Swarna Beesetti, Cliff Guy, Shyam Sirasanagandla, Mao Yang, Rhea Jr Sumpter, Heather Sheppard, Stephane Pelletier, Marcin W. Wlodarski, Douglas R. Green
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引用次数: 0
摘要
范可尼贫血症(Fanconi Anemia,FA)是一种常染色体隐性遗传疾病,具有多种临床表现,如再生障碍性贫血、癌症易感性和发育缺陷,包括性腺功能低下、小头畸形、器官功能障碍、不育、色素沉着、小眼球和骨骼缺陷。除了 DNA 修复缺陷外,线粒体自噬(mitophagy)缺陷导致的线粒体功能障碍也与 FA 有关,但其对 FA 表型的影响尚不清楚。本研究的重点是 FANCC 基因,该基因与其他 FA 基因一样,是 DNA 修复和线粒体质量控制不可或缺的组成部分。在本研究中,我们根据人类基因突变(FANCC c.67delG)建立了一个 FANCC 突变体小鼠模型,该模型在 DNA 修复方面存在缺陷,但在线粒体吞噬方面表现良好。我们发现,FANCC c.67delG突变小鼠模型再现了在FA患者身上观察到的一些表型,如细胞对DNA交联剂过敏和造血缺陷。相反,FANCC缺陷小鼠出现的小眼症、性腺功能低下和不育症等FA表型在FANCC c.67delG小鼠中却不存在,这表明FANCC的N端55个氨基酸对这些发育过程是不可或缺的。此外,FANCC c.67delG突变保留了有丝分裂吞噬功能,与FANCC无效突变不同,它不会导致细胞或组织中受损线粒体的积累。这项研究强调了 FANCC 蛋白的多面性,其不同的结构域负责 DNA 修复和有丝分裂。我们的研究结果表明,FA的发育缺陷可能并不仅仅源于DNA修复缺陷,还可能涉及其他功能,如线粒体质量控制。
Distinct developmental outcomes in DNA repair-deficient FANCC c.67delG mutant and FANCC−/− Mice
Fanconi Anemia (FA) is an autosomal recessive disorder characterized by diverse clinical manifestations such as aplastic anemia, cancer predisposition, and developmental defects including hypogonadism, microcephaly, organ dysfunction, infertility, hyperpigmentation, microphthalmia, and skeletal defects. In addition to the well-described defects in DNA repair, mitochondrial dysfunction due to defects in mitochondrial autophagy (mitophagy) is also associated with FA, although its contribution to FA phenotypes is unknown. This study focused on the FANCC gene, which, alongside other FA genes, is integral to DNA repair and mitochondrial quality control. In the present study, we created a FANCC mutant mouse model, based on a human mutation (FANCC c.67delG) that is defective in DNA repair but proficient in mitophagy. We found that the FANCC c.67delG mutant mouse model recapitulates some phenotypes observed in FA patients, such as cellular hypersensitivity to DNA cross-linking agents and hematopoietic defects. In contrast, FA phenotypes such as microphthalmia, hypogonadism, and infertility, present in FANCC-deficient mice, were absent in the FANCC c.67delG mice, suggesting that the N-terminal 55 amino acids of FANCC are dispensable for these developmental processes. Furthermore, the FANCC c.67delG mutation preserved mitophagy, and unlike the FANCC null mutation, did not lead to the accumulation of damaged mitochondria in cells or tissues. This study highlights the multifaceted nature of the FANCC protein, with distinct domains responsible for DNA repair and mitophagy. Our results suggest that developmental defects in FA may not solely stem from DNA repair deficiencies but could also involve other functions, such as mitochondrial quality control.
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