Department of Clinical Genetics, VU University Medical Centre, Amsterdam, the Netherlands.
Institute of Biological Sciences, Faculty of Science, University of Malaya, Kuala Lumpur, Malaysia.
PLoS One. 2018 Sep 12;13(9):e0203687. doi: 10.1371/journal.pone.0203687. eCollection 2018.
Parkinson's disease is a widespread neurodegenerative disorder which affects brain metabolism. Although changes in gene expression during disease are often measured, it is difficult to predict metabolic fluxes from gene expression data. Here we explore the hypothesis that changes in gene expression for enzymes tend to parallel flux changes in biochemical reaction pathways in the brain metabolic network. This hypothesis is the basis of a computational method to predict metabolic flux changes from post-mortem gene expression measurements in Parkinson's disease (PD) brain.
We use a network model of central metabolism and optimize the correspondence between relative changes in fluxes and in gene expression. To this end we apply the Least-squares with Equalities and Inequalities algorithm integrated with Flux Balance Analysis (Lsei-FBA). We predict for PD (1) decreases in glycolytic rate and oxygen consumption and an increase in lactate production in brain cortex that correspond with measurements (2) relative flux decreases in ATP synthesis, in the malate-aspartate shuttle and midway in the TCA cycle that are substantially larger than relative changes in glucose uptake in the substantia nigra, dopaminergic neurons and most other brain regions (3) shifts in redox shuttles between cytosol and mitochondria (4) in contrast to Alzheimer's disease: little activation of the gamma-aminobutyric acid shunt pathway in compensation for decreased alpha-ketoglutarate dehydrogenase activity (5) in the globus pallidus internus, metabolic fluxes are increased, reflecting increased functional activity.
Our method predicts metabolic changes from gene expression data that correspond in direction and order of magnitude with presently available experimental observations during Parkinson's disease, indicating that the hypothesis may be useful for some biochemical pathways. Lsei-FBA generates predictions of flux distributions in neurons and small brain regions for which accurate metabolic flux measurements are not yet possible.
帕金森病是一种广泛存在的神经退行性疾病,影响大脑代谢。尽管疾病过程中基因表达的变化经常被测量,但从基因表达数据预测代谢通量是很困难的。在这里,我们探索了这样一种假设,即酶的基因表达变化往往与大脑代谢网络中生化反应途径的通量变化平行。这一假设是一种从帕金森病(PD)大脑死后基因表达测量中预测代谢通量变化的计算方法的基础。
我们使用中央代谢网络模型,并优化通量和基因表达相对变化之间的对应关系。为此,我们应用了最小二乘法与等式和不等式(Lsei-FBA)算法。我们预测 PD 患者(1)大脑皮层糖酵解率和耗氧量降低,乳酸生成增加,与测量结果(2)ATP 合成、苹果酸-天冬氨酸穿梭和三羧酸循环中途相对通量降低相一致,这些降低幅度远大于黑质、多巴胺神经元和大多数其他脑区葡萄糖摄取的相对变化;(3)还原穿梭在细胞质和线粒体之间的转移;(4)与阿尔茨海默病相反:γ-氨基丁酸穿梭途径的激活程度很小,以补偿α-酮戊二酸脱氢酶活性的降低;(5)在苍白球 internus 中,代谢通量增加,反映出功能活动增加。
我们的方法从基因表达数据预测代谢变化,这些变化在方向和数量级上与目前帕金森病期间现有的实验观察结果相对应,表明该假设对于某些生化途径可能是有用的。Lsei-FBA 生成了神经元和小脑区的通量分布预测,目前尚无法对这些神经元和小脑区进行准确的代谢通量测量。
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