The development of cancer after p53 inactivation is determined by a series of genomic changes that occur in four steps. The loss of heterozygosity of TP53 (the gene encoding p53 in humans, named Trp53 ...

The tumor suppressor protein p53 plays a critical role in preventing cancer by regulating cell cycle, apoptosis, and genomic stability. However, mutations in the P53 gene are found in over 50% of ...

A new hypothesis article was published in Oncotarget (Volume 17) on January 3, 2026, titled “Hypothesis: HPV E6 and COVID ...

The p53 gene plays an important role in cell biology as it regulates the cell cycle and halts the formation of tumors. While the gene was discovered more than four decades ago, researchers are still ...

Mutations in the tumor suppressor TP53 are a common cause of cancer, making the altered protein an attractive target for ...

In the 1970s, scientists knew that some viruses and chemicals caused cancer, but they didn’t know how. Arnold Levine, a biologist currently at the Institute for Advanced Study researched DNA viruses ...

Toxicologists have found that the protein p53 continuously protects our cells from tumorigenesis by coordinating important metabolic processes that stabilize their genomes. The gene coding for the ...

GMCL1-dependent degradation of 53BP1 suppresses mitotic surveillance, tuning p53 activation thresholds that govern cell fate decisions and cellular responses after mitosis.

Understanding how cancer develops is critical for designing effective, personalized cancer therapies. Researchers have known for years that cancer begins with mutations in certain types of genes. One ...