DDR1 contributes to kidney inflammation and fibrosis by promoting the phosphorylation of BCR and STAT3
Corina M. Borza, Gema Bolas, Fabian Bock, Xiuqi Zhang, Favour C. Akabogu, Ming-Zhi Zhang, Mark de Caestecker, Min Yang, Haichun Yang, Ethan Lee, Leslie Gewin, Agnes B. Fogo, W. Hayes McDonald, Roy Zent, Ambra Pozzi
Corina M. Borza, Gema Bolas, Fabian Bock, Xiuqi Zhang, Favour C. Akabogu, Ming-Zhi Zhang, Mark de Caestecker, Min Yang, Haichun Yang, Ethan Lee, Leslie Gewin, Agnes B. Fogo, W. Hayes McDonald, Roy Zent, Ambra Pozzi
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Research Article Cell biology Nephrology

DDR1 contributes to kidney inflammation and fibrosis by promoting the phosphorylation of BCR and STAT3

Abstract

Discoidin domain receptor 1 (DDR1), a receptor tyrosine kinase activated by collagen, contributes to chronic kidney disease. However, its role in acute kidney injury and subsequent development of kidney fibrosis is not clear. Thus, we performed a model of severe ischemia/reperfusion-induced acute kidney injury that progressed to kidney fibrosis in WT and Ddr1-null mice. We showed that Ddr1-null mice had reduced acute tubular injury, inflammation, and tubulointerstitial fibrosis with overall decreased renal monocyte chemoattractant protein (MCP-1) levels and STAT3 activation. We identified breakpoint cluster region (BCR) protein as a phosphorylated target of DDR1 that controls MCP-1 production in renal proximal tubule epithelial cells. DDR1-induced BCR phosphorylation or BCR downregulation increased MCP-1 secretion, suggesting that BCR negatively regulates the levels of MCP-1. Mechanistically, phosphorylation or downregulation of BCR increased β-catenin activity and in turn MCP-1 production. Finally, we showed that DDR1-mediated STAT3 activation was required to stimulate the secretion of TGF-β. Thus, DDR1 contributes to acute and chronic kidney injury by regulating BCR and STAT3 phosphorylation and in turn the production of MCP-1 and TGF-β. These findings identify DDR1 an attractive therapeutic target for ameliorating both proinflammatory and profibrotic signaling in kidney disease.

Authors

Corina M. Borza, Gema Bolas, Fabian Bock, Xiuqi Zhang, Favour C. Akabogu, Ming-Zhi Zhang, Mark de Caestecker, Min Yang, Haichun Yang, Ethan Lee, Leslie Gewin, Agnes B. Fogo, W. Hayes McDonald, Roy Zent, Ambra Pozzi

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Figure 2

Attenuated AKI and chronic tubulointerstitial injury in Ddr1-KO mice.

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Attenuated AKI and chronic tubulointerstitial injury in Ddr1-KO mice. (A...
(A) Havcr1 (KIM-1) mRNA levels in WT and Ddr1-KO mice uninjured (d–1) or 3 days after IR were analyzed by quantitative PCR and normalized to Gapdh mRNA. Circles represent individual kidneys, and the bars show mean ± SD. Uninjured WT and Ddr1-KO n = 4, injured WT n = 8, injured Ddr1-KO n = 6. (B) Periodic acid–Schiff (PAS) staining of kidneys from WT and Ddr1-KO mice uninjured (d–1) and d3 after IR. Scale bar: 50 μm. (C) Acute injury was evaluated in uninjured (d–1) (WT and Ddr1-KO n = 3) and d3 injured mice (WT n = 15, Ddr1-KO n = 9). Circles represent individual kidneys, and bars show mean ± SD. (D). Blood urea nitrogen (BUN) was measured prior to injury (d–1) and at d9 and d28 after injury. Circles represent individual mice, and bars show mean ± SD. (E) PAS staining of kidneys from WT and Ddr1-KO mice uninjured (d–1) and 28 days after injury. Scale bar: 50 μm. (F) Tubular injury scores were evaluated in uninjured (d–1) (WT and Ddr1-KO n = 5) and d28 injured (WT n = 10, Ddr1-KO n = 6) mice. Circles represent single mice, and bars are mean ± SD. Statistical analysis: 1-way ANOVA followed by Tukey’s multiple-comparison test for A, C, and F and 2-way repeated measures ANOVA followed by Sidak’s multiple-comparison test for D.