Weill Cornell Medicine (WCM) and the New York Genome Center (NYGC) were recently awarded a federal grant from the National Cancer Institute (NCI) to support a joint cancer genomics data center for the research and clinical interpretation of tumors. The grant will provide funding of $490,000 per year over the next five years.

The WCM-NYGC center will perform computational analyses examining DNA and RNA to understand the role of different mutations and to assess their clinical relevance in treating cancer. It is one of 11 specialized genomic data centers nationwide selected to lead the next phase of The Cancer Genome Atlas (TCGA), an initiative between NCI and the National Human Genome Research Institute, which has generated comprehensive, multi-dimensional maps of key genomic changes in 33 types of cancer. The TCGA’s cancer genomics database, comprised of more than two petabytes of genomic data, has been made publically available and is helping the cancer research community improve the prevention, diagnosis and treatment of cancer. By joining this national network, researchers at WCM and NYGC will gain early access to newly produced genomic data, as well as cutting-edge genomic analyses and methods.

The WCM-NYGC multidisciplinary team will be led by co-principal investigators Dr. Olivier Elemento, an associate professor of physiology and biophysics, associate director of the HRH Prince Alwaleed Bin Talal Bin Abdulaziz Al-Saud Institute for Computational Biomedicine and head of the Caryl and Israel Englander Institute for Precision Medicine’s computational biology group at Weill Cornell Medicine; Dr. Mark Rubin, director of the Englander Institute for Precision Medicine and the Homer T. Hirst III Professor of Oncology in Pathology at Weill Cornell Medicine; and Dr. Michael Zody, senior director of computational biology at NYGC. The investigators have a broad range of complementary experience in cancer genomics — Drs. Elemento and Zody in bioinformatics and computational biology, and Dr. Rubin in molecular pathology.

“This is a very exciting collaboration between two outstanding institutions with complementary expertise,” Dr. Elemento said. “The NYGC brings major computational infrastructure strengths and a world-class team of computational biologists. Weill Cornell Medicine brings extensive experience in the clinical interpretation of cancer genomes. It’s a perfect match.”

The goal of this joint center is to obtain new knowledge to understand the correlations between mutations and patient data for research and clinical cancer genomics. The aims of the research are:

• to analyze mutations to predict patients’ responses to immunotherapy
• to facilitate identification of mutations that are driving disease and enabling cancer cells to grow
• to study the role of mutations involving large portions of chromosomal abnormalities

“We are excited about strengthening the collaborative genomic sequencing and bioinformatics research between investigators at Weill Cornell Medicine and the New York Genome Center,” Dr. Zody said, “and delighted for the opportunity to join the next phase of the TCGA program.”

The team has already developed several analytical computer programs that interpret various types of mutations frequently found in cancer genomes and is poised to run these tools on data provided by the TCGA initiative. Over the course of the grant, researchers will develop complementary software and methods designed to improve functional and clinical interpretation of tumor profiles. This collaborative research will utilize Weill Cornell Medicine’s expertise in clinical genomics demonstrated by the first New York State-approved whole exome sequencing test and leverage NYGC’s unique computational infrastructure with more than 5,000 cores and 10 petabytes of storage and data management expertise.

The research carried out by the WCM-NYGC center is designed to advance scientific knowledge in the field of cancer precision medicine and achieve the following objectives:

• the ability to reliably evaluate the precise identity and frequency of clinically relevant mutations in individual tumors and across tumors
• to develop tools for reinterpreting tumor profiles when new clinically relevant mutations become available
• to create software to uncover the immune landscape of individual tumors and predict which patients will likely respond to immunotherapy, which T-cell clones are shared across patients, and which immune checkpoints are more active in individual tumor types.
• to develop broadly applicable tools to uncover the effect of inherited and acquired mutations on expression of known cancer genes, and to annotate complex structural mutations
• to develop tools to detect how mutations correlate with the abnormal expression of genes

Co-principal investigators on the grant include Dr. Toby Bloom, deputy scientific director at the New York Genome Center; Dr. Nicolas Robine, manager of computational biology at the New York Genome Center; Dr. Marcin Imielinski, a core member and assistant investigator at the New York Genome Center and an assistant professor of pathology and laboratory medicine and of computational genomics at the HRH Prince Alwaleed Bin Talal Bin Abdulaziz Al-Saud Institute for Computational Biomedicine at Weill Cornell Medicine; and Dr. Ekta Khurana, an assistant professor of computational genomics in the Institute for Computational Biomedicine and an assistant professor of physiology and biophysics at Weill Cornell Medicine.

This image shows human embryonic stem cell-derived pancreatic beta cell clusters after being transplanted into immunodeficient mice. 

Image credit: Drs. Hui Zeng and Min Guo

An innovative method that uses human embryonic stem cells to model type 2 diabetes caused by genetic mutations may enable researchers to identify drugs that could treat the disease. The research by Weill Cornell Medicine investigators was published Aug. 11 in Cell Stem Cell, and may extend the use of precision medicine to metabolic diseases.

Using precision medicine approaches that target genetic mutations "is becoming commonly used in cancer, and we think it may be an approach we can use for diabetes," said senior study author Dr. Shuibing Chen, an assistant professor of chemical biology in surgery at Weill Cornell Medicine.

Type 2 diabetes is a condition in which the body does not correctly respond to insulin, a hormone that regulates the amount of glucose, or sugar, in the blood. As a result, people with the condition have high blood sugar levels. While obesity is a risk factor for diabetes, people may develop the disease for a variety of reasons. Genomic studies scanning complete sets of DNA have revealed many genetic mutations implicated in diabetes. But the precise role of these mutated genes, including three chosen for this study — CDKAL1, KCNQ1 and KCNJ11I — has been largely unknown.

To determine the functional role of these genetic mutations, Dr. Chen and colleagues, including Dr. Todd Evans, the Peter I. Pressman, M.D. Professor in Surgery at Weill Cornell Medicine, and Dr. Johannes Graumann, an assistant professor of biochemistry at Weill Cornell Medicine-Qatar, used human embryonic stem cells that were directed to function like pancreatic cells. The cells, called beta-like cells, produce, store and release insulin.

The investigators found that mutations in CDKAL1, KCNQ1 and KCNJ11I hinder the function of beta cells, resulting in decreased insulin release and problems with the regulation of blood sugar levels. They found the same to be true when the cells were studied in a Petri dish or when used in mouse studies. CDKAL1 mutations also caused the beta cells to be highly sensitive to high blood sugar and high fat levels, both of which are a common cause of beta cell death in diabetic patients.

The investigators then screened 2,000 drugs and found "one compound in phase II clinical trials that corrects the CDKAL1-related beta cell defect," Dr. Chen said. Dr. Chen and study co-authors Dr. Hui Zeng and Dr. Min Guo have filed a patent on the application of this compound for the treatment of CDKAL-related beta cell defects. Based on these study results, scientists may be able to "develop gene variant-specific therapy for different categories of diabetic patients," she said.

$4 million grant gives Columbia, Weill Cornell Medicine, NewYork-Presbyterian, and NYC Health + Hospitals key role in precision medicine cohort program

NEW YORK, NY, July 8, 2016 — Columbia University Medical Center (CUMC) and Weill Cornell Medicine, in collaboration with NewYork-Presbyterian and NYC Health + Hospitals/Harlem, have been awarded a grant from the NIH for approximately $4 million in fiscal year 2016 to enroll participants in the Cohort Program of President Barack Obama's Precision Medicine Initiative (PMI) — a large-scale research effort to improve our ability to prevent and treat disease based on individual differences in lifestyle, environment and genetics. The five-year award is estimated to total $46.5 million, pending progress reviews and availability of funds.

CUMC is one of several medical centers that will provide expertise and infrastructure needed to launch the PMI Cohort Program. This landmark research effort aims to engage 1 million or more U.S. volunteers from the diversity of America in a significant research effort to improve our ability to advance precision medicine. The program seeks to extend the success of precision medicine in some cancers to many other diseases. Importantly, the program will focus not just on disease, but on ways to increase an individual's chances of remaining healthy throughout life.

"Columbia's university-wide commitment to pioneering research and clinical care in precision medicine coincides perfectly with the national priority established by President Obama to improve health and save lives, and we are deeply enthusiastic about being selected to help lead this effort," said Columbia University President Lee C. Bollinger. "We believe that in years to come, our society will benefit immeasurably from the advances in medical science that will emerge from this collaboration with this team of outstanding New York-based medical centers."

"Cornell University has a distinguished legacy of leading scientific discoveries that address our greatest healthcare challenges," said Hunter R. Rawlings III, interim president of Cornell University. "The launch of this collaboration marks a turning point in our effort to conquer disease and to translate research discoveries into life-changing impact for communities in New York and around the world."

"The PMI Cohort Program aligns perfectly with our own precision medicine effort, which we launched in 2015 in partnership with NewYork-Presbyterian and faculty from across Columbia University," said Lee Goldman, MD, Dean of the Faculties of Health Sciences and Medicine and Chief Executive, CUMC. "This award, in collaboration also with NewYork-Presbyterian, Weill Cornell, and our long-standing colleagues at NYC Health + Hospitals/Harlem, will extend our ongoing successes in taking an individualized approach to treating some cancers and rare genetic diseases to a broader range of human illnesses across the ethnically, culturally, and socioeconomically diverse population we serve. It will also enable us to make sure that research findings benefit our local population and beyond as quickly as possible."

"Precision medicine has the power to fundamentally change the way we understand and treat some of the world's most challenging diseases," said Dr. Augustine M.K. Choi, interim dean of Weill Cornell Medicine. "This NIH grant, and our critical work with colleagues from Columbia, NYC Health + Hospitals/Harlem and NewYork-Presbyterian, will ensure that we are better able to understand the key genetic and other biological drivers of disease and ultimately improve the lives of our patients. We are incredibly honored to be selected for this grant, and grateful to President Obama and the NIH for their bold vision."

"It's an incredible honor for our physicians and researchers to be a part of this historic initiative," said Dr. Steven J. Corwin, president and CEO of NewYork-Presbyterian. "As we delve into new research and discover new prevention and treatment options, this grant gives us a tremendous opportunity to continue to excel in our collective fight against cancer and all life-threatening diseases."

"The 'patient-powered' research that will result from our partnership with CUMC promises to help transform the way we achieve our mission to deliver equitable and culturally responsive care to the city's most vulnerable populations," said Ram Raju, MD, President and CEO of NYC Health + Hospitals. "Our collaboration with CUMC also underscores the critical role that the public hospital system plays in medical education and cutting-edge research to benefit the communities we serve."

"We are pleased and excited that the NIH has chosen the Columbia/Weill Cornell/NewYork-Presbyterian and Harlem Hospital collaboration as one of the partners in this ambitious and fundamentally important program," said Tom Maniatis, PhD, Director of the Columbia/NewYork-Presbyterian Precision Medicine Initiative and co-founder of the New York Genome Center. Dr. Maniatis is also the Isidore S. Edelman Professor and Chair of the Department of Biochemistry and Molecular Biophysics at CUMC. "This award is a validation of our commitment to realize the vision of precision medicine, which identifies relationships between genetic, lifestyle and environmental differences in individuals, and the prevention, diagnosis and treatment of human diseases. This grant also recognizes the successful establishment of the Institute for Genomic Medicine (IGM) at Columbia by its Director, Dr. David Goldstein, who has demonstrated the reality of a precision medicine-based approach to treating children with rare, previously undiagnosed genetic disorders."

"As doctors and scientists, we are committed to providing our patients with the very best, most cutting-edge care to ensure that illness isn't a barrier in their everyday lives," said Dr. Mark Rubin, director of the Englander Institute for Precision Medicine and the Homer T. Hirst III Professor of Oncology in Pathology at Weill Cornell Medicine, and director of the precision medicine program at Weill Cornell Medicine and NewYork-Presbyterian/Weill Cornell Medical Center. "This grant will enable us to detect and delineate the key genetic drivers of disease across the diverse population of patients we serve — and move us closer to fulfilling the promise of precision medicine."

CUMC is one of four centers that have been designated as a regional PMI Cohort Program Healthcare Provider Organization (HPO). As an HPO, CUMC and its partners seek to enroll at least 150,000 volunteers by 2021. By engaging with a number of community organizations throughout New York City, this multicenter collaboration will help to ensure that participants in the PMI Cohort Program represent the geographic, ethnic, racial and socioeconomic diversity of the country that the NIH is hoping to achieve.

Principal Investigators include:

• David Goldstein, PhD, Contact Principal Investigator, professor of genetics and development and Director, Institute for Genomic Medicine
• Ali Gharavi, MD, professor of medicine and Chief, Division of Nephrology
• George Hripcsak, MD, MS, the Vivian Beaumont Allen Professor and Chair of the Department of Biomedical Informatics at CUMC and Director of Medical Informatics Services for NewYork-Presbyterian
• Mark Rubin, MD, director of the Englander Institute for Precision Medicine and the Homer T. Hirst III Professor of Oncology in Pathology Weill Cornell Medicine; director of precision medicine at Weill Cornell Medicine and NewYork-Presbyterian/Weill Cornell Medical Center.
• Rainu Kaushal, MD, chair of the Department of Healthcare Policy and Research at Weill Cornell Medicine; physician-in-chief of healthcare policy and research at NewYork-Presbyterian/Weill Cornell Medical Center
• Margaret Ross, MD, PhD, the Nathan Cummings Professor in Neurology, and a professor of neurology and of neuroscience at Weill Cornell Medicine
• Rhonda Trousdale, MD, Chief of Endocrinology, NYC Health + Hospitals/Harlem

Columbia University Medical Center provides international leadership in basic, preclinical, and clinical research; medical and health sciences education; and patient care. The medical center trains future leaders and includes the dedicated work of many physicians, scientists, public health professionals, dentists, and nurses at the College of Physicians and Surgeons, the Mailman School of Public Health, the College of Dental Medicine, the School of Nursing, the biomedical departments of the Graduate School of Arts and Sciences, and allied research centers and institutions. Columbia University Medical Center is home to the largest medical research enterprise in New York City and State and one of the largest faculty medical practices in the Northeast. For more information, visit cumc.columbia.edu or columbiadoctors.org.

NewYork-Presbyterian

NewYork-Presbyterian is one of the nation's most comprehensive healthcare delivery networks, focused on providing innovative and compassionate care to patients in the New York metropolitan area and throughout the globe. In collaboration with two renowned medical school partners, Weill Cornell Medicine and Columbia University College of Physicians & Surgeons, NewYork-Presbyterian is consistently recognized as a leader in medical education, groundbreaking research and clinical innovation.

NewYork-Presbyterian has four major divisions: NewYork-Presbyterian Hospital is ranked #1 in the New York metropolitan area by U.S. News and World Report and repeatedly named to the magazine's Honor Roll of best hospitals in the nation; NewYork-Presbyterian Regional Hospital Network is comprised of leading hospitals in and around New York and delivers high-quality care to patients throughout the region; NewYork-Presbyterian Physician Services connects medical experts with patients in their communities; and NewYork-Presbyterian Community and Population Health features the hospital's ambulatory care network sites and operations, community care initiatives and healthcare quality programs, including NewYork Quality Care, established by NewYork-Presbyterian, Weill Cornell and Columbia.

NewYork-Presbyterian is one of the largest healthcare providers in the U.S. Each year, nearly 29,000 NewYork-Presbyterian professionals deliver exceptional care to more than 2 million patients.

For more information, visit www.nyp.org and find us on Facebook, Twitter and YouTube.

Weill Cornell Medicine

Weill Cornell Medicine is committed to excellence in patient care, scientific discovery and the education of future physicians in New York City and around the world. The doctors and scientists of Weill Cornell Medicine — faculty from Weill Cornell Medical College, Weill Cornell Graduate School of Medical Sciences, and Weill Cornell Physician Organization — are engaged in world-class clinical care and cutting-edge research that connect patients to the latest treatment innovations and prevention strategies. Located in the heart of the Upper East Side's scientific corridor, Weill Cornell Medicine's powerful network of collaborators extends to its parent university Cornell University; to Qatar, where Weill Cornell Medicine-Qatar offers a Cornell University medical degree; and to programs in Tanzania, Haiti, Brazil, Austria and Turkey. Weill Cornell Medicine faculty provide comprehensive patient care at NewYork-Presbyterian/Weill Cornell Medical Center, NewYork-Presbyterian/Lower Manhattan Hospital and NewYork-Presbyterian/Queens. Weill Cornell Medicine is also affiliated with Houston Methodist. For more information, visit weill.cornell.edu.   

About NYC Health + Hospitals

NYC Health + Hospitals is the largest public health care system in the nation committed to providing equal access to quality, culturally-responsive, affordable health care for all New Yorkers. The system is an integrated network of 11 hospitals, trauma centers, neighborhood health centers, nursing homes, and post-acute care centers. It includes a home care agency and a health plan, MetroPlus. The health system provides essential services to 1.2 million New Yorkers every year in more than 70 locations across the city's five boroughs. Its diverse workforce of more than 42,000 employees are uniquely focused on empowering New Yorkers, without exception, to live the healthiest life possible. NYC Health + Hospitals/Harlem is one of the system's 11 acute care hospitals. The 286-bed hospital provides a broad array of preventive, primary and acute care services. The hospital has an Area-Wide Burn Center, Level I Trauma Center, a Bariatric Surgery Center of Excellence, a designated Stroke and AIDS Center, and received the World Health Organization's UNICEF Baby Friendly designation. For more information, visit nychealthandhospitals.org and stay connected on or Twitter @NYCHealthSystem.

In the dim light of Irene Price's dining room, a small Mickey Mouse cake bears two candles casting a warm glow onto the surrounding faces. As the birthday boy claps along from his high-chair while his family sings "Happy Birthday," a grin of pure joy breaks across his great-grandmother's face. For this cancer survivor, sharing precious moments with family makes beating back the disease so much sweeter.

"You see time through the eyes of your children and grandchildren," said Price, the subject of Episode 3 of the Inside Medicine online video series. "And fortunately, I've been a very lucky lady."

Price is no stranger to cancer. Her son Gary struggled with aplastic anemia as a teenager and she lost her husband Gene to gastric esophageal cancer in 1991. Then, in 2009, Price was diagnosed with bladder cancer.

For five years, Price tried the standard treatments — chemotherapy and a bladder-cancer-specific immunotherapy — both of which she said had shown promise. But then her cancer started to metastasize; she was running out of options — and time.

"I found out my cancer had penetrated the wall of my bladder, so it had to be removed," Price said. "That's when they asked me to take part in precision medicine. I said yes — it's a win-win situation."

Dr. David Nanus speaks with his patient, Irene Price.

With standard bladder cancer treatments proving ineffective, Price's doctors — including Dr. David Nanus, chief of hematology and medical oncology — decided to analyze her tumor using a next-generation DNA-sequencing test called EXaCT-1. The approach, developed by scientists at the Caryl and Israel Englander Institute for Precision Medicine at Weill Cornell Medicine, scours thousands of genes to reveal mutations that drive a patient's cancer and pinpoints the most precise treatment options.

Her doctors made an unexpected find: Price's tumor consisted of cells associated with a form of breast cancer. Based upon this discovery, Price's doctors prescribed a personalized treatment regimen that combined chemotherapy with two breast cancer drugs, Herceptin and Taxol.

"It's precision," Price said. "It's geared to you, and it was recommended that I should go on breast cancer drugs. They wouldn't have thought, and I wouldn't have thought."

As of her last three CT scans, Price is cancer-free. For someone who loves celebrating birthdays like her great-grandson's, Price now makes a special wish for her own.

"What do I wish for myself?" she said. "That things go on just as they are."

 Using the social media hashtag, #WeAreWCM, read more stories to discover the faces behind the medicine and how they are paving the future for innovative healthcare.

A subset of treatment-resistant prostate cancer pathologically resembles small cell lung cancer rather than typical prostate cancer, Weill Cornell Medicine and University of Trento investigators discovered in a new study. The scientists say their findings may lead to more effective ways to diagnose and treat neuroendocrine prostate cancer.

Therapies that cut off the hormone androgen, which fuels tumor growth, are commonly used to treat patients with advanced prostate cancer. While this is initially effective, patients often stop responding and develop treatment resistance. Some of these tumors transform from typical prostate cancer, called adenocarcinoma, into neuroendocrine prostate cancer — an event that scientists have increasingly observed but knew little about how or why it happened.

For their large study, published Feb. 8 in Nature Medicine, Weill Cornell Medicine investigators collaborated with scientists at the University of Trento. They used next-generation sequencing technologies to examine resistance across a spectrum of patients and discovered the genetic, epigenetic and molecular features that underlie neuroendocrine prostate cancer. Their findings illuminate the disease's distinctive characteristics, which may enable researchers to develop biomarkers to help identify this subset of patients with prostate cancer less likely to respond to the next line of hormonal-based therapies. This large dataset can now also be used by researchers to develop new therapeutic approaches for patients.

"We used genomics to better understand how neuroendocrine prostate tumors develop," said lead author Dr. Himisha Beltran, an assistant professor of medicine at Weill Cornell Medicine and director of clinical activities at its Caryl and Israel Englander Institute for Precision Medicine. "These tumors seem to arise clonally from a typical prostate cancer (adenocarcinoma) cell of origin."

Prostate cancer is the leading cause of male cancer death worldwide. The American Cancer Society estimated that 220,000 new cases of prostate cancer were diagnosed in the United States in 2015, and nearly 28,000 men died from the disease.

Microscopic images of treatment-resistant prostate cancer. The top panel shows typical prostate cancer, known as adenocarcinoma, while the bottom depicts neuroendocrine prostate cancer. The investigators also used a technique to detect a genetic deletion associated with prostate cancer; the blue images on the bottom right hand side of the top and bottom panels show the genetic changes between the two forms of cancer. Image credit: Dr. Himisha Beltran/Nature Medicine

While patients with advanced prostate cancer typically respond well to initial and even subsequent hormonal therapies, understanding why patients stop responding can help identify new therapeutic options. Most commonly, tumors remain driven by androgen even during treatment resistance; only a small fraction of patients develop truly androgen-independent disease associated with neuroendocrine features, the investigators said. To discern these differences, scientists examined 114 metastatic tumor samples from 81 patients with resistant prostate cancer enrolled at the Englander Institute for Precision Medicine, including 30 patients with neuroendocrine prostate cancer.

"Usually patients only have one biopsy — the one that leads to a diagnosis — and no more. For this study, we examined cancers that had been rebiopsied after they spread to see how the tumors changed," said Dr. Beltran, who is also a member of the Sandra and Edward Meyer Cancer Center at Weill Cornell Medicine and an oncologist at NewYork-Presbyterian/Weill Cornell Medical Center.

The investigators first compared adenocarcinoma and neuroendocrine prostate cancer tumors under the microscope. The difference was stark: The neuroendocrine tumors looked pathologically different than the adenocarcinoma tumors, Dr. Beltran said. The investigators then sequenced the two tumor types to see if they were genetically and epigenetically the same.

"While the two resistant tumor types (adenocarcinoma and neuroendocrine prostate cancer) were genomically similar, they had distinct epigenomic profiles," said co-senior author Dr. Mark Rubin, director of the Englander Institute for Precision Medicine, the Homer T. Hirst III Professor of Oncology in Pathology and a member of the Meyer Cancer Center at Weill Cornell Medicine. "These changes could potentially explain why the altered cells no longer respond to anti-hormonal therapies."

The investigators found that the features of a person's tumor can evolve over time, and the tumor cells can acquire molecular changes affecting cancer-associated pathways.

"Neuroendocrine tumors evolved from adenocarcinomas, but they are being activated in different ways," said co- senior author Dr. Francesca Demichelis, an associate professor at the University of Trento and an adjunct professor of computational biomedicine in the Institute for Computational Biomedicine and a member of the Meyer Cancer Center at Weill Cornell Medicine, whose laboratory led the computational analyses for this study. "Because of this difference in activation, it may be possible to find new drug targets that can shut down these previously untreatable cells."

These findings may help scientists develop biomarkers to help predict which patients are developing this disease transformation. With that information, physicians may be able to diagnose the condition earlier and intervene with different therapeutic approaches.

"The goal of precision medicine — our goal — is to identify which therapies are most effective for an individual patient and to understand why some patients stop responding to the available therapies that we have," Dr. Beltran said. "This study identifies distinct molecular characteristics associated with neuroendocrine prostate cancer, one subset of treatment resistant prostate cancer. This study is an excellent example of current collaborative and multidisciplinary team science, and the results of this effort between Weill Cornell Medicine, University of Trento, and the Broad Institute, will serve as an important resource for future research focused on how to more effectively treat patients that have developed this aggressive subtype."

"The Prostate Cancer Foundation applauds the work of Dr. Beltran and colleagues in understanding genomic alterations for patients with severe treatment resistance," said Dr. Howard R. Soule, chief science officer of the foundation. "This work addresses a significant unmet medical need and may ultimately result in improved disease control."

Precision Medicine Team at Weill Cornell Medicine and NewYork-Presbyterian Will Introduce Whole Exome Sequencing Test, EXaCT-1, to Clinical Setting

NEW YORK (November 13, 2015) — A powerful new test that can reveal untapped therapies for patients with advanced cancers by scanning thousands of their genes will soon be available for patients at Weill Cornell Medicine and NewYork-Presbyterian/Weill Cornell Medical Center. The test, EXaCT-1, identifies alterations within tumors — some of which drive cancerous growth — on a magnitude up to hundreds of times greater than similar technologies designed to pinpoint the most precise ways of treating the disease.

Tumor cells from a biopsy of a patient enrolled in the EXaCT-1 pilot program that investigators are culturing in the lab for further biologic studies and drug testing. Image credit: Dr. Loredana Puca

Weill Cornell Medicine recently received approval for EXaCT-1 by the New York State Department of Health. The test was developed by the institutions' precision medicine team. In May, the team published findings on its first 97 patients who underwent the test and found that scanning a patient's tumor to look for any genomic mutations — rather than limiting the screen to mutations commonly associated with a given patient's tumor type — worked. In 92 percent of cases in the pilot program, the precision medicine team was able to recommend new treatment options based on the test's findings. Now that the state has approved the test, precision medicine leaders will begin the process to implement it for large-scale clinical use for oncology patients treated at NewYork-Presbyterian/Weill Cornell. Until that time, patients with advanced cancers will be able to access EXaCT-1 through the Caryl and Israel Englander Institute for Precision Medicine at Weill Cornell Medicine, the research enterprise of the two institutions' joint precision medicine efforts.

"Since President Obama announced his precision medicine initiative in January, there has been a huge push from institutions across the country to establish themselves as leaders in this field," said Dr. Mark Rubin, director of the Englander Institute and the Homer T. Hirst III Professor of Oncology in Pathology at Weill Cornell Medicine, vice chair for molecular and genomic pathology at NewYork-Presbyterian/Weill Cornell, and head of the precision medicine program at both institutions. Dr. Rubin was at the White House when the president announced the initiative, which dedicates $215 million from his proposed 2016 budget to expand data sharing between institutions; develop new tests, like EXaCT-1, that identify genomic drivers in cancer; and calls for more research on how to apply findings in precision medicine to more effective therapies.

"As the only team in the region that can offer this comprehensive and technically advanced test, Weill Cornell Medicine and NewYork-Presbyterian are at the forefront of precision medicine. We are the go-to destination for patients who need the most advanced care," Dr. Rubin said.

Dr. Mark Rubin

Most institutions offer sequencing tests that examine anywhere from 50 to 400 genes within a sample of a patient's tumor to look for disease characteristics that physicians know can be effectively treated with particular drugs or other technologies. Many patients with primary cancers — those of the lung, breast, skin, blood and lymphatic system — will undergo this screening with their initial evaluation. Other patients will have these screenings done after their disease has spread, grown or stopped responding to treatment.

Unlike these focused tests, typically called panel sequencing, the EXaCT-1 assay takes an unbiased, exploratory look at more than 21,000 genes in cells both healthy and malignant, allowing researchers to find alterations in the cancer-development process in unexpected regions of the exome, where DNA is transcribed into RNA. This type of test, known as whole exome sequencing, can be effective in advanced-stage patients for whom other treatments have failed because it uncovers mutations that the less comprehensive tests miss. In practice, this means, for example, that a patient with bladder cancer whom EXaCT-1 shows to share a mutation associated with breast cancer might benefit from a drug typically prescribed to fight the latter type of tumor.

"That's the nice thing about sequencing the entire tumor genome – we cover genes that other tests will miss," said Dr. Olivier Elemento, head of the Englander Institute for Precision Medicine's computational biology group, an associate professor of physiology and biophysics and head of the laboratory of cancer systems biology in the HRH Prince Alwaleed Bin Talal Bin Abdulaziz Al-Saud Institute for Computational Biomedicine at Weill Cornell. "This test is ideal for patients with advanced cancer because it allows us to identify mutations that may be related to the resistance of their disease, and helps us to pinpoint the best way to treat them."

Dr. Olivier Elemento. Photo credit: Roger Tully

The screen requires a blood sample and a sample of the patient's tumor. Computational biologists at the Englander Institute analyze the data and generate patient-and physician-friendly reports that summarize the key clinical and genetic findings. Once the precision medicine team has reviewed the results, it consults with the patient's oncologist at NewYork-Presbyterian/Weill Cornell to help decide which treatment options and clinical trials may best target the patient's disease.

"We're able to do this quickly enough that we can make a significant impact on a patient's treatment plan," Dr. Rubin said. "This means that a patient who's seen by a doctor and started on a treatment will get their results back quickly enough to potentially influence their treatment protocol if the results uncover something new."

Once EXaCT-1 is available in the clinical setting, Dr. Rubin expects that the test will draw many new patients to Weill Cornell Medicine and NewYork-Presbyterian.

"Emerging knowledge from genomic studies is telling us that there are many more mutations than we anticipated, and our test addresses that," Dr. Rubin said. "Patients that would previously have been considered untreatable might now have hope for additional therapeutic approaches."

NewYork-Presbyterian

NewYork-Presbyterian is one of the nation's most comprehensive healthcare delivery networks, focused on providing innovative and compassionate care to patients in the New York metropolitan area and throughout the globe. In collaboration with two renowned medical school partners, Weill Cornell Medicine and Columbia University College of Physicians & Surgeons, NewYork-Presbyterian is consistently recognized as a leader in medical education, ground-breaking research and clinical innovation.

NewYork-Presbyterian has four major divisions: NewYork-Presbyterian Hospital is ranked #1 in the New York metropolitan area by U.S. News and World Report and repeatedly named to the magazine's Honor Roll of best hospitals in the nation; NewYork-Presbyterian Regional Hospital Network is comprised of leading hospitals in and around New York and delivers high-quality care to patients throughout the region; NewYork-Presbyterian Physician Services connects medical experts with patients in their communities; and NewYork-Presbyterian Community and Population Health features the hospital's ambulatory care network sites and operations, community care initiatives and healthcare quality programs, including NewYork Quality Care, established by NewYork-Presbyterian, Weill Cornell and Columbia.

NewYork-Presbyterian is one of the largest healthcare providers in the U.S. Each year, nearly 29,000 NewYork-Presbyterian professionals deliver exceptional care to more than 2 million patients.

For more information, visit www.nyp.org and find us on Facebook, Twitter and YouTube.

Weill Cornell Medicine

Weill Cornell Medicine is committed to excellence in patient care, scientific discovery and the education of future physicians in New York City and around the world. The doctors and scientists of Weill Cornell Medicine — faculty from Weill Cornell Medical College, Weill Cornell Graduate School of Medical Sciences, and Weill Cornell Physician Organization — are engaged in world-class clinical care and cutting-edge research that connect patients to the latest treatment innovations and prevention strategies. Located in the heart of the Upper East Side's scientific corridor, Weill Cornell Medicine's powerful network of collaborators extends to its parent university Cornell University; to Qatar, where Weill Cornell Medicine-Qatar offers a Cornell University medical degree; and to programs in Tanzania, Haiti, Brazil, Austria and Turkey. Weill Cornell Medicine faculty provide comprehensive patient care at NewYork-Presbyterian/Weill Cornell Medical Center, NewYork-Presbyterian/Lower Manhattan Hospital and NewYork-Presbyterian/Queens. Weill Cornell Medicine is also affiliated with Houston Methodist. For more information, visit weill.cornell.edu.

Precision medicine nets early results — with the promise of more to come

By Anne Machalinski

Portraits by John Abbott

When the tests came back, they revealed something unexpected: multiple copies, or amplification, of a gene typically associated with breast cancer growth. Based on these results, Price's medical team targeted the alteration using an approach not FDA-approved for her type of disease — chemotherapy with Taxol and Herceptin, drugs frequently used in breast cancer — and it worked. As of June 2015, the date of her most recent CAT scan, she has shown no evidence of cancer. "I don't think I'd be here without that test," Price says. Her oncologist agrees. "The genomic testing was extremely informative," says Dr. David Nanus, chief of the Division of Hematology and Medical Oncology. "I would never have used Herceptin without the precision medicine data."In December 2013, right before she had her bladder removed, Irene Price heard the term "precision medicine" for the first time. She'd been diagnosed with cancer about five years earlier, and in the interim had exhausted the standard treatments — chemotherapy and a bladder-cancer-specific immunotherapy — both of which had shown early promise. But the once-contained cancer continued to spread, and she was running out of time. Then her doctors told her they planned to analyze her tumor using next-generation DNA-sequencing technology to look for genetic alterations that might point to new treatment options. "I was excited," says Price, a 77-year-old from Livingston, N.J., "and also anxious to see the results."

Caring relationship: Dr. David Nanus with patient Irene Price

While Price represents an early ideal of this approach, patient success stories are expected to multiply as clinicians increasingly target the genomic characteristics of a disease rather than its site of origin. Having already performed comprehensive genomic testing on about 300 patients with advanced cancers over more than two years, the Caryl and Israel Englander Institute for Precision Medicine at Weill Cornell is poised to lead the charge toward making this personalized approach the standard of care. The institute received a generous gift from the Englander family this month to widen its mission to emphasize dermatological malignancies as well as metabolic diseases, cardiovascular disease, genetic disorders, and respiratory diseases and eventually offer precision medicine to as many as 6,000 cancer patients a year. "There's no playbook. We need to establish our own guidelines in real time," says the institute's founding director, Dr. Mark Rubin, the Homer T. Hirst III Professor of Oncology in Pathology. "Our goal is simply to direct the patient to the right care. It's really out-of-the-box thinking, and we're innovating and figuring out what to do all the time."

While the Englander Institute — comprising a growing team of about 50 — offers advanced-stage cancer patients access to the most powerful genomic test in New York State, three years ago the organization didn't even exist. Dr. Rubin is a renowned pathologist and expert in genomics research who has dedicated his career to understanding and combating prostate cancer; he came to Weill Cornell seven years ago to develop a genomics center. Since the early days of his career — which has included work at a number of prestigious institutions like NewYork-Presbyterian/Columbia University Medical Center, the University of Michigan, and Harvard Medical School — he has always believed in the concept that doctors are "clever detectives," making discoveries about their patients based on direct observations and clinical data. "Adding genomics to the toolbox means having thousands of additional pieces of information that can help you make discoveries and answer questions," he says. "That's the genius of medicine."

Guided by his vision, the Institute for Precision Medicine opened in January 2013 as one of the first entities of its kind. Dr. Rubin's first order of business was to gather a dream team of clinicians, researchers, data experts, and others. Its leadership includes Dr. Himisha Beltran, a medical oncologist and physician-scientist who serves as the Englander Institute's director of clinical activities, and Dr. Olivier Elemento, who joined the team from the HRH Prince Alwaleed Bin Talal Bin Abdulaziz Alsaud Institute for Computational Biomedicine (ICB) at Weill Cornell, where he heads the Laboratory for Cancer Systems Biology.

Although Dr. Rubin's team has advocated for precision medicine's potential for years, the approach got widespread attention in January when President Barack Obama used his State of the Union address to announce a national initiative, which earmarked $215 million from the proposed 2016 budget for expanded clinical and research development in the field. More recently, the National Cancer Institute launched a nationwide precision medicine research study that will sort patients into treatment groups based on genomic alterations in their tumors, representing a sea change in oncology. "All of a sudden, there's an environment where people want to know what precision medicine is and what's going on," says Dr. Rubin, who was invited to the Obama initiative's announcement at the White House. "The fact that we are already doing it allows us to drive the conversation and innovation in this field."

A Key Test

Dr. Mark Rubin

To pinpoint individualized therapies, a number of clinicians offer patients a simple genomic test that canvasses a tumor tissue sample for mutations on 50 to 400 genes that can be targeted with proven therapies. This process is called "focused" or "panel" sequencing. But there's a second, more comprehensive type of test that reviews up to a hundred times more genes to uncover alterations basic tests can miss. Called "whole exome" sequencing, this process looks where DNA is transcribed into RNA — a region of the gene called the exome — and helps researchers find new therapeutic pathways for patients who have exhausted standard protocols. While some area medical centers offer the first kind of test, Weill Cornell is the only institution in New York State to offer the second.

The Englander Institute-developed test, called EXaCT-1 (for EXome Cancer Test-1) was recently described in JAMA Oncology by Dr. Beltran and colleagues; it looks for any and all mutations across more than 21,000 genes. Because it doesn't focus on expected mutations or those tied to a specific treatment protocol (what physicians call "actionable"), it's especially effective in pinpointing previously undetected alterations in patients' tumors. (As Dr. Elemento notes: "The advantage of sequencing the entire tumor genome is that we're not going to miss anything.")

Early on, the team decided to focus on patients with advanced-stage cancers. "The typical approach in cancer treatment is that you first start with the most advanced disease, because those patients are out of options," Dr. Rubin explains. "The discovery of an effective drug in this advanced setting paves the way for using it earlier and earlier with the hope that it will prevent the tumor from progressing. That's where we can have a cure."

Dr. Rubin and his team emphasize that the test is not just about sequencing a tumor's DNA. It's about gathering that data — enough to fill a 100-gigabyte hard drive — and then synthesizing it and delivering the results in a way that's easy for the physician to access, read, understand and share. "How the clinician interacts with the data and communicates the findings back to their patient is the most important thing," Dr. Rubin says.

The process — which requires extensive teamwork between surgeons, medical oncologists, and radiation therapy experts — starts with the samples: the patient's blood (the control) and tumor tissue, ideally with a large percentage of abnormal cells. DNA sequencing takes about two days, after which the raw data is sent to a super-computer for additional, automated analysis. At the end of this process, an easy-to-read report — including clinical information, images of the tumor, and a summary of discovered mutations — is generated. Someday soon, Dr. Rubin hopes to benefit patient s by seamlessly delivering such reports directly to a clinician's iPad, Android device, or Apple Watch — "the simplest solution in an elegant, easy way" — but today, it's e-mailed as a PDF file. On it, the list of mutations is grouped into three categories. At the top are mutations that drive cancer growth and are connected to a known treatment protocol; the middle have been previously observed in other tumors and may very well drive the disease but are not well understood and not therapeutically targetable; and the bottom are of unknown significance, and not yet connected to cancer.

On Fridays, the precision medicine team meets in a tumor board to review the results of one to five patients to discuss available treatment options and next steps. From start to finish, the process of running the sequencing test, generating the report, reviewing the findings, and pursuing new treatments currently takes four to six weeks — slower than a focused test that looks at only a few hundred genes, but still fast enough to influence outcome if there's a new therapeutic option available. Dr. Rubin, though, hopes to speed up that timeline to two weeks from the start of the test to the treatment recommendation.

Big Promise, Mixed Results

Genomic testing: Tumor cells, above and image below, from a biopsy of a patient enrolled in a trial evaluating the efficacy of whole exome sequencing. Image credit, above and below: Dr. Loredana Luca

For Irene Price, the standard treatment — flushing out her bladder with a weakened form of a tuberculosis vaccine pathogen, called BCG therapy, and monitoring her disease — was enough to keep the cancer contained within her bladder for years. After it spread to her lymph nodes, Price underwent chemotherapy, and in October 2013 she was given a clean bill of health. But the cancer returned within weeks. That December, she had her bladder removed.

Early in 2014, tumor tissue from that surgery was sequenced and the precision medicine report came back with a targetable alteration: over-expression of a gene called HER2. Amplification of this gene is known to drive cancer growth, and it is frequently detected in breast cancer patients, says Dr. Nanus, who is also the Mark W. Pasmantier Professor of Hematology and Oncology in Medicine and the associate director of clinical services at the Sandra and Edward Meyer Cancer Center at Weill Cornell and NewYork-Presbyterian Hospital. An antibody-based therapy that targets that alteration has saved many lives, but it is not normally used in a patient like Price, who had bladder — not breast — cancer. But because Price had run out of options, and her cancer had spread to her liver — giving her, statistically, about a year to live — they gave it a try. And it worked. "I can tell you very clearly that we would not have been able to find that mutation using a 50-gene panel," says Dr. Elemento, noting that commonly used focused panels do not look for gene amplifications or deletions.

But not all precision medicine results are as straightforward as Price's. While her report included a known alteration that had a highly proven and available therapy connected to it, many patients' reports don't reveal mutations that can be tackled with readily accessible treatments. New research that Dr. Beltran, Dr. Elemento, Dr. Rubin, and colleagues recently published in JAMA Oncology detailed the Englander Institute's work with its first 97 patients. They explained how they were able to pinpoint previously unknown mutations and recommend new therapeutic options 92 percent of the time — but only 5 percent of those patients actually gained access to the recommended treatment. In some cases there wasn't a clinical trial being offered nearby. In others, clinicians couldn't access the proposed drugs, or they were too expensive. "As trials are developing and the medications become more accessible, I think that success rate will change in the coming years," Dr. Beltran says. But for now, she says, accessibility of therapies is one of precision medicine's major limitations.

Even in Price's case, once the clinicians found a target, the recommended treatment wasn't FDA-approved for bladder cancer, so Dr. Nanus and others from the team had to petition her insurance company to pay for it. They gained that approval, but advocating for each and every precision medicine patient — or starting single-subject clinical trials to get them the drugs that they need — is time-consuming and unsustainable. "We need to figure out a process to quickly and seamlessly get FDA approval and move past this bottleneck," Dr. Rubin says.

Another challenge of using the EXaCT-1 test — which reviews genes without looking for specific mutations, like panel tests do — is that the majority of alterations fall into the category of "unknown significance." This is why research is so important, Dr. Beltran says. Some of those alterations are likely driving cancer growth and spread — and by identifying these key drivers and understanding how they work, scientists can develop new therapeutic options — but many others are likely inconsequential to the disease. "We're learning from each individual patient," Dr. Beltran says. "By studying the extremes — people who respond really well and people who don't respond at all when they should — we are learning more about which molecular alterations are important in predicting response to treatment."

To learn more about mutations, the precision medicine team often splits the biopsied tumor tissue in half. (Indeed, a patient can only benefit from precision medicine when his or her cancerous tissue is made available for analysis.) While one part goes toward DNA sequencing, the other is used in the lab to grow mini-tumors (also called organoids) or implanted into mice. These tumors can be propagated indefinitely and treated with various drug combinations in a search for the most effective treatment strategy. In time, the team hopes to identify new targetable mutations and develop treatment protocols based on this bench work.

The Case for Data

While gathering genomic information can help clinicians determine the right treatment for each patient, the development of robust, searchable databases (a process that received early attention from the ICB) is also vital to precision medicine's success. Currently, the Englander Institute has its own internal database, which it updates with information on genetic mutations, associated drug trials, and patient outcomes. But that data set, while growing, is relatively small. Creating databases that incorporate clinical information from patients at institutions across the country and around the world is essential, Dr. Elemento says. "Individual institutions just can't keep up," he says, "and it doesn't make sense for everyone to have their own database." Dr. Rubin agrees. "With vast clinical data, if we have a patient sitting in front of us who has a mutation that we've never seen before, we can ask the question, 'Has anyone ever seen it before?'" he says. "One of the biggest hurdles within precision medicine is to marry clinical and genomic data and also have a way to share that data. Our dream is to find a way to do this."

The New York City Clinical Data Research Network (NYC-CDRN), launched in January 2014, is an early example of effective clinical data sharing to support research. Notable for its breadth and scope, it includes the largest and most diverse collection of patient records in the country, connecting more than 40 million encounters from the medical records of a growing pool of more than 4 million individual patients records from six healthcare systems in New York City. "For common conditions, getting broad data like this is phenomenal," says the project's principal investigator, Dr. Rainu Kaushal, chair of the Department of Healthcare Policy and Research and a national leader in developing medical data systems. "For rare diseases or mutations, it's even more valuable because you can get a significant sample size to study them."

Investigators working on a wide variety of diseases and conditions are already requesting access to the network's data, which could eventually include everything from the results of an annual physical to those of a genomic test, Dr. Kaushal says. Doctors, too, will be able to gain valuable insights from it; for instance, by tracking how cancer patients with a rare mutation have responded to a certain treatment, they can make more informed decisions in treating people with that same genetic make-up.

Dr. Beltran notes that while the identity of individual patients is scrubbed from these databases, it's important that there be a way to re-identify them, if necessary. "I think in the next five years we're going to be able to present patients who have genomic information in their medical records with new findings and treatment options," she says. "If a mutation moves from the 'unknown' to the 'actionable' category, there would be good reason to follow up with patients who have it."

Looking Ahead

While at present the precision medicine approach is primarily used in cancer diagnosis and care, experts agree that in the future it will have wider clinical relevance. As our understanding of human biology improves, Dr. Elemento says, doctors will increasingly look to analyses of "germline" — or heritable — DNA, for alterations that predispose people to Alzheimer's, schizophrenia, pulmonary disease, or other conditions. BRCA1 and BRCA2 mutations — germline DNA variations connected to an increased risk of developing breast or ovarian cancer — are the most prominent examples of how this type of test is used to date.

Increased use of sequencing tests in cancer is likely in the future, too, Dr. Rubin says, especially earlier or more often in the diagnosis and treatment stages. The results may dictate not only how a patient is treated, but also what approaches are used early on, like whether to try the latest immunologic therapies. "I think a year or two from now — but not five — insurance companies will be advocating for patients to have some sort of genomic test before they're approved for treatment," he says.

\But to make this type of test more accessible, its costs will have to decrease. While EXaCT- 1, which is currently being reviewed by the New York State Department of Health for clinical use, currently costs a few thousand dollars per patient on paper, it's likely closer to $30,000 if everyone's time and effort is taken into account, Dr. Rubin says. But that doesn't mean the test — or approach — should be abandoned. "It's like if you were building a prototype car," he says. "The first car might cost $3 million; you would never sell it. But you can't get to the final car that costs $15,000 or $20,000 until you've done all the testing and established a production line. Soon, all of these worries about the turnaround time and cost are going to be trivial." Dr. Nanus agrees, comparing genomic testing's rise in technological sophistication and drop in cost to cell phones, which were once expensive but are now affordable and ubiquitous. "Someday, it will be the standard of care," he says. "Everybody will get their tumor sequenced."

Despite the high cost and mixed results, Dr. Rubin says, there's substantial value in charting new territory in this field. By being in the vanguard, he says, the Englander Institute for Precision Medicine can build things like the EXaCT-1 test from the ground up to its own specifications. He compares the Englander Institute to a start-up company that helps define an industry. "We could wait and then re-enter this arena when there's a kit and the test will be done in an hour," Dr. Rubin says. "But with contributions from pathology, oncology, urology, and computational biology, we're gaining expertise, we're honing our communication platform so that the results make sense to the patient, and we're conducting meaningful research that's going to have a long-lasting impact."

For Price — who still has CAT scans and heart tests every few months, and regularly checks herself for new lumps in her groin, where they appeared in the past — the glass is more than half full. Precision medicine and her Weill Cornell team have bought her more time with her family — allowing her to see the birth of her second great-grandchild, Hailey, in March; to help move her granddaughter to a town just 35 minutes away; and to gather with her extended family to celebrate her grandson's kindergarten graduation this summer. Despite being on maintenance chemotherapy — a Herceptin drip every three weeks for 30 minutes — she's feeling good. "I'm just so thankful," Price says. "I'm not ready to go."

This story first appeared in Weill Cornell Medicine,Vol. 14, No. 2.

A significant investment in Weill Cornell's leading precision medicine program by Overseer Israel Englander and his wife Caryl will expand the scope of the institution's approach to understanding and treating disease through therapies customized to patients' unique genetic profiles.

The gift names the Caryl and Israel Englander Institute for Precision Medicine at Weill Cornell Medical College. The institute uses genomic sequencing to better understand the factors that drive disease development and progression and identify treatments that are most likely to be effective for each patient. The Englander Institute has focused on cancer since its inception in 2013 and this generous gift will widen its mission to emphasize dermatological malignancies as well as metabolic diseases, cardiovascular disease, genetic disorders, and respiratory diseases. The Institute plans to eventually offer precision medicine to as many as 6,000 cancer patients a year.

"Precision medicine is the future of healthcare," said Dr. Mark Rubin, director of the Englander Institute, the Homer T. Hirst III Professor of Oncology in Pathology, and a professor of pathology and laboratory medicine and of pathology in urology. "Physician-scientists at the Englander Institute are making critical discoveries that are changing the lives of our patients and expanding our breadth of scientific knowledge. The Englanders' gift provides us with the resources to further capitalize on this tremendous opportunity."

The gift to Weill Cornell will support the recruitment of six investigators — including a leader in immunotherapy and three computational biologists — to expand the capabilities of its physician-scientists. It will also fund pilot grants for innovative, multi-investigator projects; outfit the Englander Institute with the latest technology and computational resources; and establish an endowment to ensure that it remains at the vanguard of the field.

"We are deeply grateful to the Englanders for their visionary gift, which will enable Weill Cornell to transform the way we practice medicine," said Dr. Laurie H. Glimcher, the Stephen and Suzanne Weiss Dean of Weill Cornell Medical College. "Precision medicine offers great hope for understanding and treating some of the most formidable diseases of our time, and the Englanders' support will ensure that we can continue our work to enhance the care we provide our patients, both now and into the future."

Cornell President Elizabeth Garrett said, "The Englanders have our thanks and admiration for their generosity and targeted investment in the future of one of medicine's most promising fields and an area in which Cornell sets the pace."

"We are immensely appreciative of our generous supporters Caryl and Izzy Englander, whose confidence in the power of precision medicine to enhance human health is as inspiring as it is essential to spark scientific discovery," said Jessica M. Bibliowicz, chairman of Weill Cornell's Board of Overseers. "The Englanders' investment in Weill Cornell will help us expand a robust culture of innovation and maintain our position as a national leader in this field."

"Philanthropic support is critical for the advancement of translational research," said Sanford I. Weill, chairman emeritus of Weill Cornell's Board of Overseers. "Our friends Caryl and Izzy Englander have made their generous gift in an area that holds enormous promise for patients and in which Weill Cornell excels. Joan and I are incredibly grateful."

Computational biologists at the Englander Institute analyze tumor sequencing data and summarize the key clinical and genetic findings into physician-friendly reports that are seamlessly integrated into Weill Cornell's electronic health record system. Using these reports, a team of interdisciplinary specialists, including radiologists, pathologists, computational biologists, basic scientists, oncologists, and surgeons determine the best treatment options for each patient. With patients' permission, tissue samples from sequenced tumors are then saved in a biobank for further research.

The Englander Institute's expanded program will target areas of oncology including melanoma, a rare but serious form of skin cancer that the American Cancer Society estimates will kill about 10,000 of nearly 74,000 Americans diagnosed with it in 2015. Recent breakthroughs in melanoma research have yielded new treatments that target genetic mutations driving the disease, but it has been unclear which patients would most benefit from them; Institute investigators will try to identify those patients. Weill Cornell will recruit an investigator who specializes in melanoma research and provide support for research in immunotherapy, which uses the immune system to attack tumor cells.

"Groundbreaking research over the last few years has revolutionized our understanding of melanoma's molecular changes, bringing newfound hope to patients with advanced metastatic disease for whom treatment has been particularly challenging," said Dr. Richard Granstein, chairman of the Department of Dermatology and the George W. Hambrick, Jr. Professor of Dermatology at Weill Cornell. "With our expertise in genetic medicine and the Englanders' generous support, we expect to give our patients another powerful reason to hope."

Renowned biostatistician Dr. Karla Ballman has been named chief of the Division of Biostatics and Epidemiology in the Department of Healthcare Policy and Research at Weill Cornell Medical College, effective July 15.

Dr. Ballman specializes in designing clinical trials, analyzing complex data, and developing molecular signatures that can help predict whether or not a cancer patient will respond to targeted therapies. She most recently was a professor of biostatistics at the Mayo Clinic College of Medicine and a consultant in the Division of Biomedical Statistics and Informatics at the Mayo Clinic in Rochester, Minn. She is also a former chair of the Division of Biostatistics at Mayo.

In her new role, Dr. Ballman will recruit top-tier biostatisticians who will work closely with Weill Cornell's principal investigators to design translational, clinical and basic research studies, as well as clinical trials, that most effectively answer their central scientific questions. Once these research projects are in progress, biostatisticians will collect, examine and interpret the incoming data, providing key analysis for the scientists. Dr. Ballman will ensure that her team is aligned with investigators from the start of each project, and work to form new and strengthen existing collaborative partnerships within the institution.

"We are so pleased to have Dr. Ballman joining us. She is a talented biostatistician and effective leader," said Dr. Rainu Kaushal, chair of the Department of Healthcare Policy and Research and the Frances and John L. Loeb Professor of Medical Informatics at Weill Cornell, and healthcare policy and research physician-in-chief at NewYork-Presbyterian/Weill Cornell Medical Center. "In her new role, Dr. Ballman will serve as an integral part of our multidisciplinary department. She'll bring her expertise to bear on specific research projects as well as on recruitment of new biostatisticians, and we couldn't be happier to have her on board."  

"Weill Cornell Medical College is an exciting place to be right now," Dr. Ballman said. "Research is growing rapidly — especially in cancer, clinical trials and precision medicine — areas in which I have a background and specialized interest. My goal is to make sure that every investigator is fully supported, and I'm excited to really grow the program to meet that objective."

Dr. Ballman, who is also an associate editor for the high-impact Journal of Clinical Oncology, has spent the last 16 years working in medical statistics, 13 of them in cancer biostatistics. She's received research grants from the National Cancer Institute and National Institutes of Health, and served as biostastics core director for a prostate Specialized Programs of Research Excellence (SPORE) grant and for a brain cancer SPORE.

Dr. Ballman has published more than 130 peer-reviewed articles in publications including Cancer, Lancet, the Journal of Clinical Oncology and Neuro-Oncology, and is a member of the American Society of Clinical Oncology, the Society for Clinical Trials and other professional groups. She serves on the National Cancer Institutes' Brain Malignancies Steering Committee and Gastrointestinal Stromal Tumors Working Group, and was a member of the institute's Breast Cancer Intergroup Committee and Breast Cancer Intergroup Correlative Sciences Committee. She also serves on the U.S. Food and Drug Administration's General and Plastic Surgery Devices Panel, and is a member of the Damon Runyon Investigator Award panel. Dr. Ballman holds two patents for gene signatures. The first predicts the risk for men with rising prostate-specific antigen levels of developing metastatic prostate cancer. The other predicts which women diagnosed with a form of breast cancer called HER2-positive breast cancer will benefit from the medicine trastuzumab (Herceptin).

To get where she is today, though, she said that she took a circuitous path.

"I've always been good at math, but I'm not a mathematician," she said. "I like using math to solve problems that need to be solved."

This interest in problem solving first led her to pursue a doctorate in operations research from the Massachusetts Institute of Technology, which she received in 1991. After a few years teaching at her undergraduate alma mater, Macalester College in St. Paul, Minn., she landed a job at the Mayo Clinic in 1999 — her first in a medical setting.

Research statisticians at the Mayo Clinic are assigned a few medical disciplines to focus on and become experts in so that they can actively assist in developing new studies and clinical trials.

"Statistics is more than just doing the numbers," Dr. Ballman said. "It's doing the numbers within a particular context while trying to solve a specific problem. In order to match the right statistics and the right design, you have to be able to really understand that discipline."

She credits this approach for enabling her to design a clinical trial that eventually led to a change in the way early-stage breast cancer patients are treated. The trial assessed whether a procedure called complete axillary lymph node dissection that removed all lymph nodes in the armpits and surrounding areas in women whose breast cancer had spread to just one node was medically necessary in early-stage patients. The procedure increases the risk that the arm becomes permanently swollen; this occurs in about 10 percent of women who undergo it, and the study found that removing the lymph nodes made no difference in patients' overall outcomes. Today, many women won't have the procedure done because of her work.

Dr. Ballman is dedicated to bringing this integrated and specialized approach to Weill Cornell. She will first recruit statisticians to what she considers to be the biggest need areas: cancer research and clinical trials. Both areas, she said, present interesting challenges for statisticians. For example, they may have to use a different blueprint for effective clinical trials that involve precision medicine approaches in cancer. Dr. Ballman's team will be empowered to enhance study design and how data is processed.

"Getting in at the ground floor and working in a field where you can possibly have an effect on someone's life is always exciting," she said.

Tumor cells from a biopsy of a patient enrolled in the precision medicine trial that investigators are culturing in the lab for further biologic studies and drug testing. Image credit: Dr. Loredana Puca

Much of precision medicine and cancer care focuses on targeting the genomes of specific tumors or metastases. At Weill Cornell Medical College, a research team has now shown that a more global look at the body using next-generation sequencing can offer new insights — and targets — in patients with advanced, treatment-resistant disease.

The research, published May 28 in JAMA Oncology, offers a look at how the Institute for Precision Medicine at Weill Cornell Medical College and NewYork-Presbyterian Hospital is transforming the way that physician-scientists address individualized cancer care.

"Most institutions are using focused or panel sequencing to look at a few hot spot mutation areas in cancer," said senior author Dr. Mark Rubin, the institute's director, the Homer T. Hirst III Professor of Oncology in Pathology and a professor of pathology and laboratory medicine at Weill Cornell. "But we believe that Whole Exome Sequencing, which tests more than 21,000 genes in the cancer's exome, the DNA that is transcribed into RNA, is ideal for patients with advanced cancer where we don't know where the mutations of resistance are."

To conduct their research, Dr. Rubin, lead author Dr. Himisha Beltran and their team of investigators developed a clinical trial and enlisted 97 cancer patients with advanced, treatment-resistant disease. All participants consented to testing their metastatic disease genome as well as their normal tissue with a Whole Exome Sequencing clinical test called EXaCT-1, which was developed at Weill Cornell. The team also developed three-dimensional cancer cells known as organoids from each individual biopsy, as well as xenografts — cancer tissue samples — for animal study, which allowed them to review the genetics of the disease and to test treatments.

"These are patients who had exhausted every treatment option available to them," said Dr. Beltran, an assistant professor of medicine at Weill Cornell. "But with Whole Exome Sequencing — and reviewing the cancer's exome, which is believed to harbor the vast majority of mutations that drive disease — we were able to identify new therapeutic possibilities."

Dr. Mark Rubin

In all, the team examined 154 tumors from the 97 patients and found an average of 16 mutations per patient. Of the mutations, 16 could be immediately targeted by available drugs, 98 had targeted therapies in clinical or preclinical development, and 1,474 will require additional research to understand their clinical or biological significance.

Patients and their clinicians were informed of the results through an EXaCT-1-generated report. A multidisciplinary precision medicine tumor board — which reviewed the patients' genomic sequencing results, medical histories and radiology reports — developed and shared treatment recommendations for 92 percent of cases.

The board's recommendations led to positive outcome for one patient with advanced bladder cancer after a combination therapy successfully reversed the disease's spread to the lungs and liver. Another patient with an aggressive form of prostate cancer went into complete remission during the study, and the investigators used genomic data to understand why he experienced this exceptional response to the common chemotherapy he'd received.

"The dramatic and durable remission that a neuroendocrine prostate cancer patient experienced, even after several years of follow-up, is exceptional," Dr. Rubin said. "This study shows what is possible, both in terms of treatment and advanced learnings, with precision medicine."

But while their study highlighted the promise of precision medicine, it also revealed some challenges: Only five percent of cases could follow the tumor board's recommendations, said Dr. Beltran.

"This was largely because patients did not have access to the recommended therapies through clinical trials or because the drug was not available," she said, a challenge rooted in the field's infancy.

"Yet our study also demonstrates the feasibility of doing an extensive molecular analysis within a short timeframe in order to find potential therapies that had not been used before," she added. "This is an accomplishment that brings us closer to realizing our goal."