Blood metabolites, neurocognition and psychiatric disorders: a Mendelian randomization analysis to investigate causal pathways

IF 5.8 1区医学 Q1 PSYCHIATRY

Translational Psychiatry Pub Date : 2024-09-16 DOI:10.1038/s41398-024-03095-4

Jing Guo, Ping Yang, Jia-Hao Wang, Shi-Hao Tang, Ji-Zhou Han, Shi Yao, Ke Yu, Cong-Cong Liu, Shan-Shan Dong, Kun Zhang, Yuan-Yuan Duan, Tie-Lin Yang, Yan Guo

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Abstract

Background

Neurocognitive dysfunction is observationally associated with the risk of psychiatric disorders. Blood metabolites, which are readily accessible, may become highly promising biomarkers for brain disorders. However, the causal role of blood metabolites in neurocognitive function, and the biological pathways underlying their association with psychiatric disorders remain unclear.

Methods

To explore their putative causalities, we conducted bidirectional two-sample Mendelian randomization (MR) using genetic variants associated with 317 human blood metabolites (n_max = 215,551), g-Factor (an integrated index of multiple neurocognitive tests with n_max = 332,050), and 10 different psychiatric disorders (n = 9,725 to 807,553) from the large-scale genome-wide association studies of European ancestry. Mediation analysis was used to assess the potential causal pathway among the candidate metabolite, neurocognitive trait and corresponding psychiatric disorder.

Results

MR evidence indicated that genetically predicted acetylornithine was positively associated with g-Factor (0.035 standard deviation units increase in g-Factor per one standard deviation increase in acetylornithine level; 95% confidence interval, 0.021 to 0.049; P = 1.15 × 10⁻⁶). Genetically predicted butyrylcarnitine was negatively associated with g-Factor (0.028 standard deviation units decrease in g-Factor per one standard deviation increase in genetically proxied butyrylcarnitine; 95% confidence interval, −0.041 to −0.015; P = 1.31 × 10⁻⁵). There was no evidence of associations between genetically proxied g-Factor and metabolites. Furthermore, the mediation analysis via two-step MR revealed that the causal pathway from acetylornithine to bipolar disorder was partly mediated by g-Factor, with a mediated proportion of 37.1%. Besides, g-Factor mediated the causal pathway from butyrylcarnitine to schizophrenia, with a mediated proportion of 37.5%. Other neurocognitive traits from different sources provided consistent findings.

Conclusion

Our results provide genetic evidence that acetylornithine protects against bipolar disorder through neurocognitive abilities, while butyrylcarnitine has an adverse effect on schizophrenia through neurocognition. These findings may provide insight into interventions at the metabolic level for risk of neurocognitive and related disorders.

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血液代谢物、神经认知和精神障碍：研究因果关系的孟德尔随机分析法

背景据观察，神经认知功能障碍与精神疾病的风险有关。血液代谢物很容易获得，可能成为极有希望的脑部疾病生物标志物。然而，血液代谢物在神经认知功能中的因果作用及其与精神疾病相关的生物学途径仍不清楚。方法为了探索它们的推定因果关系，我们使用与 317 种人类血液代谢物（nmax = 215,551 个）、g-因子（多种神经认知测试的综合指数，nmax = 332,050 个）和 10 种不同精神疾病（n = 9,725 至 807,553 个）相关的遗传变异进行了双向双样本孟德尔随机化（MR），这些遗传变异来自欧洲血统的大规模全基因组关联研究。结果MR证据表明，基因预测的乙酰鸟氨酸与g-因子呈正相关（乙酰鸟氨酸水平每增加一个标准差，g-因子增加0.035个标准差单位；95%置信区间为0.021至0.049；P = 1.15 × 10-6）。基因预测的丁酰肉碱与 g 因子呈负相关（基因代理丁酰肉碱每增加一个标准差，g 因子减少 0.028 个标准差单位；95% 置信区间，-0.041 至 -0.015；P = 1.31 × 10-5）。没有证据表明基因代g因子与代谢物之间存在关联。此外，通过两步MR的中介分析发现，乙酰鸟氨酸与双相情感障碍的因果关系部分由g-因子中介，中介比例为37.1%。此外，g-因子还介导了从丁酰肉碱到精神分裂症的因果关系，介导比例为 37.5%。结论我们的研究结果提供了遗传学证据，证明乙酰鸟氨酸可通过神经认知能力预防躁郁症，而丁酰肉碱则可通过神经认知能力对精神分裂症产生不利影响。这些发现可能有助于从代谢层面干预神经认知和相关疾病的风险。

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

Translational Psychiatry PSYCHIATRY-

CiteScore

11.50

自引率

2.90%

发文量

484

审稿时长

23 weeks

期刊介绍： Psychiatry has suffered tremendously by the limited translational pipeline. Nobel laureate Julius Axelrod''s discovery in 1961 of monoamine reuptake by pre-synaptic neurons still forms the basis of contemporary antidepressant treatment. There is a grievous gap between the explosion of knowledge in neuroscience and conceptually novel treatments for our patients. Translational Psychiatry bridges this gap by fostering and highlighting the pathway from discovery to clinical applications, healthcare and global health. We view translation broadly as the full spectrum of work that marks the pathway from discovery to global health, inclusive. The steps of translation that are within the scope of Translational Psychiatry include (i) fundamental discovery, (ii) bench to bedside, (iii) bedside to clinical applications (clinical trials), (iv) translation to policy and health care guidelines, (v) assessment of health policy and usage, and (vi) global health. All areas of medical research, including — but not restricted to — molecular biology, genetics, pharmacology, imaging and epidemiology are welcome as they contribute to enhance the field of translational psychiatry.