Blockage of melatonin receptors impairs p53-mediated prevention of DNA damage accumulation.
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
melatonin | increase | p38-dependent phosphorylation of both p53 and histone H2AX | - | - | induces | #1 |
melatonin | increase | repair of both endogenous and chemotherapy-induced DNA damage | - | - | associated with a p53-mediated increase in repair of both endogenous and chemotherapy-induced DNA damage | #2 |
melatonin | decrease | p53-dependent DNA damage response and genome integrity | - | - | impairs melatonin's capability to induce a p53-dependent DNA damage response and thus its ability to maintain genome integrity | #3 |
melatonin | increase | p53-dependent DNA damage response | - | - | activation of the p53-dependent DNA damage response by melatonin is indeed mediated by MT1 and MT2 | #4 |
melatonin | decrease | cell proliferation and clonogenic potential of cancer cells | cancer cells | - | impairs melatonin's ability to reduce both cell proliferation and clonogenic potential of cancer cells | #5 |
melatonin | decrease | p53-dependent DNA damage response | - | - | causes an impairment of the p53-dependent DNA damage response | #6 |
Melatonin has been known to be a chemopreventive agent since its levels inversely correlate with the risk of developing cancer. We have recently shown that melatonin induces p38-dependent phosphorylation of both p53 and histone H2AX. This is associated with a p53-mediated increase in repair of both endogenous and chemotherapy-induced DNA damage. In addition, the inhibition of p38 activities impairs melatonin's capability to induce a p53-dependent DNA damage response and thus its ability to maintain genome integrity. Since melatonin-induced p53 phosphorylation requires an intact p38 phosphorylation cascade and p38 can be activated by G proteins, we supposed that melatonin's activities could be mediated by its G-protein-coupled membrane receptors, MT1 and MT2. Here, we show that the activation of the p53-dependent DNA damage response by melatonin is indeed mediated by MT1 and MT2. As a result, the absence of either receptor impairs melatonin's ability to reduce both cell proliferation and clonogenic potential of cancer cells. In addition, this causes an impairment of the p53-dependent DNA damage response. By providing molecular insight, our findings might have translational impact, suggesting the involvement of melatonin receptors in tumorigenesis.