Oxidative stress promotes fibrosis in systemic sclerosis through stabilization of a kinase-phosphatase complex
Ruiyuan Zhang, … , Wolfgang Peti, Nunzio Bottini
Ruiyuan Zhang, … , Wolfgang Peti, Nunzio Bottini
Published April 22, 2022
Citation Information: JCI Insight. 2022;7(8):e155761. https://doi.org/10.1172/jci.insight.155761.
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Research Article Inflammation

Oxidative stress promotes fibrosis in systemic sclerosis through stabilization of a kinase-phosphatase complex

Abstract

Systemic sclerosis (SSc) is a fibrotic autoimmune disease characterized by pathogenic activation of fibroblasts enhanced by local oxidative stress. The tyrosine phosphatase PTP4A1 was identified as a critical promoter of TGF-β signaling in SSc. Oxidative stress is known to functionally inactivate tyrosine phosphatases. Here, we assessed whether oxidation of PTP4A1 modulates its profibrotic action and found that PTP4A1 forms a complex with the kinase SRC in scleroderma fibroblasts, but surprisingly, oxidative stress enhanced rather than reduced PTP4A1’s association with SRC and its profibrotic action. Through structural assessment of the oxo-PTP4A1-SRC complex, we unraveled an unexpected mechanism whereby oxidation of a tyrosine phosphatase promotes its function through modification of its protein complex. Considering the importance of oxidative stress in the pathogenesis of SSc and fibrosis, our findings suggest routes for leveraging PTP4A1 oxidation as a potential strategy for developing antifibrotic agents.

Authors

Ruiyuan Zhang, Ganesan Senthil Kumar, Uwe Hansen, Martina Zoccheddu, Cristiano Sacchetti, Zachary J. Holmes, Megan C. Lee, Denise Beckmann, Yutao Wen, Zbigniew Mikulski, Shen Yang, Eugenio Santelli, Rebecca Page, Francesco Boin, Wolfgang Peti, Nunzio Bottini

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Figure 4

Oxidation-induced conformational changes in PTP4A1 P- and WPD-loops promote interaction with SRC.

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Oxidation-induced conformational changes in PTP4A1 P- and WPD-loops prom...
(A) Two-dimensional [1H,15N] TROSY spectra of oxidized and reduced PTP4A1 in the absence (black) or presence (red, magenta) of excess SRC SH3SH2. Blue dotted lines indicate 1σ levels, and residues that are line broadened beyond detection are indicated by magenta bars. (B) Diagram of CSPs of oxidized (top) and reduced (bottom) PTP4A1 upon binding of SRC SH3SH2. (C and D) Secondary structure elements are shown for reference. Residues showing chemical shift changes (blue; greater than 1σ) and intensity changes (magenta) for (C) oxidized and (D) reduced PTP4A1 were mapped onto the structures of oxidized (PDB ID 1RXD) and reduced (PDB ID 1XM2) PTP4A1 in ribbon and solvent-accessible surface representation. The key interacting regions of PTP4A1 are labeled.