Meera Nandhabalan

Histone H3.3 Mutations Drive Pediatric Glioblastoma through Upregulation of MYCN

UNLABELLED Children and young adults with glioblastoma (GBM) have a median survival rate of only 12 to 15 months, and these GBMs are clinically and biologically distinct from histologically similar cancers in older adults. They are defined by highly specific mutations in the gene encoding the histone H3.3 variant H3F3A , occurring either at or close to key residues marked by methylation for regulation of transcription—K27 and G34. Here, we show that the cerebral hemisphere-specific G34 mutation drives a distinct expression signature through differential genomic binding of the K36 trimethylation mark (H3K36me3). The transcriptional program induced recapitulates that of the developing forebrain, and involves numerous markers of stem-cell maintenance, cell-fate decisions, and self-renewal.Critically, H3F3A G34 mutations cause profound upregulation of MYCN , a potent oncogene that is causative of GBMs when expressed in the correct developmental context. This driving aberration is selectively targetable in this patient population through inhibiting kinases responsible for stabilization of the protein. SIGNIFICANCE We provide the mechanistic explanation for how the fi rst histone gene mutation inhuman disease biology acts to deliver MYCN, a potent tumorigenic initiator, into a stem-cell compartment of the developing forebrain, selectively giving rise to incurable cerebral hemispheric GBM. Using synthetic lethal approaches to these mutant tumor cells provides a rational way to develop novel and highly selective treatment strategies

Integrated Molecular Meta-Analysis of 1,000 Pediatric High-Grade and Diffuse Intrinsic Pontine Glioma

Summary We collated data from 157 unpublished cases of pediatric high-grade glioma and diffuse intrinsic pontine glioma and 20 publicly available datasets in an integrated analysis of >1,000 cases. We identified co-segregating mutations in histone-mutant subgroups including loss of FBXW7 in H3.3G34R/V, TOP3A rearrangements in H3.3K27M, and BCOR mutations in H3.1K27M. Histone wild-type subgroups are refined by the presence of key oncogenic events or methylation profiles more closely resembling lower-grade tumors. Genomic aberrations increase with age, highlighting the infant population as biologically and clinically distinct. Uncommon pathway dysregulation is seen in small subsets of tumors, further defining the molecular diversity of the disease, opening up avenues for biological study and providing a basis for functionally defined future treatment stratification.

Molecular prognostic factors in glioblastoma: state of the art and future challenges

Gliomas account for the majority of primary tumors of the CNS, of which glioblastoma (GBM) is the most common and malignant, and for which survival is very poor. Despite significant inter- and intra-tumor heterogeneity, all patients are treated with a standardized therapeutic approach. While some clinical features of GBM patients have already been established as classic prognostic factors (e.g., patient age at diagnosis and Karnofsky performance status), one of the most important research fields in neuro-oncology today is the identification of novel molecular determinants of patient survival and tumor response to therapy. Here, we aim to review and discuss some of the most relevant and novel prognostic biomarkers in adult and pediatric GBM patients that may aid in stratifying subgroups of GBMs and rationalizing treatment decisions.

Abstract 2962: Histone H3.3 mutations drive paediatric glioblastoma through upregulation of MYCN.

Proceedings: AACR 104th Annual Meeting 2013; Apr 6-10, 2013; Washington, DC Glioblastomas of children and young adults (pGBM) have a median survival of only 12-15 months and are clinically and biologically distinct from histologically similar cancers in older adults. They are defined by highly specific mutations in the gene encoding the histone H3.3 variant H3F3A, occurring either at or close to key residues marked by methylation for regulation of transcription - K27 and G34. The G34 mutation is specific to tumours of the cerebral hemispheres and is associated with a distinct age of incidence (16 yrs) and gene expression signature compared to K27 and wild-type tumours. ChIP-Seq for the activating K36 trimethylation mark (H3K36me3) mark of G34V mutant KNS42 pGBM cells identified 156 genes differentially bound and expressed compared to wild-type pGBM control. The transcriptional program induced recapitulates that of the developing forebrain, and involves numerous markers of stem cell maintenance, cell fate decisions and self-renewal. Critically, H3F3A G34 mutations cause profound upregulation of MYCN, a potent oncogene which is causative of glioblastomas when expressed in the correct developmental context. A synthetic lethality siRNA screen revealed this driving aberration to be selectively targetable in this patient population by inhibiting kinases responsible for stabilisation of the protein such as AURKA and CHK1. We thus provide the mechanistic explanation for how the first histone gene mutation in human disease biology acts to deliver MYCN, a potent tumorigenic initiator, into a stem cell compartment of the developing forebrain, selectively giving rise to incurable cerebral hemispheric glioblastoma. Employing synthetic lethal approaches to these mutant tumour cells provides a rational way to develop novel and highly selective treatment strategies. Citation Format: Lynn Bjerke, Alan Mackay, Meera Nandhabalan, Anna Burford, Alexa Jury, Sergey Popov, Dorine Bax, Diana Carvalho, Katy Taylor, Mara Vinci, Illirjana Bajrami, Imelda McGonnell, Chris Lord, Rui Reis, Darren Hargrave, Alan Ashworth, Paul Workman, Chris Jones. Histone H3.3 mutations drive paediatric glioblastoma through upregulation of MYCN. [abstract]. In: Proceedings of the 104th Annual Meeting of the American Association for Cancer Research; 2013 Apr 6-10; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2013;73(8 Suppl):Abstract nr 2962. doi:10.1158/1538-7445.AM2013-2962 Note: This abstract was not presented at the AACR Annual Meeting 2013 because the presenter was unable to attend.