TGen-USC study finds 'precision ,edicine' may not always be so precise

October 26, 2017

PHOENIX and LOS ANGELES -- Oct. 26, 2017 -- Precision Medicine in oncology, where genetic testing is used to determine the best drugs to treat cancer patients, is not always so precise when applied to some of the world's more diverse populations, according to a study led by the Translational Genomics Research Institute (TGen), an affiliate of City of Hope, and the Keck School of Medicine of the University of Southern California (USC).

Precision Medicine in oncology is based upon identifying mutations that have turned normally healthy cells into tumor cells and where possible matching those to targeted therapies. There are two main approaches to identify those changes. Ideally, a patient's tumor, as well as normal tissue -- usually from a blood sample -- are sequenced to identify mutations specific to the tumor.

However, collecting normal tissue is not always possible or feasible, thus tumor-only sequencing is an alternative. One is then left with trying to distinguish normal genetic variation from the actual tumor mutations. In general, population databases are used to filter out genetic changes that are inherited rather than specific to the tumor.

Precision Medicine using this type of tumor-only approach, as a means of guiding therapeutic intervention, is more precise for those of European decent, and less precise for those whose ancestry is from Latin America, Africa and Asia, according to the study published online Oct. 19 in the scientific journal BMC Medical Genomics.

In an effort to help identify those genetic variants that might cause cancer when normal tissue is not available, the TGen-USC team devised a genomic tool with the Harry Potter-ish name of LumosVar. While this tool represents a significant improvement for research purposes, even this technological advance is not of sufficient precision to determine which anti-cancer drugs to give individual patients.

"The field of precision medicine isn't taking into account population differences. The approaches being used are imprecise when you look at very specific populations," said Dr. John Carpten, Director of the Institute of Translational Genomics at the Keck School of Medicine of USC, and one of the study's lead authors.

The problem is multi-pronged:

"It is very difficult to identify a somatic, or potentially cancer-causing, variant when you don't have a germline, or normal, sample," said Dr. Rebecca Halperin, a TGen Assistant Research Professor and the study's other lead author. "It's even worse, depending on your ancestry. You get more false positives -- those genetic variants that don't cause cancer -- from populations with non-European ancestry."

To assist researchers in sorting out false positives, TGen and USC researchers devised a computational tool called LumosVar, a Harry Potter reference to Lumos (light) in the story's magic spells, and Var for genetic variance. LumosVar is essentially a tool to light up the genome's potentially cancer-causing genetic mutations.

"Simply sequencing more individuals from various populations is not enough. We really need access to the germlines. But when those aren't available, we need better tools and this is where we have put our focus," said Dr. David W. Craig, Vice Chair of the Keck School of Medicine of USC's Department of Translational Genomics and the study's senior author.

Drs. Craig and Halperin are the co-creators of LumosVar.

One surprising finding of the study involves the "out of Africa" theory of evolution; the fact that all modern humans across the globe can be genetically traced back to ancestors from Africa. Researchers assumed that because Africa was a starting point that those with African ancestry would be more genetically diverse, and those populations who spread elsewhere across the globe would, as descendants of more recent common ancestors, became less genetically diverse. Instead, rapid population expansion in Africa, as in South America and Asia, over millennia has been the driving force resulting in more genetically diverse individuals.

"The added complexity of identifying inherited genetic changes surprised me and many others we have shared these findings with," said Dr. Craig, who also is a Professor and Co-Director of the Institute of Translational Genomics at the Keck School of Medicine of USC.

"There is a growing body of knowledge on the shortfalls of Precision Medicine," said Dr. Rick Kittles, Professor and Founding Director of the Division of Health Equities, Department of Population Sciences, at City of Hope, and one of world's foremost scientists in the area of population genetics and cancer.

"This study goes beyond the barriers to participation and provides insight on the lack of genetic data from diverse populations and its impact on the value and utility of Precision Medicine. There is still much work to be done in order for all communities to benefit from Precision Medicine," said Dr. Kittles, who was not part of the study, but was asked by the authors to provide perspective on the study's findings.

The problem is not trivial or academic. Patients whose tumor-cell sequencing cannot be matched with their normal-cell sequencing, run the risk of being misdiagnosed, researchers said.

"That means you might be getting the wrong therapy simply because of our lack of understanding of the genetic architecture based on one's ancestry," Dr. Craig said. "These findings argue that we're really not doing a very good job of doing Precision Medicine for many populations."

Dr. Carpten added, "Tumor-only sequencing in patients from populations that have undergone rapid expansion significantly decreases the precision of Precision Medicine. Importantly, the greater impact will be on individuals from underrepresented communities."

Even for those of European ancestry, the lack of normal-cell sequencing to compare to tumor-cell sequencing still poses substantial risk, the study says: "Even within a European ancestry cohort, there are many individuals who still will have a high number of private variants that would result in a higher number of false positives."

Still, the study points to the LumosVar, which the TGen-USC team has offered as an open-source tool for any researcher to use, as a substantial improvement in searching for potentially cancer-causing mutations.

"While the goal of the present study was to evaluate the benefit and limitations of leveraging allele frequencies to distinguish somatic and germline variants in unmatched tumor samples, in the process we have developed a tool that we have made available to the research community," the study says.

"We have clearly demonstrated that LumosVar has improved positive predictive value in calling somatic variants compared to database filtering, which is the most commonly used approach with unmatched tumor samples," the study says. "When analyzing archival samples in a research setting, we believe LumosVar would be of great utility."

The study -- titled: A method to reduce ancestry related germline false positives in tumor only somatic variant calling -- predicts that, as the cost of high-depth sequencing continues to decline, the sensitivity of tools like LumosVar will continue to improve.
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This study was funded by The Ben & Catherine Ivy Foundation and by the Multiple Myeloma Research Foundation.

LumosVar is available for download at: https://github.com/tgen/LumosVar

About TGen

Translational Genomics Research Institute (TGen) is a Phoenix, Arizona-based non-profit organization dedicated to conducting groundbreaking research with life changing results. TGen is focused on helping patients with neurological disorders, cancer, diabetes, and infectious diseases, through cutting edge translational research (the process of rapidly moving research towards patient benefit). TGen physicians and scientists work to unravel the genetic components of both common and rare complex diseases in adults and children. Working with collaborators in the scientific and medical communities literally worldwide, TGen makes a substantial contribution to help our patients through efficiency and effectiveness of the translational process. TGen is affiliated with City of Hope, a world-renowned independent research and cancer and diabetes treatment center: http://www.cityofhope.org. This precision medicine affiliation enables both institutes to complement each other in research and patient care, with City of Hope providing a significant clinical setting to advance scientific discoveries made by TGen. For more information, visit: http://www.tgen.org. Follow TGen on Facebook, LinkedIn and Twitter @TGen.

About the Keck School of Medicine of USC Founded in 1885, the Keck School of Medicine of USC is among the nation's leaders in innovative patient care, scientific discovery, education and community service. The school has approximately 1,650 full-time faculty members and voluntary faculty of more than 2,400 physicians. These faculty direct the education of approximately 800 medical students and 1,000 students pursuing graduate and postgraduate degrees. The school trains more than 900 resident physicians in more than 50 specialty or subspecialty programs and is the largest educator of physicians practicing in Southern California. Together, the school's faculty and residents serve more than 1.5 million patients each year at Keck Hospital of USC and USC Norris Cancer Hospital, as well as USC-affiliated hospitals Children's Hospital Los Angeles and Los Angeles County + USC Medical Center. Keck School faculty also conduct research and teach at several research centers and institutes, including the Zilkha Neurogenetic Institute and the Eli and Edythe Broad Center for Stem Cell Research and Regenerative Medicine at USC. In 2017, U.S. News & World Report ranked Keck School of Medicine among the top 35 medical schools in the country.

Media Contacts:

Steve Yozwiak
TGen Senior Science Writer
602-343-8704
syozwiak@tgen.org

Zen Vuong
USC Health and Medical Research Writer
213-300-1381
zvuong@usc.edu

About The Ben & Catherine Ivy Foundation

The Ben & Catherine Ivy Foundation, based in Scottsdale, Ariz., was formed in 2005, when Ben Ivy lost his battle with glioblastoma multiforme (GBM). Since then, the Foundation has contributed more than $70 million to research in gliomas within the United States and Canada, with the goal of better diagnostics and treatments that offer long-term survival and a high quality of life for patients with brain tumors. The Ben & Catherine Ivy Foundation is the largest privately funded foundation of its kind in the United States. For more information, visit http://www.ivyfoundation.org.

About the Multiple Myeloma Research Foundation (MMRF)

The mission of the Multiple Myeloma Research Foundation (MMRF) is to find a cure for multiple myeloma by relentless pursuing innovation that accelerates the development of next-generation treatments to extend the lives of patients. Founded in 1998 by Kathy Giusti, a multiple myeloma patient, and her twin sister Karen Andrews as a 501 (c) (3) nonprofit organization, the MMRF is a world-recognized leader in cancer research. Together with its partners, the MMRF has created the only end-to-end solution in precision medicine and the single largest genomic dataset in all cancers. The MMRF continues to disrupt the industry today, as a pioneer and leader at the helm of new research efforts. Since its inception, the organization has raised over $350 million and directs nearly 90% of the total funds to research and related programs. As a result, the MMRF has been awarded by Charity Navigator's coveted four-star rating for 12 years, the highest designation for outstanding fiscal responsibility and exceptional efficiency.

The Translational Genomics Research Institute

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