Abstract
The "guardian of the genome," TP53, is one of the most frequently mutated genes of all cancers. Despite the important biological roles of TP53, the clinical relevance of TP53 mutations, in gastric cancer (GC), remains largely unknown. Here, we systematically assessed clinical relevance, in terms of TP53 mutation positions, finding substantial variability. Thus, we hypothesized that the position of the TP53 mutation might affect clinical outcomes in GC. We systematically inspected missense mutations in TP53, from a TCGA (The Cancer Genome Atlas) GC dataset in UCSC Xena repository. Specifically, we examined five aspects of each mutational position: (1) the whole gene body; (2) known hot-spots; (3) the DNA-binding domain; (4) the secondary structure of the domain; and (5) individual mutation positions. We then analyzed the clinical outcomes for each aspect. These results showed that, in terms of secondary structure, patients with mutations in turn regions showed poor prognosis, compared to those with mutations in beta strand regions (log rank ${\text{p}}= {{0.043}}$p=0.043). Also, in terms of individual mutation positions, patients having mutations at R248 showed poorer survival than other patients having mutations at different TP53 positions (log rank ${\text{p}}= {{0.035}}$p=0.035).
Highlights
THE gene encoding the tumor suppressor TP53, dubbed the “guardian of the genome,” is the most frequently ð > 50 percentÞ mutated gene across all cancers [1]
Based on the previous TP53 studies described above, we hypothesized that TP53 mutational location might affect clinical outcomes, in gastric cancer (GC), via unique mechanisms
Since we had assigned the 80 mutations into either TP53 known hot spot, or non-hot spot, groups (Fig. 2b), we examined possible clinical differences between the two groups. 32 of the 80 GC tumors were assigned to known hot spot (R175, G245, R248, R273, and R282) [9], and 48 to non-hot spot, groups
Summary
THE gene encoding the tumor suppressor TP53, dubbed the “guardian of the genome,” is the most frequently ð > 50 percentÞ mutated gene across all cancers [1]. The extent of TP53 mutation, in specific tumors, varies widely. A previous study of the “mutational landscape,” of 12 distinct tumor types, found 20 biologic processes to be significantly dysregulated. In one such process, “genome integrity,” TP53 mutation rates ranged from 2.2 percent to 94.9 percent, in renal cell and serous ovarian cancers, respectively [2]. TP53 is widely known as the prevailing arbitrator of DNA repair and apoptosis, one study found that its role in DNA repair, in mice, was unrelated to tumor suppression. Activation by the small protein, ARF, in response to oncogenic signaling, resulted in TP53’s
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