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Sanglifehrin A mitigates multiorgan fibrosis by targeting the collagen chaperone cyclophilin B
Hope A. Flaxman, Maria-Anna Chrysovergi, Hongwei Han, Farah Kabir, Rachael T. Lister, Chia-Fu Chang, Robert Yvon, Katharine E. Black, Andreas Weigert, Rajkumar Savai, Alejandro Egea-Zorrilla, Ana Pardo-Saganta, David Lagares, Christina M. Woo
Hope A. Flaxman, Maria-Anna Chrysovergi, Hongwei Han, Farah Kabir, Rachael T. Lister, Chia-Fu Chang, Robert Yvon, Katharine E. Black, Andreas Weigert, Rajkumar Savai, Alejandro Egea-Zorrilla, Ana Pardo-Saganta, David Lagares, Christina M. Woo
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Research Article Inflammation Therapeutics

Sanglifehrin A mitigates multiorgan fibrosis by targeting the collagen chaperone cyclophilin B

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Abstract

Pathological deposition and crosslinking of collagen type I by activated myofibroblasts drives progressive tissue fibrosis. Therapies that inhibit collagen synthesis have potential as antifibrotic agents. We identify the collagen chaperone cyclophilin B as a major cellular target of the natural product sanglifehrin A (SfA) using photoaffinity labeling and chemical proteomics. Mechanistically, SfA inhibits and induces the secretion of cyclophilin B from the endoplasmic reticulum (ER) and prevents TGF-β1–activated myofibroblasts from synthesizing and secreting collagen type I in vitro, without inducing ER stress or affecting collagen type I mRNA transcription, myofibroblast migration, contractility, or TGF-β1 signaling. In vivo, SfA induced cyclophilin B secretion in preclinical models of fibrosis, thereby inhibiting collagen synthesis from fibrotic fibroblasts and mitigating the development of lung and skin fibrosis in mice. Ex vivo, SfA induces cyclophilin B secretion and inhibits collagen type I secretion from fibrotic human lung fibroblasts and samples from patients with idiopathic pulmonary fibrosis (IPF). Taken together, we provide chemical, molecular, functional, and translational evidence for demonstrating direct antifibrotic activities of SfA in preclinical and human ex vivo fibrotic models. Our results identify the cellular target of SfA, the collagen chaperone cyclophilin B, as a mechanistic target for the treatment of organ fibrosis.

Authors

Hope A. Flaxman, Maria-Anna Chrysovergi, Hongwei Han, Farah Kabir, Rachael T. Lister, Chia-Fu Chang, Robert Yvon, Katharine E. Black, Andreas Weigert, Rajkumar Savai, Alejandro Egea-Zorrilla, Ana Pardo-Saganta, David Lagares, Christina M. Woo

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Figure 5

SfA reduces fibrosis and immune activation in a mouse model of bleomycin-induced lung fibrosis.

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SfA reduces fibrosis and immune activation in a mouse model of bleomycin...
(A) Schematic of experimental procedure. (B) Representative images of lung sections stained with Picrosirius red to visualize collagen. Scale bar: 100 μm. (C) Collagen content in left lungs, as determined by hydroxyproline assay (n = 5–8). (D) Vascular leak assay, as determined by BCA assay for protein content in bronchioalveolar lavage (BAL) supernatant (n = 6). (E) Characterization of immune cells in BAL (n = 4–8). (F) Western blot for PPIA and PPIB in lung cell lysates. Representative Western blot and quantification of PPIA and PPIB in lung cell lysates (n = 3). (G) Generation of fibrotic precision cut lung slices (PCLS) from transgenic collagen-GFP reporter mice (Col-GFP) at day 14 after bleomycin challenge. PCLS were treated with or without SfA (1 μm) for 2 days (n = 3). (H and I) Collagen type I protein and mRNA levels were assessed in GFP– cells and GFP+ fibroblasts sorted by FACS from PCLS by Western blot (H) and real time PCR (I), respectively (n = 3). Secreted collagen type I was assessed in PCLS supernatants by sircol assay (J) (n = 3). All graphed data represent mean ± SD. C, D, F, and H–J were analyzed using 1-way ANOVA followed by pairwise comparisons corrected for multiple comparisons using the Šidák correction. E was analyzed using a 2-way ANOVA followed by pairwise comparisons corrected for multiple comparisons using the Tukey correction. *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.

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