DHA (omega-3 fatty acid) and estradiol: key roles in regional cerebral glucose uptake

IF 1.8 Q2 AGRONOMY

OCL-Oilseeds and Fats Crops and Lipids Pub Date : 2023-01-01 DOI:10.1051/ocl/2023023

Didier Majou, Anne-Lise Dermenghem

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Abstract

Neurons have a high energy need, requiring a continuous supply of glucose from the blood. Tight regulation of glucose metabolism in response to stimuli is essential for brain physiology. Glucose metabolism and cerebral blood flow are closely coordinated during neuronal activity to maintain proper brain function. Glucose uptake across the blood - brain barrier is facilitated by a carrier protein: the GLUT-1 transporter. The first way the body meets urgent demand for glucose is to increase the blood flow through vasodilatory responses generated by nitric oxide. If that is insufficient, the second way is to increase the density of GLUT-1 through the translocation of this transporter from intracellular stores. The third pathway is to increase GLUT-1 synthesis by stimulating SLC2A1 (GLUT-1 gene) transcription. A tandem of two key molecules, free estradiol and DHA, is involved in this critical regulation. Their relationship is synergistic and reciprocal: free estradiol with genomic and non-genomic actions via ERα, and DHA via the PPARα-RXRα and PPARɣ-RXRα heterodimers. We highlight several original mechanisms linking two main principles (neuronal stimulation and brain energy metabolism) with the fundamental roles played by DHA and free estradiol. In particular, it has been shown that from a certain level of chronic DHA deficiency, a permanent imbalance sets in with disturbances in glucose intake and brain metabolism. This DHA deficiency is an aggravating factor in some neuropathologies.

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DHA (omega-3脂肪酸)和雌二醇:脑葡萄糖摄取的关键作用

神经元有很高的能量需求，需要从血液中持续供应葡萄糖。葡萄糖代谢对刺激的严格调节对脑生理至关重要。在神经元活动过程中，葡萄糖代谢和脑血流密切协调，以维持正常的脑功能。葡萄糖通过血脑屏障的摄取是由一种载体蛋白促进的:GLUT-1转运蛋白。身体满足葡萄糖紧急需求的第一种方式是通过一氧化氮产生的血管舒张反应来增加血流量。如果这还不够，第二种方法是通过细胞内储存转运体的易位来增加GLUT-1的密度。第三种途径是通过刺激SLC2A1 (GLUT-1基因)转录增加GLUT-1合成。两个关键分子的串联，游离雌二醇和DHA，参与了这个关键的调节。它们之间的关系是协同和互惠的:游离雌二醇通过ERα发挥基因组和非基因组作用，DHA通过PPARα-RXRα和PPARα-RXRα异源二聚体发挥作用。我们强调了将两个主要原理(神经元刺激和脑能代谢)与DHA和游离雌二醇所起的基本作用联系起来的几种原始机制。特别是，研究表明，从一定程度的慢性DHA缺乏开始，葡萄糖摄入和脑代谢紊乱就会导致永久性的不平衡。DHA缺乏是某些神经疾病的加重因素。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

OCL-Oilseeds and Fats Crops and Lipids AGRONOMY-

CiteScore

4.70

自引率

14.30%

发文量

审稿时长

10 weeks

期刊介绍： OCL-Oilseeds and fats, Crops and Lipids is a peer-reviewed full Open-Access scientific journal devoted to fats, lipids and oil- and protein-crops. OCL covers the entire sector. The research papers and reviews published address a range of topical matters in agronomy, plant biology, biochemistry, analytical chemistry, lipid chemistry, as well as transversal research themes such as nutrition, the health-quality-food safety nexus, innovation and industrial processes, the environment and sustainable development, economics and social development. A particular feature of OCL is the inclusion of special thematic sections focusing on a topical subject among the Journal''s core domains. Invited contributors to these thematic sections are chosen with care in order to ensure the expression of a genuine cross-section of interests and expertise.

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