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Genomics Revolution Personalizing Brain Cancer Treatment
1. Genomics: Personalized Medicine in Brain Cancer?
Stephen Shiao MD, PhD
Assistant Professor
Cedars-Sinai Medical Center
Department of Radiation Oncology
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Why genomics and cancer?
Cancer is a disease of
Identification of all the genomic changes would help define new and more detailed cancer subsets which has the potential to transform drug targeting, diagnosis and prevention of cancer
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Cancer and the Genomics Revolution
Cancer biology and genome sequencing technology have advanced together at extraordinary rates
Cancer genomics have identified over 500 genes associated with various cancers
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Next Generation Sequencing
Massively parallel sequencing has dramatically enhanced sequencing time:
1980s – slab gel sequencing, time to sequence a single human genome = 146 years
1990s – capillary sequencing, human genome = 7.5 years
2005 Massive parallel pyrosequencing, human genome = 33 days
2007 Sequencing by synthesis, human genome = 15 days
2010 Single molecule sequencing, human genome = 4 hours
2013 Multiple new parallel sequencing techniques, human genome = 15 minutes
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Next Gen Sequencing: Gene Regulation
Epigenetics (DNA, Histone Methylation)
NoncodingRNA, MicroRNA (lncRNA, miRNA)
Copy number alterations (Single-nucleotide polymorphism (SNP) analysis)
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The Age of Bioinformatics: Network and Functional Analysis
Mapping genomic data onto both known and inferred regulatory networks is the next level of analysis being applied to cancer biology
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The Cancer Genome Atlas
Traditional pathologic classification has been problematic in that they have no biological basis and were unable to predict rational therapeutic strategies for any given tumor
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Subtypes can predict survival
Lin et al. PLoSOne. 2014.
Why do subtypes predict survival and can we change our practice to find better targets?
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The Dream
As a new generation of drugs are developed that target specific protein targets, personalized treatment for brain cancer will mean more than classifying patients but rather identifying small subset of patients who are likely to respond to a particular agent.
Drug signatures may have the potential to guide clinical trial by enabling the selection of patients who have the best chance of responding to the drug under investigation.
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Chemosensitivity can be tested in vitro
Pathway specific gene expression
Drug specific gene expression signatures
Gene Chips
Foundation Medicine
Cedars-Sinai
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Genomics in Action: The Case of WEE1
Wuchty and colleagues integrated miRNA and gene expression data from glioma tumor samples and found a network of miRNAs strongly associated with the kinase WEE1
Mir and colleagues profiled protein expression level of all human kinases between different cancers and demonstrated that the Wee1- like protein kinase is overexpressed in GBM
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What is WEE1?
WEE1 is a kinase that mediates DNA- damage induced cell cycle arrest which allows mutated tumor cells to keep dividing despite DNA damage
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From Genomics to Human Trials
Mir et al found that genetic or pharmacologic inhibition of WEE1 sensitizes glioma cells to radiation and DNA damaging agents in cells and mice
This observation led Merck to develop a WEE1 inhibitor (MK-1775)
NCT01849146:
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Challenges in the Age of Genomics: Too much of a good thing?
Management and curation of large amounts of genome-wide data
Integration of genomic data to understand how diverse alterations in cellular networks gives rise to brain tumors
Translation into therapy
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Genomics at Cedars: Ongoing Projects
Modeling GBM in mice (Breunig Laboratory)
Genomic pathway analysis for tailored therapy (Cedars-Sinai Pathology and Foundation Medicine)
Genomic analysis – Genome Wide Association Studies (GWAS) (Cedars-Sinai Medical Genetics Research Institute)
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Conclusions
Database infrastructure is currently being developed and deployed to efficiently warehouse information to allow both computation and molecular biologists to perform integrated genome-scale analysis of clinical tumor samples on scale previously unimaginable
Bioinformaticians have developed approaches for analyzing this information have led to improve classification of tumor subtypes with corresponding insights into glioma biology
We are just beginning to probe the dense web of connected intracellular pathways that drive the formation, progression and response to treatment of brain tumors
The challenge for researchers, physicians and patients is now to use this information to develop treatment plans that incorporate this information to maximize the outcome for each patient
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References
1.Riddick, G. & Fine, H.A. Integration and analysis of genome-scale data from gliomas. Nature reviews. Neurology , 439-450 (2011).
2.Wuchty, S., et al. Prediction of Associations between microRNAs and Gene Expression in Glioma Biology. PLoS One , e14681 (2011).
3.Mir, S.E., et al. In silico analysis of kinase expression identifies WEE1 as a gatekeeper against mitotic catastrophe in glioblastoma. Cancer cell , 244-257 (2010).
4.Cancer Genome Atlas Research, N. Comprehensive genomic characterization defines human glioblastoma genes and core pathways. Nature , 1061-1068 (2008).
5.Verhaak, R.G., et al. Integrated genomic analysis identifies clinically relevant subtypes of glioblastoma characterized by abnormalities in PDGFRA, IDH1, EGFR, and NF1. Cancer cell , 98-110 (2010).
6.Brennan, C.W., et al. The somatic genomic landscape of glioblastoma. Cell , 462-477 (2013).