Primary liver cancer is now the second leading cause of cancer-related death worldwide, and its incidences and mortality are increasing rapidly in the United Stated. In late stages of the malignancy, there are no effective treatments or drugs. However, an unexpected finding made by a team of University of California San Diego School of Medicine researchers sheds light on the development of a new strategy for prevention of liver cancer.
While studying the pathogenic mechanisms of liver cancer, the researchers discovered that a commonly used synthetic double-stranded RNA (dsRNA) strongly boosts a variety of anti-tumor innate immune functions. They suggest it may have the potential to be administered as a vaccine to prevent cancer in individuals at high-risk of developing liver cancer.
“The liver has unique immune tolerance, which is why existing treatments, including immunotherapy, have little to no lasting effects on liver cancer,” said Gen-Sheng Feng, PhD, professor of pathology and molecular biology at UC San Diego and senior author on the paper. “We were initially performing gene deletion to investigate how different types of cells communicate in the liver to promote or suppress cancer development when we found that this synthetic double-stranded RNA prevented liver cancer from initiating by harnessing the body’s own innate immune system.”
In the findings, published online on November 14 in Cell Reports, researchers describe how dsRNA polyinosinic-polycytidylic acid (pIC) prevented primary liver cancer from occurring in mouse models when it was injected into the body cavity during the pre-cancer stage. Primary liver cancer is cancer that begins in the liver; metastatic liver cancer starts elsewhere in the body and spreads to the liver.
The study showed that the formation of tumors — or tumorigenesis — was suppressed by reprogramming macrophages (specialized immune cells that destroy targeted cells) and activation of natural killer cells and dendritic cells that kill tumor cells directly or boost adaptive immunity.
Mouse models with tumors induced either by chemical carcinogen or fatty liver diseases were injected with pIC at different stages. Tumor inhibition was successful in all models that received the dsRNA before tumor formation. The greatest decrease in tumor numbers and size was seen when pIC was administered at one month. At three months the impact was reduced but still significant. At five months, when tumors had already began to form, there was little inhibitory effect observed when comparing tumor numbers or sizes to control groups.
Future studies will look at dosages and timing of pIC as a vaccine, said Feng. In addition, the researchers will evaluate the use of pIC in combination with other agents to stop tumor growth when cancer has already initiated.
“The findings suggest that the drug may prevent liver cancer. We have more work to do, but we could make a real impact at a time when liver cancer rates are increasing,” said Feng, also a researcher with UC San Diego Moores Cancer Center. “There is a large population living with chronic liver disease who are at high risk of developing cancer. If we can develop a vaccine that prevents tumor formation or a therapeutic combination that stops existing cancer from growing, we could reduce the rapid increase of liver cancer rates.”
Liver cancer in adults is among the leading causes of cancer mortality in the world, with more than 780,000 new cases and 740,000 deaths each year. More than 40,000 new cases are diagnosed and 29,000 deaths are reported in the United States annually.
Co-authors include: Jin Lee, Rui Liao, Gaowei Wang, Bi-Huei Yang, Xiaolin Luo, Nissi M. Varki, Wenxian Fu, UC San Diego; Shuang-Jian Qiu, Fudan University; and Bing Ren, Ludwig Cancer Research Institute and UC San Diego.
This research was funded, in part, by the National Cancer Institute (R01CA176012, R01CA188506), National Institute of Diabetes, Digestive and Kidney Disease (P30DK063491) and Juvenile Diabetes Research Foundation (JDRF 2-SRA-2016-306-S-B).
UC San Diego