Rodríguez Luis R, Alysandratos Konstantinos-Dionysios, Katzen Jeremy, Murthy Aditi, Roque Barboza Willy, Tomer Yaniv, Bui Sarah, Acín-Pérez Rebeca, Petcherski Anton, Minakin Kasey, Carson Paige, Iyer Swati, Chavez Katrina, Cooper Charlotte H, Babu Apoorva, Weiner Aaron I, Vaughan Andrew E, Arany Zoltan, Shirihai Orian S, Kotton Darrell N, Beers Michael F
Pulmonary, Allergy, and Critical Care Division, Department of Medicine, Perelman School of Medicine at the University of Pennsylvania, Philadelphia, United States of America.
Center for Regenerative Medicine, Boston University and Boston Medical Center, Boston, United States of America.
JCI Insight. 2025 Jul 1. doi: 10.1172/jci.insight.182578.
Alveolar epithelial type II (AT2) cell dysfunction is implicated in the pathogenesis of familial and sporadic idiopathic pulmonary fibrosis (IPF). We previously demonstrated that expression of an AT2 cell exclusive disease-associated protein isoform (SP-CI73T) in murine and patient-specific induced pluripotent stem cell (iPSC)-derived AT2 cells leads to a block in late macroautophagy and promotes time-dependent mitochondrial impairments; however, how a metabolically dysfunctional AT2 cell results in fibrosis remains elusive. Here, using murine and human iPSC-derived AT2 cell models expressing SP-CI73T, we characterize the molecular mechanisms governing alterations in AT2 cell metabolism that lead to increased glycolysis, decreased mitochondrial biogenesis, disrupted fatty acid oxidation, accumulation of impaired mitochondria, and diminished AT2 cell progenitor capacity manifesting as reduced AT2 self-renewal and accumulation of transitional epithelial cells. We identify deficient AMP-kinase signaling as a critical component of AT2 cell dysfunction and demonstrate that targeting this druggable signaling hub can rescue the aberrant AT2 cell metabolic phenotype and mitigate lung fibrosis in vivo.
肺泡II型上皮细胞(AT2)功能障碍与家族性和散发性特发性肺纤维化(IPF)的发病机制有关。我们之前证明,在小鼠和患者特异性诱导多能干细胞(iPSC)来源的AT2细胞中表达AT2细胞特异性疾病相关蛋白异构体(SP-CI73T)会导致晚期巨自噬受阻,并促进时间依赖性线粒体损伤;然而,代谢功能失调的AT2细胞如何导致纤维化仍不清楚。在此,我们使用表达SP-CI73T的小鼠和人iPSC来源的AT2细胞模型,表征了导致AT2细胞代谢改变的分子机制,这些改变导致糖酵解增加、线粒体生物合成减少、脂肪酸氧化中断、受损线粒体积累以及AT2细胞祖细胞能力下降,表现为AT2自我更新减少和过渡性上皮细胞积累。我们确定AMP激酶信号缺陷是AT2细胞功能障碍的关键组成部分,并证明靶向这个可药物化的信号枢纽可以挽救异常的AT2细胞代谢表型,并减轻体内肺纤维化。
