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A TGF-β1/LEF1/β-catenin/JLP network motif regulates autophagy and tubule injury in renal fibrosis
Chen Li, Meng Zhang, Maoqing Tian, Zeyu Tang, Yuying Hu, Yuyu Long, Xiaofei Wang, Liwen Qiao, Jiefei Zeng, Yujuan Wang, Xinghua Chen, Cheng Chen, Xiaoyan Li, Lu Zhang, Huiming Wang
Chen Li, Meng Zhang, Maoqing Tian, Zeyu Tang, Yuying Hu, Yuyu Long, Xiaofei Wang, Liwen Qiao, Jiefei Zeng, Yujuan Wang, Xinghua Chen, Cheng Chen, Xiaoyan Li, Lu Zhang, Huiming Wang
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Research Article Cell biology Nephrology

A TGF-β1/LEF1/β-catenin/JLP network motif regulates autophagy and tubule injury in renal fibrosis

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Abstract

Sustained injury to renal tubular epithelial cells (TECs), driven by excessive autophagy, is a critical mechanism underlying kidney fibrosis. Our previous work identified JLP — a TEC-expressed scaffolding protein — as an endogenous antifibrotic factor that counteracts TGF-β1–induced autophagy and fibrogenesis. However, the mechanism underlying JLP downregulation in renal fibrosis remains unclear. Here, we delineated a TGF-β1/LEF1/β-catenin/JLP axis that governs TEC autophagy through a dichotomous regulatory circuit. Under physiological conditions, low levels of β-catenin and LEF1 with minimal nuclear localization permitted normal JLP expression, which in turn maintained autophagy in check. In contrast, during renal injury, TGF-β1 promoted the expression and nuclear translocation of β-catenin and LEF1, which together suppressed JLP transcription. This loss of JLP-mediated inhibition led to unchecked autophagy and exacerbated fibrotic damage. Analyses of kidney tissues from patients with CKD, murine fibrotic kidneys, and cultured HK-2 cells confirmed consistent JLP downregulation accompanied by upregulation and nuclear accumulation of LEF1 and β-catenin. Therapeutic intervention using the β-catenin/LEF1 inhibitor iCRT3 or LEF1-targeted silencing in murine fibrosis models restored JLP expression, attenuated TEC autophagy, and ameliorated renal fibrosis. These findings revealed an autoregulatory circuit controlling TEC autophagy and fibrogenesis, and supported LEF1 and β-catenin as potential therapeutic targets in CKD.

Authors

Chen Li, Meng Zhang, Maoqing Tian, Zeyu Tang, Yuying Hu, Yuyu Long, Xiaofei Wang, Liwen Qiao, Jiefei Zeng, Yujuan Wang, Xinghua Chen, Cheng Chen, Xiaoyan Li, Lu Zhang, Huiming Wang

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Figure 1

LEF1 acts as a transcription factor to inhibit JLP gene expression.

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LEF1 acts as a transcription factor to inhibit JLP gene expression.
(A) ...
(A) The 4 putative 4 LEF1 binding sites in the JLP gene (SPAG9) promoter region identified by JASPAR. (B) PCR amplification was carried out with DNA fragments that were immunoprecipitated by anti-LEF1 (IP), anti-IgG (negative control), and anti–RNA polymerase II (RPII, positive control), and total DNA fragment (Input). (C) ChIP-qPCR was performed to verify LEF1 binding to the promoter of the SPAG9 gene in HK-2 cells (n = 3 independent experiments). (D) Relative luciferase activities associated with the wild-type (Wt) and site-mutated (Mut) LEF1-binding sequences in the SPAG9 gene promoter in LEF1-overexpressing HEK-293T cells (n = 5 independent experiments). (E) qRT-PCR analysis of SPAG9 and LEF1 expression in HK-2 cells from the indicated groups. Cells were transfected with either LEF1 siRNA or control siRNA (left panel), or with either pcDNA3.1 (oe-Ctrl) or LEF1-pcDNA3.1 (oe-LEF1) plasmid (right panel) (n = 3 independent experiments). (F) Schematic representation of LEF1 binding to the promoter region of the SPAG9 gene, regulating JLP expression. Data are presented as mean ± SD. Two-tailed, unpaired Student’s t test (C and E) and 1-way ANOVA followed by Tukey’s multiple-comparison test (D) were used for statistical analysis. NS, no significant difference.

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