AI Article Synopsis
- Obesity is increasingly recognized as a global health issue, and high-fat intake may lead to increased levels of free fatty acids, impacting neuroendocrine functions related to obesity.
- Researchers examined the effects of oleic acid on hypothalamic monoamines, proposing that it activates PPAR-α, a key factor in fatty acid metabolism, and that this effect would be diminished in rats with diet-induced obesity (DIO).
- The study found that oleic acid significantly raised levels of norepinephrine, dopamine, and serotonin in a dose-dependent manner, but this response was reduced in DIO rats, indicating the importance of PPARα in the hypothalamus's response to fatty acids.
Article Abstract
Obesity continues to be a growing health concern around the world, and elevated levels of free fatty acids as a result of high-fat intake might play a role in neuroendocrine alterations leading to obesity. However, it is unclear how fatty acids affect neuroendocrine functions and energy metabolism. Since hypothalamic monoamines play a crucial role in regulating neuroendocrine functions relating to energy balance, we investigated the direct effects of oleic acid on hypothalamic monoamines and hypothesized that oleic acid would activate peroxisome proliferator-activated receptor alpha (PPAR-α), a nuclear transcription factor involved with fatty acid metabolism, to affect monoamines. We also hypothesized that this response would be subdued in diet-induced obesity (DIO). To test these hypotheses, hypothalami from Sprague Dawley and DIO rats were incubated with 0 (Control), 0.00132 mM, 0.132 mM, 1.32 mM oleic acid, 50 μM MK 886 (a selective PPAR- α antagonist), or oleic acid + MK 886 in Krebs Ringers Henseleit (KRH) solution. HPLC-EC was used to measure monoamine levels in perfusates. Oleic acid produced a significant increase in norepinephrine, dopamine, and serotonin levels in a dose-dependent manner, and incubation with MK886 blocked these effects. The effect of oleic acid on hypothalamic monoamines was attenuated in DIO rats. These findings suggest that PPARα probably plays an essential role in fatty acid sensing in the hypothalamus, by affecting monoamine efflux and DIO rats are resistant to the effects of oleic acid.
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| http://dx.doi.org/10.1016/j.lfs.2020.117867 | DOI Listing |
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