lunes, 4 de mayo de 2015

Study points to possible treatment for lethal pediatric brain cancer

Study points to possible treatment for lethal pediatric brain cancer

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Michelle Monje, M.D., Ph.D., discusses pediatric brain cancer and her efforts to find new treatments. Video courtesy of NINDS.


Study points to possible treatment for lethal pediatric brain cancer

NIH-funded preclinical study suggests epigenetic drugs may be used to treat leading cause of pediatric brain cancer death
Using brain tumor samples collected from children in the United States and Europe, an international team of scientists found that the drug panobinostat and similar gene regulating drugs may be effective at treating diffuse intrinsic pontine gliomas (DIPG), an aggressive and lethal form of pediatric cancer. The study, published in Nature Medicine, was partially funded by the National Institutes of Health, the Department of Defense, and more than 25 nonprofit foundations devoted to finding cures for childhood brain cancer.
“Our results provide a glimmer of hope for treating this heartbreaking disease,” said Michelle Monje, M.D., Ph.D., assistant professor of neurology and neurological sciences, Stanford University School of Medicine, California, a senior author of the study and a specialist in DIPG. “Caring for DIPG patients drives me to find new ways to treat them.”
DIPG typically attacks children 4 to 9 years of age. Children progressively lose muscle control as the tumor rapidly attacks the pons, a region deep inside the brain that connects the brain to the spinal cord, and is difficult to reach and surgically remove. Despite radiation treatment, children usually survive for about nine months, and less than 1 percent survive longer than five years.
Image of a pediatric brain tumor
Searching for brain cancer treatments - Scientists found that the drug panobinostat may be effective at treating diffuse intrinsic pontine gliomas, the leading cause of pediatric brain cancer death. Courtesy of Monje lab, Stanford University, California
Six years ago, Dr. Monje started to create and share cell cultures of patients’ DIPG cells that could be studied in labs. In this study, she and her colleagues used cell cultures collected from 16 patients in the United States and Europe to search for drugs that could kill or stop the growth of DIPG cells. By performing experiments in petri dishes and with mice, they found that panobinostat, a drug designed to change the way cells regulate genes, may be effective at inhibiting DIPG growth and extending survival rates.
“It’s astounding. In only six years, scientists have gone from knowing virtually nothing about this tumor to understanding its underlying genetics and finding a potential therapy,” said Jane Fountain, Ph.D., program director, at the National Institute of Neurological Disorders and Stroke (NINDS), part of NIH. “This study epitomizes collaborative medicine at work. It took a dedicated team of international scientists working with patients, families and foundations to get to this point.”
The scientists begain their work by performing high-throughput screening experiments, an advanced method for rapidly searching for effective compounds. The screening simultaneously tested 83 known or potential cancer drugs on each of the DIPG cell lines. They found that drugs called histone deacetylase (HDAC) inhibitors consistently slowed DIPG growth. Several of these drugs block histone deacetylases, a group of enzymes that regulate genes by removing chemical tags, called acetyl groups, from histone proteins. The scientists saw similar results when they genetically blocked individual histone deacetylases in the DIPG cells.
The scientists also analyzed the genes of each cell line. After reviewing the genetic and screening data they decided to focus on panobinostat, a drug designed to block multiple types of histone deacetylases. In petri dishes, they showed that panobinostat inhibited the growth of 12 out of 16 DIPG cell lines. When the scientists placed DIPG cells in the pons area of mice they found that systemic injections of panobinostat inhibited DIPG growth and extended survival.
“All roads lead to histones,” said Dr. Monje. “Our results support the idea that histone modifications are the keys to understanding and treating DIPG.”
Located in a cell’s nucleus, histones are protein complexes that act like genetic spools wound with genes on chromosomes. Enzymes, including histone deacetylases, influence how chromosomes wind around histones by adding or removing chemical tags. In turn, the tagging indirectly, or epigenetically, controls whether a gene on a chromosome will be used, or expressed, in that cell.
The scientists showed that panobistat may be effective at treating a variety of DIPG tumors. Approximately 80 percent of DIPG tumors have a specific mutation in a histone gene. This mutation, called H3K27M, blocks the ability of an enzyme called a methyltransferase from adding a chemical tag, called a methyl group, to the histone. Although the H3K27M mutation disrupts a different chemical tagging system, the scientists showed that panobinostat slowed the growth of a line of cells that had the mutation. Panobinostat also slowed the growth of DIPG cells that do not have that mutation.
Finally the scientists showed that panobinostat may work in combination with other treatments. Studying H3K27M cells that developed resistance to panobinostat over time, they showed that GSKJ4, a drug that blocks the removal of methyl groups from histones, slowed tumor growth. Combining panobistat and GSKJ4 appeared to slow growth further, suggesting the two compounds work synergistically.
“This may be a first step to finally improving the prognosis of this seemingly untreatable disease,” said Dr. Monje.
Dr. Monje, together with the National Cancer Institute-supported Pediatric Brain Tumor Consortium and Novartis, is planning to conduct clinical trials to test the safety and effectiveness of panobinostat for children with DIPG.
This work was supported by grants from NINDS (NS070926), the National Cancer Institute (CA098543), the DIPG Collaborative External Web Site Policy (The Cure Starts Now Foundation, Reflections of Grace Foundation, Smiles for Sophie Foundation, Cancer-Free Kids Foundation, Carly’s Crusade Foundation, Jeffrey Thomas Hayden Foundation, Soar with Grace Foundation), Accelerate Brain Cancer Cures Foundation, The Lyla Nsouli Foundation, CureSearch for Childhood Cancer, The Team Julian Foundation, Alex’s Lemonade Stand Foundation, McKenna Claire Foundation, Connor Johnson Memorial Fund, Dylan Jewett Memorial Fund, Dylan Frick Memorial Fund, Abigail Jensen Memorial Fund, Zoey Ganesh Memorial Fund, Wayland Villars Memorial Fund, Jennifer Kranz Memorial Fund, Virginia & D.K. Ludwig Fund for Cancer Research, Price Family Charitable Fund, Matthew Larson Foundation, Godfrey Family Fund in memory of Fiona Penelope, Child Health Research Institute at Stanford Anne T. and Robert M. Bass Endowed Faculty Scholarship in Pediatric Cancer and Blood Diseases, Etoile de Martin, Foundation LEMOS and Le Defi de Fortunee, Scott Carter Foundation, Semmy Foundation, Department of Defense, Marie Curie (IRG270459), Spanish Ministry of Health (PI13/0125), St. Baldrick’s Foundation, and Iron Matt Foundation.
The NINDS is the nation’s leading funder of research on the brain and nervous system. The mission of NINDS is to seek fundamental knowledge about the brain and nervous system and to use that knowledge to reduce the burden of neurological disease.
About the National Institutes of Health (NIH): NIH, the nation's medical research agency, includes 27 Institutes and Centers and is a component of the U.S. Department of Health and Human Services. NIH is the primary federal agency conducting and supporting basic, clinical, and translational medical research, and is investigating the causes, treatments, and cures for both common and rare diseases. For more information about NIH and its programs, visit www.nih.gov.
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References

Grasso et al. “Functionally-defined Therapeutic Targets in Diffuse Intrinsic Pontine Glioma,” Nature Medicine, May 4, 2015. DOI: 10.1038/nm.3855

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