The molecular landscape and associated clinical experience in infant medulloblastoma: prognostic significance of second-generation subtypes.

AIMS: Biomarker-driven therapies have not been developed for infant medulloblastoma (iMB). We sought to robustly sub-classify iMB, and proffer strategies for personalized, risk-adapted therapies. METHODS: We characterized the iMB molecular landscape, including second-generation subtyping, and the associated retrospective clinical experience, using large independent discovery/validation cohorts (n = 387). RESULTS: iMBGrp3 (42%) and iMBSHH (40%) subgroups predominated. iMBGrp3 harboured second-generation subtypes II/III/IV. Subtype II strongly associated with large-cell/anaplastic pathology (LCA; 23%) and MYC amplification (19%), defining a very-high-risk group (0% 10yr overall survival (OS)), which progressed rapidly on all therapies; novel approaches are urgently required. Subtype VII (predominant within iMBGrp4 ) and subtype IV tumours were standard risk (80% OS) using upfront CSI-based therapies; randomized-controlled trials of upfront radiation-sparing and/or second-line radiotherapy should be considered. Seventy-five per cent of iMBSHH showed DN/MBEN histopathology in discovery and validation cohorts (P < 0.0001); central pathology review determined diagnosis of histological variants to WHO standards. In multivariable models, non-DN/MBEN pathology was associated significantly with worse outcomes within iMBSHH . iMBSHH harboured two distinct subtypes (iMBSHH-I/II ). Within the discriminated favourable-risk iMBSHH DN/MBEN patient group, iMBSHH-II had significantly better progression-free survival than iMBSHH-I , offering opportunities for risk-adapted stratification of upfront therapies. Both iMBSHH-I and iMBSHH-II showed notable rescue rates (56% combined post-relapse survival), further supporting delay of irradiation. Survival models and risk factors described were reproducible in independent cohorts, strongly supporting their further investigation and development. CONCLUSIONS: Investigations of large, retrospective cohorts have enabled the comprehensive and robust characterization of molecular heterogeneity within iMB. Novel subtypes are clinically significant and subgroup-dependent survival models highlight opportunities for biomarker-directed therapies.

Minimal methylation classifier (MIMIC): A novel method for derivation and rapid diagnostic detection of disease-associated DNA methylation signatures.

Rapid and reliable detection of disease-associated DNA methylation patterns has major potential to advance molecular diagnostics and underpin research investigations. We describe the development and validation of minimal methylation classifier (MIMIC), combining CpG signature design from genome-wide datasets, multiplex-PCR and detection by single-base extension and MALDI-TOF mass spectrometry, in a novel method to assess multi-locus DNA methylation profiles within routine clinically-applicable assays. We illustrate the application of MIMIC to successfully identify the methylation-dependent diagnostic molecular subgroups of medulloblastoma (the most common malignant childhood brain tumour), using scant/low-quality samples remaining from the most recently completed pan-European medulloblastoma clinical trial, refractory to analysis by conventional genome-wide DNA methylation analysis. Using this approach, we identify critical DNA methylation patterns from previously inaccessible cohorts, and reveal novel survival differences between the medulloblastoma disease subgroups with significant potential for clinical exploitation.

c-MYC is a radiosensitive locus in human breast cells.

Ionising radiation is a potent human carcinogen. Epidemiological studies have shown that adolescent and young women are at increased risk of developing breast cancer following exposure to ionising radiation compared with older women, and that risk is dose-dependent. Although it is well understood which individuals are at risk of radiation-induced breast carcinogenesis, the molecular genetic mechanisms that underlie cell transformation are less clear. To identify genetic alterations potentially responsible for driving radiogenic breast transformation, we exposed the human breast epithelial cell line MCF-10A to fractionated doses of X-rays and examined the copy number and cytogenetic alterations. We identified numerous alterations of c-MYC that included high-level focal amplification associated with increased protein expression. c-MYC amplification was also observed in primary human mammary epithelial cells following exposure to radiation. We also demonstrate that the frequency and magnitude of c-MYC amplification and c-MYC protein expression is significantly higher in breast cancer with antecedent radiation exposure compared with breast cancer without a radiation aetiology. Our data also demonstrate extensive intratumor heterogeneity with respect to c-MYC copy number in radiogenic breast cancer, suggesting continuous evolution at this locus during disease development and progression. Taken together, these data identify c-MYC as a radiosensitive locus, implicating this oncogenic transcription factor in the aetiology of radiogenic breast cancer.

Downregulation of nuclear expression of the p33(ING1b) inhibitor of growth protein in invasive carcinoma of the breast.

BACKGROUND/AIMS: The inhibitor of growth gene 1 (ING1) is a modulator of cell cycle checkpoints, apoptosis, and cellular senescence. The most widely expressed ING1 isoform is p33(ING1b), which can modulate p53, a molecule that is frequently altered in breast cancer. Reduced ING1 mRNA expression has been observed in primary breast cancer expressing wild-type p53. METHODS: p33(ING1b), p53, oestrogen receptor (ER), and progesterone receptor (PgR) expression was studied in 86 primary invasive breast cancers using immunohistochemistry. RESULTS: Reduced nuclear expression of p33(ING1b) was found in cancer cells, both in intensity and the proportion of cells staining. This was associated with enhanced cytoplasmic p33(ING1b) expression in a proportion of cases. Analysis of several known biological factors indicated that high grade tumours were of larger size and more often negative for ER and PgR expression. However, larger tumours were more frequently p53 negative. These results provide evidence that p33(ING1b) alterations are associated with more poorly differentiated tumours. Positive correlations were found between nuclear p33(ING1b) expression and both ER and PgR expression. CONCLUSIONS: Optimum function of p53 is dependent on p33(ING1b) so that a reduction of nuclear p33(ING1b) expression, as seen in this series, would be predicted to compromise p53 function. This study showed that p33(ING1b) alterations were associated with more poorly differentiated tumours. Therefore, p33(ING1b) expression could be used as a marker of differentiation in invasive breast cancer. These results support the view that loss of p33(ING1b) may be an important molecular event in the differentiation and pathogenesis of invasive breast cancer.

Nuclear to cytoplasmic compartment shift of the p33ING1b tumour suppressor protein is associated with malignancy in melanocytic lesions.

AIMS: Cutaneous malignant melanoma is an unpredictable neoplasm. Studies of cell cycle and proliferation-associated proteins may help in the understanding of the genesis of melanomas. The tumour suppressor gene TP53 has been shown to be involved in melanomas. However, the incidence of TP53 malfunction in cutaneous melanoma is unclear, and other regulators of cell cycle control are likely to be involved in both the development and progression of melanocytic neoplasia. A candidate is the ING1 gene, which co-operates with TP53 in growth suppression and apoptosis. Thus loss of ING1 function may have similar consequences to loss of TP53 function and may contribute to tumorigenesis. Therefore we have studied the expression of p33ING1b protein in cutaneous melanocytic neoplasia. METHODS AND RESULTS: Sixty-seven melanocytic lesions were studied by immunohistochemistry for the expression of p33ING1b. In our series there was loss of nuclear p33ING1b expression in invasive malignant melanoma compared with normal cutaneous melanocytes or the melanocytes of benign melanocytic naevi. This was associated with an enhancement of cytoplasmic p33ING1b expression which was particularly prominent in invasive malignant melanoma. CONCLUSIONS: Cytoplasmic immunostaining for p33ING1b using MAb GN2 is strongly associated with 'activated' melanocytic lesions; therefore it is possible that this MAb could be of value in diagnostic practice. Furthermore, the reduction in p33ING1b expression and perhaps translocation from the nucleus to the cytoplasm may play a central role in the development and progression of melanomas.

Development and characterisation of a glutamate-sensitive motor neurone cell line.

Modification of the growth conditions of NSC-34 mouse neuroblastoma x motor neurone cells by serum depletion promotes the expression of functional glutamate receptors as the cells mature into a form that bears the phenotypic characterisation of motor neurones. Immunocytochemical studies demonstrated the presence of the glutamate receptor proteins NMDAR1, NMDAR2A/B, GluR1, GluR2, GluR2/3, GluR4, GluR6/7, and KA2. Toxicity assays using cell counting techniques demonstrated a mild but significant cell death (approximately 30%, p < 0.01) following a 24-h exposure to 1 mM glutamate that could be prevented by the presence of the glutamate receptor antagonists (+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine maleate (10 microM) and 2,3-dioxo-6-nitro-1,2,3,4-tetrahydrobenzo[f]quinoxaline-7-sulphonamide (1 microM). As an indication of glutamate receptor functional activity a novel approach was used to detect the production of free radicals following stimulation with glutamate receptor agonists. The release of superoxide free radicals was detected using a micro-electrochemical sensor following addition of glutamate receptor agonists to the cell bathing solution. Alterations in intracellular calcium concentrations were examined using fura-2 imaging. Exposure of the differentiated NSC-34 cells to glutamate leads to an increase in intracellular calcium concentrations that is prevented by the presence of glutamate receptor antagonists. The motor neurone origin of these cells makes them particularly useful for investigating the potential role of glutamatergic toxicity in motor neurone degeneration.