CD47 prevents the elimination of diseased fibroblasts in scleroderma
Tristan Lerbs, Lu Cui, Megan E. King, Tim Chai, Claire Muscat, Lorinda Chung, Ryanne Brown, Kerri Rieger, Tyler Shibata, Gerlinde Wernig
Tristan Lerbs, Lu Cui, Megan E. King, Tim Chai, Claire Muscat, Lorinda Chung, Ryanne Brown, Kerri Rieger, Tyler Shibata, Gerlinde Wernig
View: Text | PDF
Research Article Dermatology

CD47 prevents the elimination of diseased fibroblasts in scleroderma

Abstract

Scleroderma is a devastating fibrotic autoimmune disease. Current treatments are partly effective in preventing disease progression but do not remove fibrotic tissue. Here, we evaluated whether scleroderma fibroblasts take advantage of the “don’t-eat-me-signal” CD47 and whether blocking CD47 enables the body’s immune system to get rid of diseased fibroblasts. To test this approach, we used a Jun-inducible scleroderma model. We first demonstrated in patient samples that scleroderma upregulated transcription factor JUN and increased promoter accessibilities of both JUN and CD47. Next, we established our scleroderma model, demonstrating that Jun mediated skin fibrosis through the hedgehog-dependent expansion of CD26+Sca1– fibroblasts in mice. In a niche-independent adaptive transfer model, JUN steered graft survival and conferred increased self-renewal to fibroblasts. In vivo, JUN enhanced the expression of CD47, and inhibiting CD47 eliminated an ectopic fibroblast graft and increased in vitro phagocytosis. In the syngeneic mouse, depleting macrophages ameliorated skin fibrosis. Therapeutically, combined CD47 and IL-6 blockade reversed skin fibrosis in mice and led to the rapid elimination of ectopically transplanted scleroderma cells. Altogether, our study demonstrates the efficiency of combining different immunotherapies in treating scleroderma and provides a rationale for combining CD47 and IL-6 inhibition in clinical trials.

Authors

Tristan Lerbs, Lu Cui, Megan E. King, Tim Chai, Claire Muscat, Lorinda Chung, Ryanne Brown, Kerri Rieger, Tyler Shibata, Gerlinde Wernig

×

Figure 5

JUN mediates increased self-renewal to fibroblasts.

Options: View larger image (or click on image) Download as PowerPoint
JUN mediates increased self-renewal to fibroblasts. (A) Mean fluorescenc...
(A) Mean fluorescence intensity for p-JUN after JUN knockout (ko JUN). Tukey’s multiple comparison test. *P < 0.05. n = 2. Bars represent means with standard deviations. (B) Mean fluorescence intensity for incorporated EdU (Alexa Fluor 594) after JUN knockout, without JUN induction (- JUN) and under JUN induction (+ JUN). Tukey’s multiple comparison test. *P < 0.05; ***P < 0.001. n = 6. Bars represent means with standard deviations. (C) Western blot bands for p-JUN, p-Stat3, FSP1, and GAPDH without and with JUN induction in primary mouse dermal fibroblasts. (D) Kaplan-Meier curve of adaptive transfer graft survivals with JUN induction, without JUN induction, and after JUN knockout. Photon emissions below 100,000 were considered as representing a lost graft. n = 5–8. (E) Representative optical images of an adaptive transfer model with JUN-inducible fibroblasts. n = 4–6. (F) Quantification of absolute photon emissions with and without JUN induction. Fisher’s multiple comparison test. *P < 0.01. n = 4–6. Bars represent means with standard deviations. (G) Corresponding trichrome (original magnification, ×10) and p-JUN stains of grafts. Black scale bar: 200 μm. Red scale bar: 25 μm. n = 4–6. (H) Representative optical images of a JUN-inducible adaptive transfer model ± vismodegib. n = 4–6. (I) Corresponding quantification of photon emissions. Values were normalized to the expression at day 0. Fisher’s multiple comparison test. *P < 0.05; **P < 0.01. n = 4–6. Bars represent means with standard deviations. (J) Schema of the adaptive serial transplantation model. (K) Corresponding pictures of RFP+ cells in the second, third, and fourth recipients with and without JUN induction. Scale bar: 500 μm. n = 2.