It is hard for me to contain my enthusiasm about the recent publication in the Journal of the Pancreas by Pamela Itkin-Ansari, PhD, a Hirshberg Seed Grant award recipient in 2011-2012.

Dr. Ansari stated, “For the first time, we have shown that overexpression of a single gene can reduce the tumor-promoting potential of pancreatic cancer adenocarcinoma cells and reprogram them toward their original cell type. Thus, pancreatic cancer cells retain a genetic memory which we can exploit. Additionally, we are screening for molecules-potential drugs-that can induce overexpression of E47.”

The new research study has shown that pancreatic cancer cells can be coaxed to revert back to normal cells by introducing a protein called E47. The finding is promising as it is possible to turn cancer cells back to normal cells.

We congratulate Dr. Itkin-Ansari and her team at the Sanford-Burnham Cancer Institute, UC San Diego, who expressed her appreciation for our support. At the Hirshberg Foundation we are committed to funding research that accelerates our goal of early detection, improved treatment options and a cure.

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Gift will advance breakthroughs in pancreatic cancer research

Editor’s Note: The following article was originally published on UCLA Newsroom.

“Agi Hirshberg’s 18-year commitment to finding a cure has placed UCLA at the forefront of cutting-edge research in pancreatic cancer,” said UCLA Chancellor Gene Block. “In recognition of her visionary support and a generous new $5-million gift, we are pleased to name the UCLA Agi Hirshberg Center for Pancreatic Diseases.”

Hirshberg established the Hirshberg Foundation for Pancreatic Cancer Research in 1997, in memory of her late husband, Ronald S. Hirshberg, who died of pancreatic cancer age 54. The innovative research inspired by the Foundation has changed the face of pancreatic cancer treatment. As the first beneficiary of the Foundation’s giving, UCLA established the Ronald S. Hirshberg Translational Pancreatic Cancer Research Laboratory in 1998 and the Ronald S. Hirshberg Chair in Translational Pancreatic Cancer Research in 2000.

Hirshberg’s most recent gift will fund seed grants as well as the center’s highest priority needs. The Hirshberg Foundation’s Seed Grant Program has helped propel pancreatic cancer research, serving as a springboard for multiple investigations at UCLA and other prestigious institutions and leading to additional investments from the National Institutes of Health and other organizations. Since the program’s inception in 2000, it has generated more than $65 million in additional support for research involving the molecular mechanisms of pancreatic cancer, early diagnosis, surgical and chemotherapeutic treatments, psychosocial approaches to disease management and prevention strategies.

“Agi Hirshberg raised the visibility of this devastating disease and has been instrumental in advancing pancreatic cancer research, not only at UCLA but across the nation,” said Dr. Vay Liang Go, Director of the UCLA Center for Excellence in Pancreatic Diseases. “Her ongoing support of the multiple areas focused on pancreatic cancer at UCLA has led to pioneering investigations that have given many patients a chance to survive one of the most deadly forms of cancer.”

According to Dr. Howard Reber, distinguished professor of surgery emeritus, chief of gastrointestinal and pancreatic surgery, and director emeritus of the newly renamed center, “Agi Hirshberg has had a major role in the growth and development of one of the country’s busiest and most successful clinical programs for the multidisciplinary treatment of pancreatic cancer.

Dr. Anna Gukovskaya from UCLA, a past Hirshberg Foundation Seed Grant recipient, has received more than $8 million in 5-year funding from the National Institute of Diabetes and Digestive and Kidney Diseases, National Institutes of Health, to elucidate the pathogenic mechanism initiating and driving pancreatitis, a common and potentially fatal inflammatory disease of the pancreas. Pancreatitis is a major risk factor in developing pancreatic cancer. This is the first ever multi-institutional and multidisciplinary Program project grant awarded in pancreatitis, with key investigators from Yale University, the University of Wisconsin, University of California, San Diego, Cedars-Sinai Medical Center, and the University of California, Los Angeles.

Dr. Anna Gukovskaya and her team expressed great appreciation and gratitude to the Hirshberg Foundation for their support, which helped generate key preliminary data for this successful application.

It is with happy tears that I share the following news article with you entitled “Researchers discover a metabolic mechanism for resistant pancreatic cancer.”

As part of our 2010-2011 Seed Grant Program, Andrea Viale, MD, was a recipient of a $50,000 award. His research resulted in a recent publication on the resistance of cells in targeted cancer therapy. With this new information, many potential new therapies will be available for cancer treatment.

Upon receiving the news, Dr. Viale said “I am really grateful to the Hirshberg Foundation for having believed in and supported this study from the beginning when experimental data were few and weak. Your support was critical for this research. We are strongly committed to move these findings toward the clinic and improve the outcome of such a dreadful disease.”

Our next grant cycle begins on August 15, 2014 and we expect to receive 50 qualified applicants requesting funding for novel studies. Please help us keep up the outstanding momentum of research discoveries that will change the outcome of a pancreatic cancer diagnosis. Our mission is to save lives and with your support our dream will become a reality!

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Sincerely,

Agi Hirshberg

Founder

Originally published in Health Canal

Mitochondrial function steps in to save cancer cells after tumor-driving mutation is stifled.

Knock out a genetic mutation that’s a driving force behind pancreatic cancer and a few cells quietly hunker down in the resulting scar tissue, nibbling on themselves to survive before roaring back as resistant disease that taps the cell’s normal powerhouses to thrive.  

Scientists at The University of Texas MD Anderson Cancer Center reveal this mode of metabolic resistance to targeted cancer therapy and a way to attack it in a paper published online in Nature.
Their findings raise the possibility of combining a drug that inhibits the function of mitochondria, the cell’s main energy producers, with targeted therapies to thwart pancreatic cancer recurrence.

“Effective therapies that target specific genes can have an incredible initial impact. Cancerous lesions disappear, but they all come back, all of them,” said senior author Giulio Draetta, Ph.D., M.D.,  professor of Molecular and Cellular Biology.  “So there must be something left behind. We’re interested in what’s left behind.”

“Targeting mitochondrial function with drugs called OXPHOS inhibitors to overcome resistance to targeted therapies would be an entirely new paradigm in cancer treatment,” said Draetta, also a professor of Genomic Medicine.

Surviving without KRAS
Draetta said Andrea Viale, Ph.D., instructor in Genomic Medicine and lead author of the paper, wanted to know whether tumor-initiating pancreatic cancer stem cells need an active oncogene to survive.
The scientists’ research focused on KRAS, a gene whose mutated versions are known to drive development and progression of pancreatic ductal adenocarcinoma, largely incurable cancer with only a 6 percent survival rate at five years.

They developed a unique mouse model that allows them to induce KRAS-driven pancreatic cancer and then turn KRAS off. The mice are genetically engineered so that treating them with the antibiotic doxycycline activates KRAS expression in the pancreas.  When the researchers withdrew doxycycline, tumors regressed in two or three weeks, but then returned in 4-5 months with KRAS still turned off.

Nests of surviving cells were found in fibrotic scar tissue left after KRAS-deprived tumors appeared to completely regress.

“The surviving cells were dormant, and there was lots of autophagy – essentially they were eating pieces of themselves,” Draetta said. The survivors had many characteristics of pancreatic cancer stem cells.

Metabolic differences, not genetic mutations, drive resistance
Additional analysis showed that the resistant cells did not arise via genetic selection of new dominant mutations after KRAS was gone.  

Instead, there was strong expression of genes that govern mitochondrial function and mitochondrial respiration.  Cellular mitochondria are the main metabolic power plants of the cell, using oxygen to convert fatty acids and proteins into energy by a process of oxidative phosphorylation (OXPHOS).

The resistant cells also relied less on another method of energy production called glycolysis, the conversion of glucose to energy in the absence of oxygen, which is commonly found in cancer.
“We suspected that this reliance on mitochondrial respiration made these resistant tumors vulnerable to OXPHOS inhibitors,” Draetta said.

OXPHOS and KRAS inhibition work together
The team found that treating resistant cells and KRAS-dependent cells with the OXPHOS inhibitor oligomycin reduced mitochondrial respiration in both cell types.  While KRAS-dependent cells made up for the energy loss by increasing glycolysis, the survivor cells could not compensate for the resulting energy deficit.

Subsequent experiments showed that oligomycin treatment reduced the ability of cells to form tumor spheres and increased the survival of mice.

KRAS so far cannot be directly targeted by a drug but two pathways that it regulates, MEK and PI3K, can.  Draetta said the collaborators are studying combinations of MEK, PI3K and OXPHOS inhibitors as well as moving OXPHOS drugs toward the clinic. MD Anderson’s Institute of Applied Cancer Science is developing an OXPHOS inhibitor.

Draetta and collaborator Lewis Cantley, Ph.D., Joan and Sanford I. Weill Medical College of Cornell University, New York, were awarded a three-year, $1 million grant earlier this year by the Pancreatic Cancer Action Network and the American Association for Cancer Research titled “Developing a novel oxidative phosphorylation inhibitor in pancreatic cancer.”

“This approach will need to be managed carefully because mitochondrial function is required for many vital functions,” Draetta said.  So far preclinical studies indicate this can be done safely, but the next step is to undertake formal toxicology studies.  “We need to be cautiously optimistic at this point.”

“We’re excited that we aren’t just targeting the proliferating cells in a tumor,” Draetta said. “A large portion of a tumor doesn’t proliferate, it’s just sitting there dormant, making a mess, and secreting harmful cytokines that affect patients’ performance status.”

Co-authors with Viale and Draetta are co-lead author Piergiorgio Pettazzoni, Haoqiang Ying, Nora Sanchez, Matteo Marchesini, Alessandro Carugo, Tessa Green, Florian Muller, Simona Colla, Luigi Nez, Giannicola Genovese, Angela K. Deem, Avnish Kapoor, Wantong Yao and Y. Alan Wang of Medical Genomics;  Costas Lyssiotis and Cantley of Weill Cornell Medical College, New York; Sahil Seth, Virginia Giuliani, Maria Kost-Alimova, and Timothy Heffernan of MD Anderson’s Institute for Applied Cancer Science;  Emanuela Brunetto of San Raffaele Scientific Institute, Milan, Italy; Ya’an Kang and Jason Fleming of Surgical Oncology at MD Anderson; Min Yuan,  and John M. Asara of Beth Israel Deaconness Hospital, Boston;  Alec Kimmelman of Dana-Farber Cancer Institute, Boston; Huamin Wang MD Anderson Pathology; and Ronald DePinho, MD Anderson Cancer Biology.

This research was funded by the Hirshberg Foundation for Pancreatic Cancer Research, the Harvard Stem Cell Institute, Sheikh Ahmed Center for Pancreatic Cancer Research at MD Anderson, American Italian Cancer Foundation, The National Cancer Institute of the National Institutes of Health (P01CA117969, NCI P01CA120964), The Viragh Family Foundation,  a Pancreatic Cancer Action Network-AACR Pathway to Leadership Fellowship and MD Anderson’s NCI Cancer Center Support Grant (CA16672).

In our 2012-2013 Seed Grant Program Alexander Tzatsos, MD, PhD, was a recipient of a $50,000 award to study the epigenetics of pancreatic cancer. We are pleased to announce he has just received more than $1 million in funding from National Institute of Health (NIH). This recognition of Dr. Tzastos’s work is another positive outcome for our investment towards the cure!

Dr. Tzastos shared his appreciation with us. “We are really happy and fortunate that we secured significant funding to study pancreatic cancer for the next 3-4 years. In fact, this is largely due to the seed grant from the Hirshberg Foundation that allowed us to take the risk and generate all the necessary preliminary data to submit those successful applications.”

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The Hirshberg Seed Grant Program began in 2000 to provide start-up funds for scientists with innovative ideas for improving diagnosis, developing new treatment modalities and to impact the understanding of pancreatic cancer cell biology. To date, we estimate $45 million in government funding received from our selected awardees. We thank our distinctive Scientific Advisory board for their outstanding collaboration.

Our next grant cycle begins on August 15, 2014 and we expect more qualified applicants than ever before. We need your continued support to take us another step closer to a pancreatic cancer-free life!