Part-time cancers and role of melatonin in determining their metabolic phenotype.
Study Goal
The researchers aimed to explore the association between melatonin and the metabolic behavior of solid tumors, particularly breast cancer, and its potential mechanisms in altering cancer cell metabolism.
Results Summary
The study suggests that melatonin may shift tumor metabolism from Warburg-type to oxidative phosphorylation at night, reducing tumor aggressiveness and proliferation. It also proposes that melatonin could enhance conventional chemotherapy outcomes when used concurrently.
Population
Solid tumors, particularly breast cancer (no specific human or animal population detailed).
Effective Dosage
Not specified
Duration
Not specified
Interactions
None mentioned
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
endogenously-produced melatonin | neutral | metabolic phenotype of cancer cells | solid tumors, particularly breast cancer | - | impacts | #1 |
exogenously-administered melatonin | neutral | metabolic phenotype of cancer cells | solid tumors, particularly breast cancer | - | impacts | #2 |
nocturnal rise in melatonin | increase | solid tumors to redirect their metabolic phenotype from Warburg-type metabolism to mitochondrial oxidative phosphorylation | solid tumors | - | causes | #3 |
switch to oxidative phosphorylation at night | decrease | cancer cells to exhibit a reduced tumor phenotype | cancer cells | - | causes | #4 |
switch to oxidative phosphorylation at night | decrease | cancer cells less likely to rapidly proliferate | cancer cells | - | makes | #5 |
switch to oxidative phosphorylation at night | decrease | cancer cells less likely to become invasive or metastatic | cancer cells | - | makes | #6 |
nocturnal rise in melatonin | decrease | some solid tumors especially aggressive during the day and much less so at night | some solid tumors | - | makes | #7 |
melatonin | increase | cancer treatment outcomes | - | - | would improve | #8 |
This brief review describes the association of the endogenous pineal melatonin rhythm with the metabolic flux of solid tumors, particularly breast cancer. It also summarizes new information on the potential mechanisms by which endogenously-produced or exogenously-administered melatonin impacts the metabolic phenotype of cancer cells. The evidence indicates that solid tumors may redirect their metabolic phenotype from the pathological Warburg-type metabolism during the day to the healthier mitochondrial oxidative phosphorylation on a nightly basis. Thus, they function as cancer cells only during the day and as healthier cells at night, that is, they are only part-time cancerous. This switch to oxidative phosphorylation at night causes cancer cells to exhibit a reduced tumor phenotype and less likely to rapidly proliferate or to become invasive or metastatic. Also discussed is the likelihood that some solid tumors are especially aggressive during the day and much less so at night due to the nocturnal rise in melatonin which determines their metabolic state. We further propose that when melatonin is used/tested in clinical trials, a specific treatment paradigm be used that is consistent with the temporal metabolic changes in tumor metabolism. Finally, it seems likely that the concurrent use of melatonin in combination with conventional chemotherapies also would improve cancer treatment outcomes.