Shao Lina, El-Jouni Wassim, Kong Fanwu, Ramesh Janani, Kumar Radhe Shantha, Shen Xiaogang, Ren Jingjing, Devendra Shruti, Dorschel Arianna, Wu Maoqing, Barrera Ivan, Tabari Azadeh, Hu Kang, Haque Nadeem, Yambayev Ilyas, Li Shiqi, Kumar Amresh, Behera Tapas Ranjan, McDonough Gregory, Furuichi Masahito, Xifaras Michael, Lu Tzongshi, Alhayaza Rami Mohammad, Miyabayashi Koji, Fan Qiuling, Ajay Amrendra K, Zhou Jing
Harvard Center for Polycystic Kidney Disease Research and Renal Division, Brigham and Women's Hospital, Harvard Medical School, Boston, Massachusetts, USA; Nephrology Division, Zhejiang Provincial People's Hospital, Hangzhou, Zhejiang Province, China.
Harvard Center for Polycystic Kidney Disease Research and Renal Division, Brigham and Women's Hospital, Harvard Medical School, Boston, Massachusetts, USA; Division of Nephrology, Department of Medicine, Massachusetts General Hospital, Boston, Massachusetts, USA.
Kidney Int. 2020 Nov;98(5):1225-1241. doi: 10.1016/j.kint.2020.05.049. Epub 2020 Jun 28.
Polycystin-1 (PC1) and -2 (PC2), products of the PKD1 and PKD2 genes, are mutated in autosomal dominant polycystic kidney disease (ADPKD). They localize to the primary cilia; however, their ciliary function is in dispute. Loss of either the primary cilia or PC1 or PC2 causes cyst formation. However, loss of both cilia and PC1 or PC2 inhibits cyst growth via an unknown pathway. To help define a pathway, we studied cilium length in human and mouse kidneys. We found cilia are elongated in kidneys from patients with ADPKD and from both Pkd1 and Pkd2 knockout mice. Cilia elongate following polycystin inactivation. The role of intraflagellar transport proteins in Pkd1-deficient mice is also unknown. We found that inactivation of Ift88 (a gene expressing a core component of intraflagellar transport) in Pkd1 knockout mice, as well as in a new Pkd2 knockout mouse, shortened the elongated cilia, impeded kidney and liver cystogenesis, and reduced cell proliferation. Multi-stage in vivo analysis of signaling pathways revealed β-catenin activation as a prominent, early, and sustained event in disease onset and progression in Pkd2 single knockout but not in Pkd2.Ift88 double knockout mouse kidneys. Additionally, AMPK, mTOR and ERK pathways were altered in Pkd2 single knockout mice but only AMPK and mTOR pathway alteration were rescued in Pkd2.Ift88 double knockout mice. Thus, our findings advocate an essential role of polycystins in the structure and function of the primary cilia and implicate β-catenin as a key inducer of cystogenesis downstream of the primary cilia. Our data suggest that modulating cilium length and/or its associated signaling events may offer novel therapeutic approaches for ADPKD.
多囊蛋白 -1(PC1)和 -2(PC2)是PKD1和PKD2基因的产物,在常染色体显性多囊肾病(ADPKD)中发生突变。它们定位于初级纤毛;然而,它们的纤毛功能存在争议。初级纤毛或PC1或PC2的缺失都会导致囊肿形成。然而,纤毛与PC1或PC2两者都缺失会通过未知途径抑制囊肿生长。为了帮助确定一条途径,我们研究了人和小鼠肾脏中的纤毛长度。我们发现,ADPKD患者以及Pkd1和Pkd2基因敲除小鼠的肾脏中纤毛伸长。多囊蛋白失活后纤毛会伸长。鞭毛内运输蛋白在Pkd1基因缺陷小鼠中的作用也不清楚。我们发现,在Pkd1基因敲除小鼠以及一种新的Pkd2基因敲除小鼠中,Ift88(一个表达鞭毛内运输核心成分的基因)失活会使伸长的纤毛缩短,阻碍肾脏和肝脏囊肿的发生,并减少细胞增殖。对信号通路的多阶段体内分析显示,β-连环蛋白激活是Pkd2单基因敲除小鼠而非Pkd2.Ift88双基因敲除小鼠肾脏疾病发生和进展过程中一个突出、早期且持续的事件。此外,Pkd2单基因敲除小鼠中AMPK、mTOR和ERK信号通路发生改变,但在Pkd2.Ift88双基因敲除小鼠中只有AMPK和mTOR信号通路的改变得到了挽救。因此,我们的研究结果表明多囊蛋白在初级纤毛的结构和功能中起重要作用,并表明β-连环蛋白是初级纤毛下游囊肿发生的关键诱导因子。我们的数据表明,调节纤毛长度和/或其相关的信号事件可能为ADPKD提供新的治疗方法。
