The present study was conducted to investigate cellular and molecular features of chronic graft-versus-host disease fibroblasts (GVHD-Fbs) and to assess the effectiveness of nilotinib as a fibrosis modulator. Growth kinetics, phenotype, and differentiation of cultured skin biopsy-derived GVHD-Fbs were compared with normal fibroblasts from both a dermal cell line (n-Fbs) and healthy individuals undergoing cosmetic surgery (n-skin-Fbs). Collagen genes (COL1α1/COL1α2) and p-SMAD2 expression were assessed by real-time PCR and immunofluorescence. The in vivo effects of nilotinib on chronic GVHD (cGVHD)-affected skin were investigated by immunohistochemistry; the relationship to TGF-β plasma levels was assessed. Although the morphology, phenotype, and differentiation of cultured GVHD-Fbs were comparable to normal fibroblasts, growth was slower and senescence was reached earlier. The expression of COL1α1 and COL1α2 mRNAs was respectively 4 and 1.6 times higher in cGVHD-Fbs (P =.02); the addition of TGF-β increased n-Fbs, but not GVHD-Fbs, collagen gene expression. Compared with the baseline, the addition of 1 μM nilotinib induced 86.5% and 49% reduction in COL1α1 and COL1α2 expression in cultured GVHD-Fbs, respectively (P<.01). In vivo immunohistochemistry analysis of skin biopsy specimens from patients with cGVHD showed strong baseline staining for COL1α1 and COL1α2, which decreased sharply after 180 days of nilotinib; immunofluorescence revealed TGF-β inhibition and p-Smad2 reduction at the intracellular level. Of note, nilotinib treatment was associated with normalization of TGF-β levels both in culture supernatants and in plasma. In general, the data show that cGVHD fibroblasts promote fibrosis through abnormal collagen production induced by hyperactive TGF-β signaling. TGF-β inhibition at the intracellular and systemic level represents an essential antifibrotic mechanism of nilotinib in a clinical setting.

Nilotinib Treatment of Patients Affected by Chronic Graft-versus-Host Disease Reduces Collagen Production and Skin Fibrosis by Downmodulating the TGF-β and p-SMAD Pathway.

Marinelli Busilacchi E.
Co-primo
;
Costantini A.
Co-primo
;
Mancini G.;Tossetta G.;Olivieri J.;Poloni A.;Viola N.;Campanati A.;Marzioni D.;Olivieri A.
Ultimo
2020-01-01

Abstract

The present study was conducted to investigate cellular and molecular features of chronic graft-versus-host disease fibroblasts (GVHD-Fbs) and to assess the effectiveness of nilotinib as a fibrosis modulator. Growth kinetics, phenotype, and differentiation of cultured skin biopsy-derived GVHD-Fbs were compared with normal fibroblasts from both a dermal cell line (n-Fbs) and healthy individuals undergoing cosmetic surgery (n-skin-Fbs). Collagen genes (COL1α1/COL1α2) and p-SMAD2 expression were assessed by real-time PCR and immunofluorescence. The in vivo effects of nilotinib on chronic GVHD (cGVHD)-affected skin were investigated by immunohistochemistry; the relationship to TGF-β plasma levels was assessed. Although the morphology, phenotype, and differentiation of cultured GVHD-Fbs were comparable to normal fibroblasts, growth was slower and senescence was reached earlier. The expression of COL1α1 and COL1α2 mRNAs was respectively 4 and 1.6 times higher in cGVHD-Fbs (P =.02); the addition of TGF-β increased n-Fbs, but not GVHD-Fbs, collagen gene expression. Compared with the baseline, the addition of 1 μM nilotinib induced 86.5% and 49% reduction in COL1α1 and COL1α2 expression in cultured GVHD-Fbs, respectively (P<.01). In vivo immunohistochemistry analysis of skin biopsy specimens from patients with cGVHD showed strong baseline staining for COL1α1 and COL1α2, which decreased sharply after 180 days of nilotinib; immunofluorescence revealed TGF-β inhibition and p-Smad2 reduction at the intracellular level. Of note, nilotinib treatment was associated with normalization of TGF-β levels both in culture supernatants and in plasma. In general, the data show that cGVHD fibroblasts promote fibrosis through abnormal collagen production induced by hyperactive TGF-β signaling. TGF-β inhibition at the intracellular and systemic level represents an essential antifibrotic mechanism of nilotinib in a clinical setting.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11566/275323
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