Clinical responses of patients with diffuse leptomeningeal glioneuronal tumors to chemotherapy.

INTRODUCTION: Diffuse leptomeningeal glioneuronal tumors (DLGT) have been recognized in the most recent WHO classification as a distinct entity. OBJECTIVE: We describe seven pediatric cases of DLGT and the responses to therapy and outcome. METHODS: We conducted a retrospective review of charts from 1985 to 2013. RESULTS: DBS is an effective therapeutic modality for intractable TLE, particularly in patients with lateralized EEG A total of seven patients were identified. Median age at diagnosis was 3 years. Three months was the median time from symptom development to diagnosis. Common MRI findings included diffuse leptomeningeal thickening, nodularity, or coating of the subarachnoid or ependymal surfaces. The leptomeningeal lesions often appear cystic and contrast enhancement was variable. Six patients had leptomeningeal involvement of the brain and spine. All patients had a negative CSF cytology. Biopsies demonstrated thickened meninges infiltrated by a monotonous population of oligodendrocyte-like cells. Immunohistochemistry revealed variable features of neuronal and/or glial differentiation. All samples were negative for BRAF V600E mutation by immunohistochemistry. Therapy included one patient treated with craniospinal irradiation followed by vincristine, etoposide, cyclophosphamide, and cisplatin with stable disease for 164 months. Six patients received carboplatin and vincristine with a median duration of response of 20+ months (15-122+). Three patients received temozolomide upfront and progressed at 3, 4, and 27 months. No patients demonstrated complete or partial responses to any chemotherapy regimens. Progression-free survival ranged from 3 to 164+ months; 4/7 patients remained free of progression. All patients are alive. CONCLUSIONS: DLGT are rare tumors that lack imaging responses; however, there was clinical/ symptom improvement in 100% of the patients. A better understanding of the tumor biology is necessary to improve the diagnosis and treatment of this rare disease.

Successful Retreatment of a Child with a Refractory Brainstem Ganglioglioma with Vemurafenib.

A child with brainstem ganglioglioma underwent subtotal resection and focal radiation. Magnetic resonance imaging confirmed tumor progression 6 months later. Another partial resection revealed viable BRAF V600E-positive residual tumor. Vemurafenib (660 mg/m(2) /dose) was administered twice daily, resulting in >70% tumor reduction with sustained clinical improvement for 1 year. Vemurafenib was then terminated, but significant tumor progression occurred 3 months later. Vemurafenib was restarted, resulting in partial response. Toxicities included Grade I pruritus and Grade II rash. Vemurafenib was effectively crushed and administered in solution via nasogastric tube. We demonstrate benefit from restarting vemurafenib therapy.

Synthetic extracellular matrices and astrocytes provide a supportive microenvironment for the cultivation and investigation of primary pediatric gliomas.

Background: Pediatric gliomas comprise a diverse set of brain tumor entities that have substantial long-term ramifications for patient survival and quality of life. However, the study of these tumors is currently limited due to a lack of authentic models. Additionally, many aspects of pediatric brain tumor biology, such as tumor cell invasiveness, have been difficult to study with currently available tools. To address these issues, we developed a synthetic extracellular matrix (sECM)-based culture system to grow and study primary pediatric brain tumor cells. Methods: We developed a brain-like sECM material as a supportive scaffold for the culture of primary, patient-derived pediatric glioma cells and established patient-derived cell lines. Primary juvenile brainstem-derived murine astrocytes were used as a feeder layer to support the growth of primary human tumor cells. Results: We found that our culture system facilitated the proliferation of various primary pediatric brain tumors, including low-grade gliomas, and enabled ex vivo testing of investigational therapeutics. Additionally, we found that tuning this sECM material allowed us to assess high-grade pediatric glioma cell invasion and evaluate therapeutic interventions targeting invasive behavior. Conclusion: Our sECM culture platform provides a multipurpose tool for pediatric brain tumor researchers that enables both a wide breadth of biological assays and the cultivation of diverse tumor types.

Comprehensive Genomic Profiling of High-Risk Pediatric Cancer Patients Has a Measurable Impact on Clinical Care.

PURPOSE: Profiling of pediatric cancers through deep sequencing of large gene panels and whole exomes is rapidly being adopted in many clinical settings. However, the most impactful approach to genomic profiling of pediatric cancers remains to be defined. METHODS: We conducted a prospective precision medicine trial, using whole-exome sequencing of tumor and germline tissue and whole-transcriptome sequencing (RNA Seq) of tumor tissue to characterize the mutational landscape of 127 tumors from 126 unique patients across the spectrum of pediatric brain tumors, hematologic malignancies, and extracranial solid tumors. RESULTS: We identified somatic tumor alterations in 121/127 (95.3%) tumor samples and identified cancer predisposition syndromes on the basis of known pathogenic or likely pathogenic germline mutations in cancer predisposition genes in 9/126 patients (7.1%). Additionally, we developed a novel scoring system for measuring the impact of tumor and germline sequencing, encompassing therapeutically relevant genomic alterations, cancer-related germline findings, recommendations for treatment, and refinement of risk stratification or prognosis. At least one impactful finding from the genomic results was identified in 108/127 (85%) samples sequenced. A recommendation to consider a targeted agent was provided for 82/126 (65.1%) patients. Twenty patients ultimately received therapy with a molecularly targeted agent, representing 24% of those who received a targeted agent recommendation and 16% of the total cohort. CONCLUSION: Paired tumor/normal whole-exome sequencing and tumor RNA Seq of de novo or relapsed/refractory tumors was feasible and clinically impactful in high-risk pediatric cancer patients.

Phosphatase magnesium-dependent 1 δ (PPM1D), serine/threonine protein phosphatase and novel pharmacological target in cancer.

Aberrations in DNA damage response genes are recognized mediators of tumorigenesis and resistance to chemo- and radiotherapy. While protein phosphatase magnesium-dependent 1 δ (PPM1D), located on the long arm of chromosome 17 at 17q22-23, is a key regulator of cellular responses to DNA damage, amplification, overexpression, or mutation of this gene is important in a wide range of pathologic processes. In this review, we describe the physiologic function of PPM1D, as well as its role in diverse processes, including fertility, development, stemness, immunity, tumorigenesis, and treatment responsiveness. We highlight both the advances and limitations of current approaches to targeting malignant processes mediated by pathogenic alterations in PPM1D with the goal of providing rationale for continued research and development of clinically viable treatment approaches for PPM1D-associated diseases.

Inhibition of mutant PPM1D enhances DNA damage response and growth suppressive effects of ionizing radiation in diffuse intrinsic pontine glioma.

BACKGROUND: Children with diffuse intrinsic pontine glioma (DIPG) succumb to disease within 2 years of diagnosis despite treatment with ionizing radiation (IR) and/or chemotherapy. Our aim was to determine the role of protein phosphatase, magnesium-dependent 1, delta (PPM1D) mutation, present in up to 25% of cases, in DIPG pathogenesis and treatment. METHODS: Using genetic and pharmacologic approaches, we assayed effects of PPM1D mutation on DIPG growth and murine survival. We assayed effects of targeting mutated PPM1D alone or with IR on signaling, cell cycle, proliferation, and apoptosis in patient-derived DIPG cells in vitro, in organotypic brain slices, and in vivo. RESULTS: PPM1D-mutated DIPG cell lines exhibited increased proliferation in vitro and in vivo, conferring reduced survival in orthotopically xenografted mice, through stabilization of truncated PPM1D protein and inactivation of DNA damage response (DDR) effectors p53 and H2A.X. PPM1D knockdown or treatment with PPM1D inhibitors suppressed growth of PPM1D-mutated DIPGs in vitro. Orthotopic xenografting of PPM1D short hairpin RNA-transduced or PPM1D inhibitor-treated, PPM1D-mutated DIPG cells into immunodeficient mice resulted in reduced tumor proliferation, increased apoptosis, and extended mouse survival. PPM1D inhibition had similar effects to IR alone on DIPG growth inhibition and augmented the anti-proliferative and pro-apoptotic effects of IR in PPM1D-mutated DIPG models. CONCLUSIONS: PPM1D mutations inactivate DDR and promote DIPG growth. Treatment with PPM1D inhibitors activated DDR pathways and enhanced the anti-proliferative and pro-apoptotic effects of IR in DIPG models. Our results support continued development of PPM1D inhibitors for phase I/II trials in children with DIPG.