Ikon Nikita, Ryan Robert O
Children's Hospital Oakland Research Institute, 5700 Martin Luther King Jr. Way, Oakland, CA, 94609, USA.
Lipids. 2017 Feb;52(2):99-108. doi: 10.1007/s11745-016-4229-7. Epub 2017 Jan 9.
The Barth syndrome (BTHS) is caused by an inborn error of metabolism that manifests characteristic phenotypic features including altered mitochondrial membrane phospholipids, lactic acidosis, organic acid-uria, skeletal muscle weakness and cardiomyopathy. The underlying cause of BTHS has been definitively traced to mutations in the tafazzin (TAZ) gene locus on chromosome X. TAZ encodes a phospholipid transacylase that promotes cardiolipin acyl chain remodeling. Absence of tafazzin activity results in cardiolipin molecular species heterogeneity, increased levels of monolysocardiolipin and lower cardiolipin abundance. In skeletal muscle and cardiac tissue mitochondria these alterations in cardiolipin perturb the inner membrane, compromising electron transport chain function and aerobic respiration. Decreased electron flow from fuel metabolism via NADH ubiquinone oxidoreductase activity leads to a buildup of NADH in the matrix space and product inhibition of key TCA cycle enzymes. As TCA cycle activity slows pyruvate generated by glycolysis is diverted to lactic acid. In turn, Cori cycle activity increases to supply muscle with glucose for continued ATP production. Acetyl CoA that is unable to enter the TCA cycle is diverted to organic acid waste products that are excreted in urine. Overall, reduced ATP production efficiency in BTHS is exacerbated under conditions of increased energy demand. Prolonged deficiency in ATP production capacity underlies cell and tissue pathology that ultimately is manifest as dilated cardiomyopathy.
巴氏综合征(BTHS)由一种先天性代谢缺陷引起,表现出特征性的表型特征,包括线粒体膜磷脂改变、乳酸性酸中毒、有机酸尿症、骨骼肌无力和心肌病。BTHS的根本原因已明确追溯到X染色体上tafazzin(TAZ)基因座的突变。TAZ编码一种促进心磷脂酰基链重塑的磷脂转酰基酶。tafazzin活性的缺失导致心磷脂分子种类的异质性、单赖氨酸心磷脂水平的增加和心磷脂丰度的降低。在骨骼肌和心脏组织的线粒体中,这些心磷脂的改变扰乱了内膜,损害了电子传递链功能和有氧呼吸。通过NADH泛醌氧化还原酶活性,燃料代谢产生的电子流减少,导致基质空间中NADH的积累和关键三羧酸循环酶的产物抑制。由于三羧酸循环活性减慢,糖酵解产生的丙酮酸被转化为乳酸。反过来,科里循环活性增加,为肌肉提供葡萄糖以持续产生ATP。无法进入三羧酸循环的乙酰辅酶A被转化为有机酸废物,随尿液排出。总体而言,在能量需求增加的情况下,BTHS中ATP产生效率的降低会加剧。ATP产生能力的长期缺乏是细胞和组织病理的基础,最终表现为扩张型心肌病。