P53 Mutation: A Key Player in Cancer Risk for Ulcerative Colitis Patients
P53 mutation increases colon cancer risk in ulcerative colitis patients, highlighting its crucial role in disease progression.
Research has uncovered the role of the p53 gene in ulcerative colitis, suggesting a potential new drug target to prevent disease progression to cancer. ()
New Insights into Ulcerative Colitis and Cancer Risk
A team of researchers led by Kimberly Hartl, a graduate student at the Berlin Institute for Medical Systems Biology of the Max Delbr�ck Center (MDC-BIMSB) and Charit� - Universit�tsmedizin, have shed new light on the role of the p53 tumor suppressor gene in the pathogenesis of ulcerative colitis (UC) - an inflammatory bowel disease that afflicts an estimated five million people worldwide and that is linked to an increased risk of colon cancer. The research points to a new way to stop the disease from progressing. The study was published in the journal Science Advances.‘Researchers have identified the role of the p53 gene in #ulcerativecolitis, paving the way for potential new treatments to prevent #cancer progression. #coloncancer’
"In patients with ulcerative colitis who are at high risk for developing cancer, we could potentially target aberrant cells and get rid of them early, before any cancer occurs," says Professor Michael Sigal, Group Leader of the Gastrointestinal Barrier, Regeneration Carcinogenesis lab at MDC-BIMSB, Head of Luminal Gastroenterology at Charit�, and a senior author of the paper.
Ulcerative colitis affects the large intestine, specifically areas called "crypts," tube-like glands within the epithelial tissue that lines the intestine. Crypts contain stem cells and other cell types that maintain the health and normal function of the colon, such as absorbing nutrients or secreting mucus.
When the colon is injured, epithelial crypt cells enter a "repair mode." They begin to proliferate rapidly to fix the injury. However, in patients with UC and UC-related colon cancers, these cells become stuck in repair mode, which scientists refer to as a "regenerative cell state." As a result, there are too few mature cells. Consequently, the colon struggles to function normally, which triggers even more stem cell proliferation in a toxic feedback loop.
In the current study, Hartl found this defective repair mechanism is linked to a non-functional p53 gene, which plays a key role in regulating the cell cycle and in repairing DNA.
"If there is no p53, cells remain in a proliferative state," Sigal explains.
Existing tests to find precancerous lesions in patients with UC such as colonoscopies can identify visible lesions that sometimes are not easy to remove, says Sigal. This study could be a first step in developing molecular tools for a less invasive diagnostic test that would allow physicians to identify the aberrant cells much earlier, even before visible alterations occur, he adds.
To study the repair process, the researchers developed a three-dimensional organoid - a mini organ - model of the colon grown from mouse stem cells.
Together with specialists in DNA and RNA sequencing as well as proteomics and metabolomic technology at the Max Delbr�ck Center, they found that cells in organoids lacking p53 are stuck in the regenerative state. Thus, the cells metabolize glucose more rapidly via the process of glycolysis. By contrast, when p53 is active, it diminishes glucose metabolism and signals cells to re-enter a healthy state.
The scientists then treated the organoids with compounds that interfere with glycolysis to test whether they can target these highly proliferative cells. They found that cells that lacked the p53 gene were more vulnerable to this treatment than normal cells. "With organoids, we can identify very specific agents that can target metabolic pathways and point us toward potentially new therapeutics to selectively target mutated cells," Hartl adds.
The next step is to transfer these findings to the human setting. The researchers are also now studying the repair process in more detail with the goal of developing more simple methods to identify cells with defective p53 genes in colon tissue.
"Once we have a simple method of identifying these individual cells in colon tissues, we could perform clinical studies to selectively kill them, and then analyze whether this is associated with a lower risk of developing cancer," says Sigal.
Reference:
- P53 terminates the regenerative fetal-like state after colitis-associated injury - (https:www.science.org/doi/10.1126/sciadv.adp8783)