News Release

Targeting immune cells that help tumors stay hidden could improve immunotherapy

Peer-Reviewed Publication

University of Pittsburgh Schools of the Health Sciences

Vignali Lab 3-D Microscopic Image of Tumor

image: 

Vignali Lab 3-D microscopic image of a tumor shows Tregs (green), blood vessels (red) and tumor matrix (blue).

Link to high-res version view more 

Credit: Pitt Health Sciences/Vignali Lab

PITTSBURGH, June 15, 2017 - Researchers at University of Pittsburgh School of Medicine and UPMC have discovered a clue that could unlock the potential of immunotherapy drugs to successfully treat more cancers. The findings, published in Cell, were made in mice and showed that targeting a sub-population of immune cells called regulatory T cells could be an effective approach to treating cancers. The findings also point to what could be an important mechanism by which current immunotherapy drugs work, providing clues to making them more effective.

Immunotherapy drugs that push the immune system to detect and kill cancer cells have been successful against several cancers, yet they are still only effective in approximately 10 to 30 percent of patients with certain tumor types. Exactly why these drugs don't work in more patients has remained a mystery. The discovery points to what could be an important mechanism by which current immunotherapy drugs work, providing clues to making them more effective.

Regulatory T cells (Tregs; pronounced "tee-regs") help maintain a delicate balance in our immune system. "They act like a dimmer switch, keeping the lights bright enough to detect and eliminate threats, but not so bright that our own cells are hurt," said Dario Vignali, Ph.D., who holds the Frank Dixon Chair in Cancer Immunology, and is professor and vice chair of immunology at Pitt's School of Medicine.

"In cancer, Tregs can be detrimental because by turning down the lights, they prevent the immune system from detecting and killing cancer cells. While creating drugs to eliminate Tregs may seem like a logical approach to treatment, they could lead to life-threatening autoimmune complications, making them unusable in cancer patients. Thus, we need to identify approaches that selectively target Tregs in tumors, sparing those outside the tumor," said Vignali, who also is co-director of the Cancer Immunology Program at the UPMC Hillman Cancer Center.

A few years ago, Vignali and his colleagues discovered that a surface protein called neuropilin-1 (Nrp1), which is expressed on almost all Tregs that infiltrated mouse tumors, was required to maintain the function, integrity and survival of Tregs within the harsh tumor microenvironment. Thus, Nrp1 on Tregs helps suppress the body's natural anti-tumor immune response thereby helping the tumor survive. Importantly, blocking or deleting Nrp1 in Tregs in mice only impacted their function in tumors and not in the rest of the body, resulting in tumor eradication without inducing autoimmune or inflammatory disease.

"What we've shown in the current study is that in mice, Nrp1 expression by Tregs is required to maintain their ability to prevent the immune system from clearing the tumor. Interestingly, when Tregs lose Nrp1, they not only fail to suppress, they also become active participants in the anti-tumor immune response," said Vignali. "Intriguingly, we also found that in cancer patients who had a poor prognosis, the Nrp1-expressing Treg subset was much higher, suggesting that the findings could apply to humans as well."

To arrive at their findings, the research team created a genetically modified mouse model in which the Nrp1 gene was deleted in only half the Treg cell population, but not the other half. Tumor growth in this model, they found, was dramatically reduced when compared to a normal mouse in which Nrp1 was present in all Tregs.

"Not only did Tregs without Nrp1 have a reduced ability to turn down the lights, they also prevented the normal Treg population from performing their own immunosuppressive functions. This allowed the immune system to see and attack the tumor," said Abigail E. Overacre-Delgoffe, a graduate student in Vignali's lab and the first author of the Cell study. Genomic and cellular analyses revealed that a secreted immune molecule called interferon-gamma (IFNγ) prevented the dimmer switch function of Tregs in the mice, particularly and selectively in the tumor microenvironment.

Using another genetically modified mouse model, they found that the role of IFNγ in diminishing Treg function was crucial to the success of immunotherapies targeting the PD1 protein that have been proven to be very effective in patients. "While we thought that IFNγ might impact the function of Tregs and thus influence immunotherapy outcome, the magnitude of the effect really took us by surprise. When we deleted the receptor for IFNγ in Tregs so they were no longer sensitive to the impact of IFNγ, the immunotherapy drug had absolutely no effect," said Vignali. "In essence, IFNγ seems to make Tregs fragile so that they lose their suppressive function, but only in the tumor. Thus, maybe making Tregs fragile is a critical requirement for effective immunotherapy."

Overall, the authors note that their findings are significant because they show that if we can get a portion of the tumor-associated Tregs to lose their immunosuppressive functions--possibly by using IFNγ--it may be enough to set off a chain reaction where these cells can influence other tumor-associated Tregs, consequently promoting anti-tumor immunity without the adverse autoimmune side effects. Additionally, in the near-term, tracking Treg functional fragility may prove to be an effective approach to monitor whether immunotherapy treatments are effective in patients.

###

Additional authors on the study are Maria Chikina, Ph.D., Rebekah E. Dadey, Hiroshi Yano, Ph.D., Erin A. Brunazzi, Gulidanna Shayan, William Horne, Ph.D., Jessica M. Moskovitz, Jay K. Kolls, M.D., Cindy Sander, Yongli Shuai, Daniel P. Normolle, Ph.D., John M. Kirkwood, M.D., Robert L. Ferris, M.D., Ph.D., Greg M. Delgoffe, Ph.D., Tullia C. Bruno, Ph.D., and Creg J. Workman, Ph.D., all of Pitt.

The study was supported by National Institutes of Health grants R01 CA203689, F31 CA189441, CA047904, CA21765, CA097190, CA121973, P30 CA047904, S10 OD011925, S10 OD019942, and the American Lebanese Syrian Associated Charities. Vignali and Delgoffe have disclosed competing financial interests and have submitted patents regarding Nrp1 that are pending or granted.

About the University of Pittsburgh School of Medicine

As one of the nation's leading academic centers for biomedical research, the University of Pittsburgh School of Medicine integrates advanced technology with basic science across a broad range of disciplines in a continuous quest to harness the power of new knowledge and improve the human condition. Driven mainly by the School of Medicine and its affiliates, Pitt has ranked among the top 10 recipients of funding from the National Institutes of Health since 1998. In rankings recently released by the National Science Foundation, Pitt ranked fifth among all American universities in total federal science and engineering research and development support. Likewise, the School of Medicine is equally committed to advancing the quality and strength of its medical and graduate education programs, for which it is recognized as an innovative leader, and to training highly skilled, compassionate clinicians and creative scientists well-equipped to engage in world-class research. The School of Medicine is the academic partner of UPMC, which has collaborated with the University to raise the standard of medical excellence in Pittsburgh and to position health care as a driving force behind the region's economy. For more information about the School of Medicine, see http://www.medschool.pitt.edu.

About UPMC

A $14 billion world-renowned health care provider and insurer, Pittsburgh-based UPMC is inventing new models of patient-centered, cost-effective, accountable care. UPMC provides nearly $900 million a year in benefits to its communities, including more care to the region's most vulnerable citizens than any other health care institution. The largest nongovernmental employer in Pennsylvania, UPMC integrates 65,000 employees, more than 25 hospitals, 600 doctors' offices and outpatient sites, and a more than 3.2 million-member Insurance Services Division, the largest medical and behavioral health services insurer in western Pennsylvania. Affiliated with the University of Pittsburgh Schools of the Health Sciences, UPMC ranks No. 12 in the prestigious U.S. News & World Report annual Honor Roll of America's Best Hospitals. UPMC Enterprises functions as the innovation and commercialization arm of UPMC while UPMC International provides hands-on health care and management services with partners in 12 countries on four continents. For more information, go to UPMC.com.

http://www.upmc.com/media

Contact: Arvind Suresh
Office: 412-647-9966
Mobile: 412-509-8207
E-mail: SureshA2@upmc.edu

Contact: Cyndy Patton
Office: 412-586-9773
Mobile: 412-415-6085
E-mail: PattonC4@upmc.edu


Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert system.