MECHANISM OF HOW RED MEAT CONTRIBUTES TO CANCER DISCOVERED

MECHANISM OF HOW RED MEAT CONTRIBUTES TO CANCER DISCOVERED
A new study uncovers the link between dietary iron and cancer progression, offering hope for targeted therapies.
Scientists at the Agency for Science, Technology and Research (A*STAR) and collaborators from the National Cancer Centre Singapore (NCCS) have uncovered a critical link between the overconsumption of red meat and an increased risk of colorectal cancer. Their findings pave the way for new therapeutic approaches targeting telomerase, an enzyme implicated in cancer progression.
Colorectal cancer, which affects the colon or rectum, is the third most common cancer globally and the second leading cause of cancer-related deaths in Singapore. While it is known that both genetics and lifestyle factors, such as diet, contribute to its development, the exact mechanism linking excessive red meat consumption to cancer has remained unclear -- until now.
In a study published in the journal Cancer Discovery, the researchers discovered that iron from red meat reactivates telomerase, an enzyme that extends the ends of DNA chromosomes, driving the progression of colorectal cancer. This breakthrough offers crucial insights into how dietary habits influence cancer development.
Promising New Therapeutic Approach
The study also identified a promising new treatment approach. The research team found that a small molecule, SP2509, can block the reactivation of telomerase in cancer cells by inhibiting iron's interaction with the enzyme. In laboratory tests using cancer cell lines, SP2509 halted telomerase reactivation and reduced tumor growth, presenting a new strategy for combating colorectal cancer.
Scientists from the ASTAR Institute for Molecular and Cell Biology (IMCB) led the cross-disciplinary team, which included scientists from the ASTAR Genome Institute of Singapore (GIS) and clinicians from Singapore General Hospital (SGH) and NCCS.
"Understanding the role of iron in telomerase activation opens up new avenues for addressing colorectal cancer," said Professor Vinay Tergaonkar, Distinguished Principal Investigator at A*STAR IMCB. "Our future research will focus on refining therapeutic strategies that target this mechanism, hoping to develop more effective treatments for patients, particularly those with high iron levels. We are excited about the potential of small molecules like SP2509 to revolutionize cancer care and improve patient outcomes globally."
Research Insights and Methodology
To uncover how high iron levels contribute to colorectal cancer progression, the team studied samples from colorectal cancer patients, using a combination of human colorectal cancer cell lines and advanced laboratory models. By collaborating with clinicians from NCCS, they demonstrated that iron interacts with an iron-sensing protein called Pirin, leading to the reactivation of telomerase in cancer cells -- a key factor in their unchecked growth.
Further chemical screens on human colorectal cell lines identified the small molecule SP2509, which competes with iron for binding to Pirin, effectively inhibiting telomerase reactivation. These findings offer a novel treatment approach and provide valuable insight into the molecular pathways linking high intake of iron-rich red meats to colorectal cancer. Colo-SCRIPT, the national research program that aims to harness insights on distinct colorectal cancer subtypes to reduce cancer incidence and enhance patient outcomes, will leverage these findings under the program's theme to establish the role of environmental, metabolic, and microbial risk factors enabling disease progression.
"Through Colo-SCRIPT, we will continue to investigate the role of iron and other risk factors and their influence on colorectal cancer development. Findings provide valuable insights into how they drive different subtypes of colorectal cancer and can allow us to identify novel methods to prevent and treat the disease," said Associate Professor Iain Tan, Senior Consultant in the Division of Medical Oncology, NCCS.