The many faces of a tumor suppressor protein

Human cells divide many times during a lifetime, a process that requires careful regulation to avoid uncontrolled cell division, which can lead to various disorders, including cancer. For example, TP53, which encodes multiple proteins, is the most commonly mutated gene in cancers.

TP53 carries the instructions to make a tumor suppressor protein, known as p53, which can stop cancers from forming and spreading. In humans and mice, TP53 (and the mouse analogue Trp53) can also be read by the cell to make several slightly different versions of the p53 protein, known as isoforms. The p53 isoforms are much less studied and their role in an organism is still unclear.

To address this, Fajac et al. used genome editing to make mouse strains that were still able to express p53, but were only able to create a specific subset of p53 isoforms. In these mice, part of the Trp53 gene had been mutated to remove the cell’s ability to make isoforms with an alternative C-terminal end.

Fajac et al. then allowed these mice to breed with mice that were model organisms for a cancer called B-cell lymphoma. This revealed that male offspring that lacked alternative p53 isoforms were more susceptible to B-cell lymphoma and that they had decreased levels of the protein ACKR4, a receptor for signaling proteins that regulate cellular movement. Human datasets showed that having higher levels of ACKR4 could be linked to a better disease prognosis in male patients with Burkitt lymphoma, a rare but aggressive form of B-cell lymphoma. The same effect was not observed in females, suggesting that measuring ACKR4 gene expression in male patients with Burkitt lymphoma might be useful to identify the patients at higher risk.

The study from Fajac et al. provides a new perspective on p53 – one of the most studied proteins. It highlights specific p53 isoforms and the ACKR4 protein as a potential way to identify male patients at higher risk from a type of B-cell lymphoma.