早期肥厚型心肌病的脂质和能量代谢的等位基因特异性失调

Arpana Vaniya , Anja Karlstaedt , Damla Gulkok , Tilo Thottakara , Yamin Liu , Sili Fan , Hannah Eades , Styliani Vakrou , Ryuya Fukunaga , Hilary J. Vernon , Oliver Fiehn , M. Roselle Abraham
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引用次数: 0

摘要

导言肥厚性心肌病(HCM)是由肉瘤蛋白基因的致病变异引起的,这种变异会增加心肌细胞的能量需求并导致心脏肥大。然而,在疾病的早期阶段,是否有一种共同的代谢特征是心脏表型的基础还不得而知。为了解决这个问题并确定早期 HCM 的心脏生化病理,我们研究了两种 HCM 小鼠模型,它们表达心肌肌钙蛋白 T(Tnt2)或肌球蛋白重链(Myh6)基因的致病变异,在疾病早期的心脏成像表型和线粒体功能方面存在明显差异。方法我们结合使用了超声心动图、转录组学、基于质谱的非靶向代谢组学(GC-TOF、HILIC、CSH-QTOF)和计算模型(CardioNet),研究了 R92W-TnT+/- 和 R403Q-MyHC+/- 突变小鼠在疾病早期(5 周龄)的心脏结构和代谢重塑。结果在疾病早期阶段,观察到心脏表型、基因表达和代谢物方面的等位基因特异性差异。TnT突变体的左心室舒张功能障碍非常突出。TnT突变体心脏中差异表达的基因主要富集在克雷布斯循环、呼吸电子传递和支链氨基酸代谢中,而MyHC突变体则富集在线粒体生物生成、钙稳态和肝X受体信号转导中。两种突变体心脏的嘌呤核苷、三糖、二羧酸、酰基肉碱、磷脂酰乙醇胺、磷脂酰肌醇、神经酰胺和甘油三酯的水平都发生了显著变化;TnT突变体中40.4%的脂质和24.7%的代谢物存在显著差异,而MyHC突变体中10.4%的脂质和5.8%的代谢物存在显著差异。两种突变体心脏的不饱和长链酰基肉碱(18:1、18:2、20:1)丰度都较低,但只有TnT突变体的神经酰胺和心磷脂物种中富含FA18:0。结论我们的系统生物学方法揭示了 R92W-TnT 和 R403Q-MyHC 突变体心脏代谢重塑的显著差异,在疾病早期阶段,TnT 突变体比 MyHC 突变体表现出更大的失调。TnT突变体心磷脂组成的变化可能会导致本研究中观察到的能量代谢障碍和舒张功能障碍,并在运动等高负荷工作时易导致能量应激和室性心律失常。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Allele-specific dysregulation of lipid and energy metabolism in early-stage hypertrophic cardiomyopathy

Allele-specific dysregulation of lipid and energy metabolism in early-stage hypertrophic cardiomyopathy

Introduction

Hypertrophic cardiomyopathy (HCM) results from pathogenic variants in sarcomeric protein genes that increase myocyte energy demand and lead to cardiac hypertrophy. However, it is unknown whether a common metabolic trait underlies cardiac phenotype at the early disease stage. To address this question and define cardiac biochemical pathology in early-stage HCM, we studied two HCM mouse models that express pathogenic variants in cardiac troponin T (Tnt2) or myosin heavy chain (Myh6) genes, and have marked differences in cardiac imaging phenotype, mitochondrial function at early disease stage.

Methods

We used a combination of echocardiography, transcriptomics, mass spectrometry-based untargeted metabolomics (GC-TOF, HILIC, CSH-QTOF), and computational modeling (CardioNet) to examine cardiac structural and metabolic remodeling at early disease stage (5 weeks of age) in R92W-TnT+/− and R403Q-MyHC+/− mutant mice. Data from mutants was compared with respective littermate controls (WT).

Results

Allele-specific differences in cardiac phenotype, gene expression and metabolites were observed at early disease stage. LV diastolic dysfunction was prominent in TnT mutants. Differentially-expressed genes in TnT mutant hearts were predominantly enriched in the Krebs cycle, respiratory electron transport, and branched-chain amino acid metabolism, whereas MyHC mutants were enriched in mitochondrial biogenesis, calcium homeostasis, and liver-X-receptor signaling. Both mutant hearts demonstrated significant alterations in levels of purine nucleosides, trisaccharides, dicarboxylic acids, acylcarnitines, phosphatidylethanolamines, phosphatidylinositols, ceramides and triglycerides; 40.4 % of lipids and 24.7 % of metabolites were significantly different in TnT mutants, whereas 10.4 % of lipids and 5.8 % of metabolites were significantly different in MyHC mutants. Both mutant hearts had a lower abundance of unsaturated long-chain acyl-carnitines (18:1, 18:2, 20:1), but only TnT mutants showed enrichment of FA18:0 in ceramide and cardiolipin species. CardioNet predicted impaired energy substrate metabolism and greater phospholipid remodeling in TnT mutants than in MyHC mutants.

Conclusions

Our systems biology approach revealed marked differences in metabolic remodeling in R92W-TnT and R403Q-MyHC mutant hearts, with TnT mutants showing greater derangements than MyHC mutants, at early disease stage. Changes in cardiolipin composition in TnT mutants could contribute to impairment of energy metabolism and diastolic dysfunction observed in this study, and predispose to energetic stress, ventricular arrhythmias under high workloads such as exercise.

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Journal of molecular and cellular cardiology plus
Journal of molecular and cellular cardiology plus Cardiology and Cardiovascular Medicine
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