Public Release: 

Ovarian cancer: Quick steps to widespread disease

Blocking glycogen, a key energy source, could slow or prevent tumor spread

University of Chicago Medical Center


IMAGE: These are pathways of early (proliferation) and late (proliferation, invasion and widespread) metastasis. view more 

Credit: Study authors working with Cell Metabolism

In nearly 80 percent of women with ovarian cancer, the disease has already spread to the omentum before it was diagnosed. Within the omentum -- a large, energy-dense fat pad that covers the intestines -- the cancer grows even faster.

In the December 4, 2018 issue of Cell Metabolism, published online August 30, a multi-center research team based at the University of Chicago Medicine describes how rapidly spreading ovarian cancer cells take the next steps. Once they infiltrate the omentum and begin to deplete the fat cells there, the tumor recruits cancer-associated fibroblasts (CAFs). These cells accelerate cancer proliferation and spread by enhancing the mechanisms that cancer cells use, such as increasing blood flow to the tumor, to generate additional energy sources.

In their current study, "Fibroblasts mobilize tumor cell glycogen to promote proliferation and metastasis," the researchers used a technique called quantitative phosphoproteomics to characterize the reciprocal signaling between human ovarian cancer cells and the CAFs that hasten the spread of abdominal cancers.

When the researchers grew human ovarian cancer cells together with CAFs in the lab, they were able to detect key components of their cellular crosstalk. This allowed the researchers to unravel the role of glycogen in the metabolism and rapid spread of ovarian cancers.

"This is the first time that the role of glycogen in cancer metastasis has been thoroughly investigated," said the study's senior author, Ernst Lengyel, MD, PhD, the Arthur L. and Lee G. Herbst Professor and Chairman of Obstetrics and Gynecology at the University of Chicago.

"No systematic study of the signaling pathways initiated by human cancer cells and cancer-associated fibroblasts has been performed," he added. "We think this could have significant clinical implications."

The authors summarized the cascade of events that fuel disease spread: Fibroblast-derived chemical signals help mobilize glycogen in cancer cells, which is then metabolized into glucose/sugar. This is used by cancer cells as a source of energy, helping those cells invade other tissues. It also boosts tumor aggressiveness, enhancing proliferation, invasion and metastasis.

The authors suggest, however, that inhibition of one step in the process, blocking glycogen mobilization in cancer cells by interfering with enzymes mobilizing glycogen, or inhibiting signaling pathways that prevent the glycogen mobilization stimulated by CAFs, "might be a therapeutic strategy for the reduction of tumor dissemination in abdominally metastasizing cancers after optimal tumor reduction."


This study was supported by the Cancer Research Foundation Fletcher Scholars Program, Bears Care, the National Cancer Institute, and the European Commission.

Additional authors were Marion Curtis, Hilary Kenny, Bradley Ashcroft, Abir Mukherjee, Alyssa Johnson, Yilin Zhang, Diane Yamada, Ricardo Lastra and Anthony Montag from the University of Chicago; Raquel Batlle, Nuria Gutierrez and Angel Nebreda from the Barcelona Institute of Science and Technology; Ynes Helou, Nagib Ahsan, and Arthur Saloman from Brown University; and Xiaojing Liu, Xia Gao, and Jason Locasale from Duke University.

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