by University of Konstanz

Metabolic profile of p53 mutant variants in pancreatic cancer. Credit: Journal of Experimental & Clinical Cancer Research (2024). DOI: 10.1186/s13046-024-03232-3

When cell growth gets out of control and malignant cells begin to proliferate, cancer can develop in a process known as tumorigenesis. There are always errors in cell division in every body, but sophisticated mechanisms normally ensure that only healthy cells duplicate and damaged cells die—in other words, that tumors do not emerge in the first place.

One helper in this process is the p53 protein. However, when it mutates, it can no longer fulfill its task. Until now, researchers have assumed that the process is the same with all mutation types. A research team from the University of Konstanz has now shown that different mutations have different effects on cell metabolism.

How p53 works

In the case of DNA damage, the p53 protein has the task of blocking the proliferation of the affected cell, thus providing extra time for repairs. Should this repair fail, the cell self-destructs and makes room for a new one that is as flawless as possible. This process is important to ensure that only healthy cells multiply and that uncontrolled proliferation (e.g., cancer) does not occur.

However, p53 can mutate and is then no longer able to entirely fulfill its actual function: Cell growth is no longer delayed, there is no time for repairs and cell death is not initiated. As a result, the degenerated cell eventually multiplies and a tumor can grow. In about one out of two tumors, such a mutation of the p53 protein can be detected. Cancer researchers are therefore striving to better understand and counteract the mutations.

Not all mutations are the same

The research team at the University of Konstanz, led by toxicologist Ivano Amelio, has made good progress in this direction. In a recent study published in the Journal of Experimental & Clinical Cancer Research, they compared two mutations of the p53 protein and were able to show that they have different effects on the metabolism of pancreatic carcinomas.

A review article published in Trends in Cell Biology by Alessio Butera and Amelio provides a perspective on the original research.

"Our study showed that the first variant maintains the mitochondrial function and energy production of the cell and at the same time influences the cellular antioxidant capacity. The second variant did not show this influence, but instead dampened the activation of pro-tumor metabolic pathways, such as the urea cycle," says Amelio.

The finding that the two mutations of the p53 protein selectively control different metabolic pathways in pancreatic carcinomas opens up new avenues in cancer research.

"Previous research has largely assumed that differentiating between the mutation variants of p53 is not all that important, but only the fact that there is a mutation counts," says Amelio. "This assumption has fostered debate around contradicting observations in the field. Our results emphasize the need to no longer view the mutation variants as a homogeneous group, but to systematically examine each variant individually."

According to Amelio, we are only just beginning to understand the real relevance of p53 mutant proteins. Only systematic analyses using models that reflect the tumor ecology more precisely will give us a deeper insight.

More information: Sabrina Caporali et al, Selective metabolic regulations by p53 mutant variants in pancreatic cancer, Journal of Experimental & Clinical Cancer Research (2024). DOI: 10.1186/s13046-024-03232-3

Alessio Butera et al, Deciphering the significance of p53 mutant proteins, Trends in Cell Biology (2024). DOI: 10.1016/j.tcb.2024.06.003

Provided by University of Konstanz