Finding keys to glioblastoma therapeutic resistance
Researchers at the University of California, San Diego School of Medicine have found one of the keys to why certain glioblastomas – the primary form of a deadly brain cancer - are resistant to drug therapy. The answer lies not in the DNA sequence of the tumor, but in its epigenetic signature. These findings have been published online as a priority report in the journal Oncotarget.
“There is a growing interest to guide cancer therapy by sequencing the DNA of the cancer cell,” said Clark Chen, MD, PhD, vice-chairman of Research and Academic Development, UC San Diego Division of Neurosurgery and the principal investigator of the study. “Our study demonstrates that the sensitivity of glioblastoma to a drug is influenced not only by the content of its DNA sequences, but also by how the DNA sequences are organized and interpreted by the cell.”
The team of scientists, led by Chen, used a method called comparative gene signature analysis to study the genetic profiles of tumor specimens collected from approximately 900 glioblastoma patients. The method allows investigators to discriminate whether specific cellular processes are “turned on” or “turned off” in glioblastomas. “Our study showed that not all glioblastomas are the same. We were able to classify glioblastomas based on the type of cellular processes that the cancer cells used to drive tumor growth,” said Jie Li, PhD, senior postdoctoral researcher in the Center for Theoretical and Applied Neuro-Oncology at UC San Diego and co-first author of the paper.
One of these cellular processes involves Epidermal Growth Factor Receptor (EGFR).
The study revealed that EGFR signaling is suppressed in a subset of glioblastomas. Importantly, this suppression is not the result of altered DNA sequences or mutations. Instead, EGFR is turned off as a result of how the DNA encoding the EGFR gene is organized in the cancer cell. This form of regulation is termed “epigenetic.” Because EGFR is turned off in these glioblastomas, they become insensitive to drugs designed to inhibit EGFR signaling.
“Our research suggests that the selection of appropriate therapies for our brain tumor patients will require a meaningful synthesis of genetic and epigenetic information derived from the cancer cell,” said co-first author Zachary J. Taich.
Understanding glioblastoma
Ever heard of gliomas? These primary brain tumors arise within the brain, but we don’t know the cell of origin.
There are multiple grades of gliomas - grade II, III and IV, with grade IV being the most malignant.
Grade IV tumors are called glioblastoma. They are the most aggressive and are very infiltrative - they spread into other parts of the brain quickly. Glioblastomas don’t metastasize outside of the brain.
Glioblastomas can occur in any lobe of the brain and even the brain stem and cerebellum, but more commonly occur in the frontal and temporal lobes. Below, I’ve answered some common questions I get about glioblastoma.
1. Are there any known causes or risks factors for glioblastoma?
Glioblastoma are more common in males, persons older than 50, and people of Caucasian or Asian ethnicity. There are a few very rare familial syndromes that are associated with brain tumors. One of the only known risk factors that we have for brain tumors is radiation exposure.
2. What are common symptoms of glioblastoma?
The symptoms for any brain tumor are related to the locations from where the brain tumor originates and the rate of tumor growth. Symptoms can vary widely. Some are silent and only found incidentally when a brain scan is done for another reason.
The most common symptoms include headaches, nausea, vomiting and seizures. Tumors frequently cause subtle personality changes and memory loss or, again, depending on location, muscle weakness and disturbances in speech and language.
3. How is a glioblastoma diagnosed?
Most patients with glioblastoma undergo a CT scan, followed by MRI. The actual pathological diagnosis has to be made at the time of surgery (tissue is removed and examined by a neuropathologist).
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Co-authors include Amit Goyal, David Gonda, Johnny Akers, Bandita Adhikari, Kunal Patel and Bob S. Carter, Center for Theoretic and Applied Neuro-Oncology, UCSD; Scott Vandenberg, Department of Pathology, UCSD; Wei Yan, Zhaoshi Bao and Tao Jiang, Department of Neurosurgery, UCSD; Renzhi Wang, Peking Union Medical College Hospital, China; and Ying Mao, Huashan Hospital, Shanghai Medical College, Fudan University, China.
Funding for this research came, in part, from the Sontag Foundation, the Burroughs Wellcome Foundation, the Kimmel Foundation, the Doris Duke Foundation and the Forbeck Foundation.
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Scott LaFee
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University of California - San Diego