From the Department of Biological Sciences, Wayne State University, Detroit, Michigan 48202.
J Biol Chem. 2014 Feb 7;289(6):3114-25. doi: 10.1074/jbc.M113.529487. Epub 2013 Dec 8.
Cardiolipin (CL) that is synthesized de novo is deacylated to monolysocardiolipin (MLCL), which is reacylated by tafazzin. Remodeled CL contains mostly unsaturated fatty acids. In eukaryotes, loss of tafazzin leads to growth and respiration defects, and in humans, this results in the life-threatening disorder Barth syndrome. Tafazzin deficiency causes a decrease in the CL/MLCL ratio and decreased unsaturated CL species. Which of these biochemical outcomes contributes to the physiological defects is not known. Yeast cells have a single CL-specific phospholipase, Cld1, that can be exploited to distinguish between these outcomes. The cld1Δ mutant has decreased unsaturated CL, but the CL/MLCL ratio is similar to that of wild type cells. We show that cld1Δ rescues growth, life span, and respiratory defects of the taz1Δ mutant. This suggests that defective growth and respiration in tafazzin-deficient cells are caused by the decreased CL/MLCL ratio and not by a deficiency in unsaturated CL. CLD1 expression is increased during respiratory growth and regulated by the heme activator protein transcriptional activation complex. Overexpression of CLD1 leads to decreased mitochondrial respiration and growth and instability of mitochondrial DNA. However, ATP concentrations are maintained by increasing glycolysis. We conclude that transcriptional regulation of Cld1-mediated deacylation of CL influences energy metabolism by modulating the relative contribution of glycolysis and respiration.
心磷脂(CL)是从头合成的,然后去酰化为单心磷脂酰甘油(MLCL),再由 tafazzin 重新酰化。重塑后的 CL 主要含有不饱和脂肪酸。在真核生物中,tafazzin 的缺失会导致生长和呼吸缺陷,而在人类中,这会导致危及生命的 Barth 综合征。tafazzin 缺乏会导致 CL/MLCL 比值降低和不饱和 CL 种类减少。这些生化结果中哪一个导致了生理缺陷尚不清楚。酵母细胞只有一种 CL 特异性磷脂酶 Cld1,可以用来区分这些结果。cld1Δ 突变体的不饱和 CL 减少,但 CL/MLCL 比值与野生型细胞相似。我们表明 cld1Δ 可以挽救 taz1Δ 突变体的生长、寿命和呼吸缺陷。这表明 tafazzin 缺陷细胞的生长和呼吸缺陷是由 CL/MLCL 比值降低引起的,而不是不饱和 CL 的缺乏引起的。CLD1 的表达在呼吸生长过程中增加,并受血红素激活蛋白转录激活复合物的调节。CLD1 的过表达导致线粒体呼吸和生长减少以及线粒体 DNA 不稳定。然而,通过增加糖酵解来维持 ATP 浓度。我们得出结论,Cld1 介导的心磷脂去酰化的转录调节通过调节糖酵解和呼吸的相对贡献来影响能量代谢。
