• Profile
Close

The architectural role of p53: Early 3D chromatin remodeling to trigger cellular stress response

MedicalXpress Breaking News-and-Events Apr 09, 2024

The simplest explanation of cancer is that, for any reason, a cell in our body ignores its biological program and gets loose, multiplying itself again and again, creating a tumor. This has a lot to do with the wrong use of its genetic information, contained within its genes. Cells are smart enough to see this coming and try to activate an emergency response, usually through specific genes called tumor suppressors. The best-known of these is TP53 (producing the protein p53), discovered more than 40 years ago.

Scientists certainly know a lot about p53. It starts a broad cascade of events inside the cell, involving the activation of hundreds of other genes, that will collectively try to control damage or, as a last resort, kill the cell for the benefit of the organism. However, the direct effects of p53 right after its activation remained poorly understood and this is of utmost importance, since abnormal inactivation of p53 is a known hallmark of cancer progression.

The researchers, led by Dr. Biola M. Javierre, developed an experimental setting able to detect the fast changes occurring as short as one hour after p53 activation and found it produced a heavy remodeling of the chromatin—the DNA inside the nucleus- consistent with the activation of its targets.

The results were published in Nature Communications and involved colleagues from the Graupera and the Sardina labs, also at the Josep Carreras Leukemia Research Institute, as well as researchers from the Barcelona Supercomputing Center, the University College London and the Florida State University.

Overall, the study identified 340 p53 target genes being directly activated through long-range interactions, involving the contact of specific activation regions in the genome—enhancers—with the genes themselves. That's why chromatin had to be physically reorganized within the nucleus. Noteworthy, 70% of the genes had not been previously linked with p53.

The team also proved that the rewiring of the chromatin was dependent on the presence of the cohesin complex, a known group of proteins in charge of stabilizing DNA loops, precisely the ones allowing the long-range interactions between enhancers and genes, strengthening their findings.

Despite being a key player in cancer suppression, very few therapeutic strategies have been directed towards restoring p53 function in tumors where it is inactivated, either directly or through its secondary targets. Perhaps, its newly reported mechanism of early action and the identification of many more genes under its control can inspire new clinical approaches in the future.

Go to Original
Only Doctors with an M3 India account can read this article. Sign up for free or login with your existing account.
4 reasons why Doctors love M3 India
  • Exclusive Write-ups & Webinars by KOLs

  • Nonloggedininfinity icon
    Daily Quiz by specialty
  • Nonloggedinlock icon
    Paid Market Research Surveys
  • Case discussions, News & Journals' summaries
Sign-up / Log In
x
M3 app logo
Choose easy access to M3 India from your mobile!


M3 instruc arrow
Add M3 India to your Home screen
Tap  Chrome menu  and select "Add to Home screen" to pin the M3 India App to your Home screen
Okay