Vargason Troy, Kruger Uwe, Roth Emily, Delhey Leanna M, Tippett Marie, Rose Shannon, Bennuri Sirish C, Slattery John C, Melnyk Stepan, James S Jill, Frye Richard E, Hahn Juergen
Department of Biomedical Engineering, Rensselaer Polytechnic Institute, Troy, NY, United States.
Center for Biotechnology and Interdisciplinary Studies, Rensselaer Polytechnic Institute, Troy, NY, United States.
Front Cell Neurosci. 2018 Dec 19;12:503. doi: 10.3389/fncel.2018.00503. eCollection 2018.
Several studies associate autism spectrum disorder (ASD) pathophysiology with metabolic abnormalities related to DNA methylation and intracellular redox homeostasis. In this regard, three completed clinical trials are reexamined in this work: treatment with (i) methylcobalamin (MeCbl) in combination with low-dose folinic acid (LDFA), (ii) tetrahydrobiopterin, and (iii) high-dose folinic acid (HDFA) for counteracting abnormalities in the folate-dependent one-carbon metabolism (FOCM) and transsulfuration (TS) pathways and also for improving ASD-related symptoms and behaviors. Although effects of treatment on individual metabolites and behavioral measures have previously been investigated, this study is the first to consider the effect of interventions on a set of metabolites of the FOCM/TS pathways and to correlate FOCM/TS metabolic changes with behavioral improvements across several studies. To do so, this work uses data from one case-control study and the three clinical trials to develop multivariate models for considering these aspects of treatment. Fisher discriminant analysis (FDA) is first used to establish a model for distinguishing individuals with ASD from typically developing (TD) controls, which is subsequently evaluated on the three treatment data sets, along with one data set for a placebo, to characterize the shift of FOCM/TS metabolism toward that of the TD population. Treatment with MeCbl plus LDFA and, separately, treatment with tetrahydrobiopterin significantly shifted the metabolites toward the values of the control group. Contrary to this, treatment with HDFA had a lesser, though still noticeable, effect whilst the placebo group showed marginal, but not insignificant, variations in metabolites. A second analysis is then performed with non-linear kernel partial least squares (KPLS) regression to predict changes in adaptive behavior, quantified by the Vineland Adaptive Behavior Composite, from changes in FOCM/TS biochemical measurements provided by treatment. Incorporating the 74 samples receiving any treatment, including placebo, into the regression analysis yields an of 0.471 after cross-validation when using changes in six metabolic measurements as predictors. These results are suggestive of an ability to effectively improve pathway-wide FOCM/TS metabolic and behavioral abnormalities in ASD with clinical treatment.
多项研究将自闭症谱系障碍(ASD)的病理生理学与DNA甲基化及细胞内氧化还原稳态相关的代谢异常联系起来。在这方面,本文重新审视了三项已完成的临床试验:使用(i)甲钴胺(MeCbl)联合低剂量亚叶酸(LDFA)、(ii)四氢生物蝶呤、(iii)高剂量亚叶酸(HDFA)进行治疗,以对抗叶酸依赖性一碳代谢(FOCM)和转硫途径(TS)中的异常情况,并改善与ASD相关的症状和行为。尽管之前已经研究了治疗对个体代谢物和行为指标的影响,但本研究是首次考虑干预措施对FOCM/TS途径中一组代谢物的影响,并在多项研究中将FOCM/TS代谢变化与行为改善相关联。为此,本文利用一项病例对照研究和三项临床试验的数据,建立多变量模型来考量治疗的这些方面。首先使用费希尔判别分析(FDA)建立一个区分ASD个体与正常发育(TD)对照的模型,随后在三个治疗数据集以及一个安慰剂数据集上对该模型进行评估,以表征FOCM/TS代谢向TD人群代谢的转变。使用MeCbl加LDFA治疗以及单独使用四氢生物蝶呤治疗均使代谢物显著向对照组的值转变。与此相反,高剂量亚叶酸治疗的效果较小,尽管仍很明显,而安慰剂组的代谢物有微小但并非不显著的变化。然后进行第二项分析,使用非线性核偏最小二乘(KPLS)回归,根据治疗提供的FOCM/TS生化测量变化来预测由文兰适应性行为综合量表量化的适应性行为变化。将接受任何治疗(包括安慰剂)的74个样本纳入回归分析,当使用六个代谢测量的变化作为预测指标时,交叉验证后的 为0.471。这些结果表明,临床治疗能够有效改善ASD中全途径FOCM/TS代谢和行为异常。
