increase in ΔNp73 mRNA and protein expression. We also analyzed the TP73 oncogenic-relevant internal promoter 2 (P2) and identified epigenetics as its major regulatory factor since active DNA and histone configurations strictly correlated with ΔNp73 expression upon activation by agents capable of loosening chromatin compaction. Finally, in line with the known TPA pathway, we found that nuclear proteins could bind a sequence corresponding to a unique AP1 site on promoter 2 selectively in the activated cell fraction. Our results suggest a ΔNp73 function in B cell immunity, indicate epigenetics as master TP73 P2 regulator, and point to AP1 site occupancy as playing an putative mechanistic role in this process.

Toward an epigenetic view of our musical mind.

We are transient beings, in a world of constantly changing culture. At home in the fields of Art and Science, seemingly capable of magnificent abstractions, humans have an intense need to externalize their insights. Music is an art and a highly transmissible cultural product, but we still have an incomplete understanding of how our musical experience shapes and is vividly retained within our brain, and how it affects our behavior. However, the developing field of social epigenetics is now helping us to describe how communication and emotion, prime hallmarks of music, can be linked to a transmissible, biochemical change.

An interferon-sensitive response element is involved in constitutive caspase-8 gene expression in neuroblastoma cells.

We previously identified a 1.2 Kb DNA element (P-1161/+16), 5' to caspase-8 exon-1, that acts as promoter in caspase-8-positive, but not in caspase-8-negative neuroblastoma (NB) cells. The P-1161/+16 DNA element regulates both constitutive and interferon IFN-gamma-inducible caspase-8 expression. Two GAS (IFN-activated sequence, STAT-1 binding site) and two ISRE (interferon sensitive response element, IRF binding site) were present in P-1161/+16. Deletion studies indicated that elements essential for promoter activity in NB cells were present in a 167 bp region 5' flanking exon-1 (P-151/+16), which contains an ISRE at position -32. The transcription initiation site was mapped by 5' rapid amplification of cDNA end (RACE) at position -20 from caspase-8 cDNA reference sequence. Disruption of the ISRE-32 indicated that it is required for both constitutive and IFN-gamma-inducible caspase-8 expression. IRF-1 and IRF-2 transcription factors bind to the (-151/+16) DNA fragment in vitro. Chromatin immunoprecipitation (ChIP) assays showed that IRF-1 and IRF-2 bind to the DNA region at the 5' of caspase-8 gene in NB cells, which show constitutive expression but not in caspase-8 negative cells. In these last cells, up-regulation of caspase-8 by IFN-gamma was associated to induction of IRF-1 and IRF-2 binding to caspase-8 promoter and increased histone acetylation. Moreover, RNA interference experiments also supported the involvement of IRF-1 and IRF-2 in constitutive caspase-8 expression in NB cells.

Meth-DOP-PCR: an assay for the methylation profiling of trace amounts of DNA extracted from bodily fluids.

Cancer cells release their DNA into the patient's bodily fluids and cancer-specific signatures can be recognized in the circulating DNA. The aberrant methylation of CpG-rich regions in gene promoter sequences is an early marker of cell transformation whose specificity and optimal sensitivity can be achieved by assessing the methylation status of multiple genes ('methylation profiling'). Most of the current technologies for methylation analysis rely upon the combination of chemical conversion of the DNA and PCR analysis for the detection of methylated and unmethylated alleles. However, the small amount of circulating DNA, and its fragmentation, dramatically reduces the template DNA molecules making difficult the methylation profiling. To overcome this limitation, we have developed the Meth-DOP-PCR assay, a combination between a modified degenerate oligonucleotide primed PCR (DOP-PCR) and methylation-specific PCR (MSP), for the high-throughput methylation analysis of trace-amount of circulating DNA. We have demonstrated the concordance between Meth-DOP-PCR and MSP and shown the application of this technique for the methylation analysis of DNA extracted from the serum of lung cancer patients. We have estimated that through this procedure it is possible to obtain at least a 25-fold increase of the number of determinations allowing the methylation profiling from less than 1 ml of serum. Thus, Meth-DOP-PCR appears as a simple, cost-effective and efficient technique, for the development of novel methylation-based diagnostic assays.

p16(INK4a) promoter methylation and protein expression in breast fibroadenoma and carcinoma.

The potential role of p16(INK4a) methylation in breast cancer is controversial whereas there are no data on fibroadenoma. To assess if inactivation of p16(INK4a) by promoter hypermethylation occurs in this hyperproliferative benign breast lesion or, on the contrary, it is strictly related to the carcinogenic process, we have tested the different histological components of 15 cases of fibroadenoma and the intraductal and infiltrating components of 15 cases of carcinoma and their adjacent non-tumoral epithelium. All samples were obtained by laser-assisted microdissection. The relationship between promoter methylation status, immunohistochemical protein expression and ki67 proliferative activity was evaluated for each lesion. Our data demonstrate that hypermethylation of p16(INK4a) promoter is a common event occurring at similar frequency in all the different histological areas of the benign and malignant breast lesions taken into exam. Conversely, protein p16 expression, although heterogeneously distributed within the section, is considerably higher in breast carcinoma as compared to fibroadenoma in both tumoral and non-tumoral epithelia and stroma. The protein localization was almost exclusively nuclear in fibroadenoma and non-tumoral epithelia whereas, in carcinoma, the staining was both nuclear and cytoplasmic or cytoplasmic alone. Furthermore, in a subset of fibroadenoma with higher proliferative activity, p16 protein expression was substantially decreased as compared to those showing lower proliferation. We did not observe this association in carcinomas. Our data demonstrate that the hypermethylation of the p16(INK4a) promoter is not specifically associated with malignancy and that, on the contrary, the overexpression of p16 and its cytoplasmic sequestration is a feature of breast carcinoma.