Lima Leandro Ceotto Freitas, Saliba Soraya Wilke, Andrade João Marcus Oliveira, Cunha Maria Luisa, Cassini-Vieira Puebla, Feltenberger John David, Barcelos Lucíola Silva, Guimarães André Luiz Sena, de-Paula Alfredo Mauricio Batista, de Oliveira Antônio Carlos Pinheiro, Santos Sérgio Henrique Sousa
Institute of Agricultural Sciences. Food Engineering College, Universidade Federal de Minas Gerais (UFMG), Montes Claros, Minas Gerais, Brazil.
Department of Pharmacology and Department of Physiology - ICB, Universidade Federal de Minas Gerais (UFMG), Avenida Antonio Carlos, 6627, 31270-901, Belo Horizonte, MG, Brazil.
Mol Neurobiol. 2017 Jul;54(5):3465-3475. doi: 10.1007/s12035-016-9927-x. Epub 2016 May 16.
Different factors may contribute to the development of neurodegenerative diseases. Among them, metabolic syndrome (MS), which has reached epidemic proportions, has emerged as a potential element that may be involved in neurodegeneration. Furthermore, studies have shown the importance of the sirtuin family in neuronal survival and MS, which opens the possibility of new pharmacological targets. This study investigates the influence of sirtuin metabolic pathways by examining the functional capacities of glucose-induced obesity in an excitotoxic state induced by a quinolinic acid (QA) animal model. Mice were divided into two groups that received different diets for 8 weeks: one group received a regular diet, and the other group received a high-fat diet (HF) to induce MS. The animals were submitted to a stereotaxic surgery and subdivided into four groups: Standard (ST), Standard-QA (ST-QA), HF and HF-QA. The QA groups were given a 250 nL quinolinic acid injection in the right striatum and PBS was injected in the other groups. Obese mice presented with a weight gain of 40 % more than the ST group beyond acquiring an insulin resistance. QA induced motor impairment and neurodegeneration in both ST-QA and HF-QA, although no difference was observed between these groups. The HF-QA group showed a reduction in adiposity when compared with the groups that received PBS. Therefore, the HF-QA group demonstrated a commitment-dependent metabolic pathway. The results suggest that an obesogenic diet does not aggravate the neurodegeneration induced by QA. However, the excitotoxicity induced by QA promotes a sirtuin pathway impairment that contributes to metabolic changes.
不同因素可能导致神经退行性疾病的发生。其中,已呈流行态势的代谢综合征(MS)已成为可能参与神经退行性变的一个潜在因素。此外,研究表明沉默调节蛋白家族在神经元存活和MS中具有重要作用,这为新的药理学靶点开辟了可能性。本研究通过检测喹啉酸(QA)动物模型在兴奋性毒性状态下葡萄糖诱导肥胖的功能能力,来研究沉默调节蛋白代谢途径的影响。将小鼠分为两组,给予不同饮食8周:一组给予常规饮食,另一组给予高脂饮食(HF)以诱导MS。对动物进行立体定向手术,并分为四组:标准组(ST)、标准-QA组(ST-QA)、HF组和HF-QA组。QA组在右侧纹状体注射250 nL喹啉酸,其他组注射磷酸盐缓冲液(PBS)。肥胖小鼠除了出现胰岛素抵抗外,体重比ST组增加了40%。QA在ST-QA组和HF-QA组均诱导了运动障碍和神经退行性变,尽管两组之间未观察到差异。与接受PBS注射的组相比,HF-QA组的肥胖程度有所降低。因此,HF-QA组表现出一种依赖于肥胖状态的代谢途径。结果表明,致肥胖饮食不会加重QA诱导的神经退行性变。然而,QA诱导的兴奋性毒性促进了沉默调节蛋白途径的损伤,这导致了代谢变化。
