Posted on Dec 10, 2020, 6 p.m.
According to a recent study from Harvard Medical School, high-fat diets allow cancer cells to outcompete immune cells for fuel, this impairs immune function and accelerates tumor growth in mice studies. This is done by cancer cells rewiring their metabolisms to increase fat consumption, and blocking the rewiring enhances anti-tumor immunity.
Over the years obesity has been linked to an increased risk for various different types of cancer, as well as a worse prognosis and survial. Obesity-related processes have been identified that drive tumor growth such as metabolic changes and chronic inflammation, but a detailed understanding of the mechanisms between obesity and cancer remains unknown.
Findings published in Cell may help to reveal a piece to this puzzle and may have surprising implications for cancer immunotherapy in that obesity allows cancer cells to outcompete tumour-killing immune cells in a battle for energy/fuel. The report describes how a high-fat diet reduces the numbers and antitumor activity of CD8+ T-cells which are critical immune cells inside of tumors. This happens because cancer cells can reprogram their metabolism in response to increased fat availability to better absorb the energy-rich fat molecules, thus depriving T-cells of fuel and accelerating tumor growth.
"Putting the same tumor in obese and nonobese settings reveals that cancer cells rewire their metabolism in response to a high-fat diet," said Marcia Haigis, professor of cell biology in the Blavatnik Institute at HMS and co-senior author of the study. "This finding suggests that a therapy that would potentially work in one setting might not be as effective in another, which needs to be better understood given the obesity epidemic in our society."
Blocking this fat-related metabolic cell reprogramming was found to significantly reduce tumor volume in mice who were fed high-fat diets. In this study, the effects of obesity were investigated in mouse models of different types of cancer. The animals were fed either normal or high-fat diets, with the HFD leading to increased body weight and other obesity-related changes. Then the team examined different cell types and molecules inside and around the tumors/ the tumor microenvironment. Findings may suggest new strategies for improving immunotherapies that activate the immune system against cancer as CD8+ T-cells are the main weapons used in such therapies.
"Cancer immunotherapies are making an enormous impact on patients' lives, but they do not benefit everyone," said co-senior author Arlene Sharpe, the HMS George Fabyan Professor of Comparative Pathology and chair of the Department of Immunology in the Blavatnik Institute.
"We now know there is a metabolic tug-of-war between T cells and tumor cells that changes with obesity," Sharpe said. "Our study provides a roadmap to explore this interplay, which can help us to start thinking about cancer immunotherapies and combination therapies in new ways."
The researchers found that tumors grew much more rapidly in animals on high-fat diets compared to those on normal diets. But this occurred only in cancer types that are immunogenic, which can contain high numbers of immune cells; are more easily recognized by the immune system; and are more likely to provoke an immune response.
Experiments revealed that diet-related differences in tumor growth depended specifically on the activity of CD8+ T cells, immune cells that can target and kill cancer cells. Diet did not affect tumor growth rate if CD8+ T cells were eliminated experimentally in mice.
Strikingly, high-fat diets reduced the presence of CD8+ T cells in the tumor microenvironment, but not elsewhere in the body. Those remaining in the tumor were less robust -- they divided more slowly and had markers of decreased activity. But when these cells were isolated and grown in a lab, they had normal activity, suggesting something in the tumor impaired these cells' function.
The team also encountered an apparent paradox. In obese animals, the tumor microenvironment was depleted of key free fatty acids, a major cellular fuel source, even though the rest of the body was enriched in fats, as expected in obesity.
These clues pushed the researchers to craft a comprehensive atlas of the metabolic profiles of different cell types in tumors under normal and high-fat diet conditions.
The analyses revealed that cancer cells adapted in response to changes in fat availability. Under a high-fat diet, cancer cells were able to reprogram their metabolism to increase fat uptake and utilization, while CD8+ T cells did not. This ultimately depleted the tumor microenvironment of certain fatty acids, leaving T cells starved for this essential fuel.
"The paradoxical depletion of fatty acids was one of the most surprising findings of this study. It really blew us away and it was the launch pad for our analyses," said Ringel, a postdoctoral fellow in the Haigis lab. "That obesity and whole-body metabolism can change how different cells in tumors utilize fuel was an exciting discovery, and our metabolic atlas now allows us to dissect and better understand these processes."
Hot And Cold
Through several different approaches, including single-cell gene expression analyses, large-scale protein surveys and high-resolution imaging, the team identified numerous diet-related changes to metabolic pathways of both cancer and immune cells in the tumor microenvironment.
Of particular interest was PHD3, a protein that in normal cells has been shown to act as a brake on excessive fat metabolism. Cancer cells in an obese environment had significantly lower expression of PHD3 compared to in a normal environment. When the researchers forced tumor cells to overexpress Ph.D., they found that this diminished a tumor's ability to take up fat in obese mice. It also restored the availability of key free fatty acids in the tumor microenvironment.
Increased PHD3 expression largely reversed the negative effects of a high-fat diet on immune cell function in tumors. Tumors with high PHD3 grew slower in obese mice compared to tumors with low PHD3. This was a direct result of increased CD8+ T cell activity. In obese mice lacking CD8+ T cells, tumor growth was unaffected by differences in PHD3 expression.
The team also analyzed human tumor databases and found that low PHD3 expression was associated with immunologically "cold" tumors, defined by fewer numbers of immune cells. This association suggested that tumor fat metabolism plays a role in human disease, and that obesity reduces antitumor immunity in multiple cancer types, the authors said.
"CD8+ T cells are the central focus of many promising precision cancer therapies, including vaccines and cell therapies such as CAR-T," Sharpe said. "These approaches need T cells to have sufficient energy to kill cancer cells, but at the same time we don't want tumors to have fuel to grow. We now have amazingly comprehensive data for studying this dynamic and determining mechanisms that prevent T cells from functioning as they should."
More broadly, the results serve as a foundation for efforts to better understand how obesity affects cancer and the impact of patient metabolism on therapeutic outcomes, the authors said. While it's too early to tell if PHD3 is the best therapeutic target, the findings open the door for new strategies to combat cancer through its metabolic vulnerabilities, they said.
"We're interested in identifying pathways that we could use as potential targets to prevent cancer growth and to increase immune antitumor function," Haigis said. "Our study provides a high-resolution metabolic atlas to mine for insights into obesity, tumor immunity and the crosstalk and competition between immune and tumor cells. There are likely many other cell types involved and many more pathways to be explored."
Additional authors on the study include Gregory Baker, Alessia Catozzi, Juan García-Cañaveras, Brandon Gassaway, Brian Miller, Vikram Juneja, Thao Nguyen, Shakchhi Joshi, Cong-Hui Yao, Haejin Yoon, Peter Sage, Martin LaFleur, Justin Trombley, Connor Jacobson, Zoltan Maliga, Steven Gygi, Peter Sorger and Joshua Rabinowitz.
This study was supported by the National Cancer Institute and National Institute of Diabetes and Digestive and Kidney Diseases of the National Institutes of Health (grants U54-CA225088, R01CA213062, R01DK103295, P01AI56299, 5F31CA224601 and T32CA207021), the Ludwig Center at Harvard Medical School, the Evergrande Center for Immunologic Disease, the Glenn Foundation for Medical Research and the American Cancer Society.