ABHD18通过脂肪酸的逐步水解降解心磷脂。

IF 4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Biological Chemistry Pub Date : 2025-05-14 DOI:10.1016/j.jbc.2025.110237

Mindong Ren,Shiyu Chen,Miriam L Greenberg,Michael Schlame

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引用次数: 0

摘要

心磷脂（CL）是线粒体的标志性磷脂，它携带四种脂肪酸，这些脂肪酸在重新合成后被重塑。在酵母中，重塑是通过Cld1和Taz1的共同作用完成的。Cld1是一种脂肪酶，可以从CL中去除脂肪酸，Taz1是一种转酰基酶，可以将脂肪酸从另一种磷脂转移到单聚物CL中。虽然taz1同源物已在所有真核生物中被鉴定，但cld1同源物仍然不清楚。在这里，我们证明了ABHD18是一种高度保守的植物、动物和人类蛋白，在功能上与Cld1同源。敲除Abhd18可降低taz敲除小鼠成肌细胞中单核细胞cl的浓度。果蝇中Abhd18的失活显著增加了CL的丰度。Abhd18失活还逆转了13C同位素测量的氯离子降解速率的增加，以及taz缺陷果蝇中脱酰基氯离子（如单聚氯离子和二聚氯离子）的积累。具有5个以上双键的CL种对ABHD18具有抗性。我们的数据表明，ABHD18是难以捉摸的脂肪酶，在小鼠和苍蝇中水解CL，可能在其他生物中也是如此。我们发现，ABHD18并不是仅仅去除一种脂肪酸，而是进一步使CL脱烷基。因此，ABHD18催化CL的分解，而TAZ则保护CL免受降解。

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ABHD18 degrades cardiolipin by stepwise hydrolysis of fatty acids.

Cardiolipin (CL), the signature phospholipid of mitochondria, carries four fatty acids that are remodeled after de novo synthesis. In yeast, remodeling is accomplished by the joint action of Cld1, a lipase that removes a fatty acid from CL, and Taz1, a transacylase that transfers a fatty acid from another phospholipid to monolyso-CL. While taz1 homologues have been identified in all eukaryotes, cld1 homologues have remained obscure. Here we demonstrate that ABHD18, a highly conserved protein of plants, animals, and humans, is functionally homologous to Cld1. Knockdown of Abhd18 decreased the concentration of monolyso-CL in murine, Taz-knockout myoblasts. Inactivation of Abhd18 in Drosophila substantially increased the abundance of CL. Abhd18 inactivation also reversed the increase in the rate of CL degradation, as measured with 13C isotopes, and the accumulation of deacylated CLs, such as monolyso-CL and dilyso-CL, in TAZ-deficient flies. CL species with more than 5 double bonds were resistant to ABHD18. Our data demonstrate that ABHD18 is the elusive lipase that hydrolyzes CL in mice and flies and presumably in other organisms. Rather than removing just one fatty acid, we show that ABHD18 deacylates CL further. Thus, ABHD18 catalyzes the breakdown of CL whereas TAZ protects CL from degradation.

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来源期刊

Journal of Biological Chemistry Biochemistry, Genetics and Molecular Biology-Biochemistry

自引率

4.20%

发文量

1233

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