INSERM U1149, Centre de Recherche sur l'inflammation (CRI), Paris, France; Université Paris Diderot, site Bichat, Sorbonne Paris cité, DHU UNITY, Paris, France; Laboratory of excellence GR-Ex, Paris, France; AP-HP, Centre Français des Porphyries (CFP), Hôpital Louis Mourier, Colombes, France; AP-HP, Département de Génétique, Hôpital Bichât, Paris, France.
INSERM U1149, Centre de Recherche sur l'inflammation (CRI), Paris, France; Université Paris Diderot, site Bichat, Sorbonne Paris cité, DHU UNITY, Paris, France.
Mol Genet Metab. 2019 Nov;128(3):342-351. doi: 10.1016/j.ymgme.2018.12.012. Epub 2019 Jan 7.
Non-syndromic microcytic congenital sideroblastic anemia (cSA) is predominantly caused by defective genes encoding for either ALAS2, the first enzyme of heme biosynthesis pathway or SLC25A38, the mitochondrial importer of glycine, an ALAS2 substrate. Herein we explored a new case of cSA with two mutations in GLRX5, a gene for which only two patients have been reported so far. The patient was a young female with biallelic compound heterozygous mutations in GLRX5 (p.Cys67Tyr and p.Met128Lys). Three-D structure analysis confirmed the involvement of Cys67 in the coordination of the [2Fe2S] cluster and suggested a potential role of Met128 in partner interactions. The protein-level of ferrochelatase, the terminal-enzyme of heme process, was increased both in patient-derived lymphoblastoid and CD34+ cells, however, its activity was drastically decreased. The activity of ALAS2 was found altered and possibly related to a defect in the biogenesis of its co-substrate, the succinyl-CoA. Thus, the patient exhibits both a very low ferrochelatase activity without any accumulation of porphyrins precursors in contrast to what is reported in erythropoietic protoporphyria with solely impaired ferrochelatase activity. A significant oxidative stress was evidenced by decreased reduced glutathione and aconitase activity, and increased MnSOD protein expression. This oxidative stress depleted and damaged mtDNA, decreased complex I and IV activities and depleted ATP content. Collectively, our study demonstrates the key role of GLRX5 in modulating ALAS2 and ferrochelatase activities and in maintaining mitochondrial function.
非综合征性小细胞先天性铁粒幼细胞性贫血(cSA)主要由编码血红素生物合成途径的第一个酶 ALAS2 或甘氨酸的线粒体摄取物 SLC25A38 的缺陷基因引起,甘氨酸是 ALAS2 的底物。在此,我们研究了一个新的 cSA 病例,该病例在 GLRX5 中存在两个突变,迄今为止仅报道了两个患者的 GLRX5 基因突变。该患者为年轻女性,存在 GLRX5 的双等位基因复合杂合突变(p.Cys67Tyr 和 p.Met128Lys)。三维结构分析证实 Cys67 参与了 [2Fe2S] 簇的配位,并提示 Met128 可能在伴侣相互作用中发挥作用。血红素合成途径的末端酶亚铁螯合酶的蛋白水平在患者来源的淋巴母细胞和 CD34+细胞中均增加,但其活性明显降低。发现 ALAS2 的活性发生改变,可能与其辅底物琥珀酰-CoA 的生物发生缺陷有关。因此,该患者表现出极低的亚铁螯合酶活性,而没有任何血红素前体的积累,与仅存在亚铁螯合酶活性缺陷的红细胞生成性原卟啉症形成鲜明对比。活性氧应激的证据是还原型谷胱甘肽和乌头酸酶活性降低,MnSOD 蛋白表达增加。这种氧化应激耗竭和损伤了 mtDNA,降低了复合物 I 和 IV 的活性并耗竭了 ATP 含量。总之,我们的研究表明 GLRX5 在调节 ALAS2 和亚铁螯合酶活性以及维持线粒体功能方面起着关键作用。
