bFGF rescues dysfunctional properties of adipose-derived stem cells from individuals with type 2 diabetes by modulating their miRNA profile


Por: Civit-Urgell, A, Peña, E, Bejar, MT, Moscatiello, F, Vilahur, G, Badimon, L, Arderiu, G

Publicada: 1 dic 2025 Ahead of Print: 1 sep 2025
Resumen:
Aims/hypothesisThe aim of this study was to investigate whether basic fibroblast growth factor (bFGF) can restore the proliferation and migration capacities of adipose-derived stem cells (ASCs), which are impaired by type 2 diabetes, and improve vascular remodelling.MethodsASCs obtained from individuals with or without diabetes were cultured with 10 ng/ml bFGF for 9 days. The ASCs were phenotypically characterised and functionally tested for proliferation capacity. Differentially expressed miRNAs before and after treatment were analysed using miRNA arrays. Crosstalk between ASCs and human vascular smooth muscle cells (HVSMCs) was assessed using wound healing, transwell migration and co-culture assays. Finally, a Matrigel plug assay in nude mice was used to evaluate the contribution of ASCs to neovessel formation.ResultsbFGF treatment significantly enhanced the proliferation and migration of ASCs from individuals with type 2 diabetes (T2DM ASCs), and altered the expression of miRNAs associated with ASC proliferation. ASCs promoted HVSMC migration and, when co-cultured, facilitated tube-like structure formation. In vivo Matrigel plug assays revealed that bFGF treatment enhanced neovessel formation. Although both non-T2DM ASCs (ASCs from individuals without type 2 diabetes) and untreated T2DM ASCs stimulated angiogenesis, bFGF-treated subcutaneous and visceral T2DM ASCs promoted even greater neovessel formation. Additionally, bFGF treatment modulated the expression of multiple angiogenesis-related miRNAs in ASCs.Conclusions/interpretationPreconditioning T2DM ASCs with bFGF alters their miRNA profile, enhancing cell proliferation and their vascular remodelling potential. This strategy could improve the therapeutic utility of T2DM ASCs.

Filiaciones:
Civit-Urgell, A:
 Inst Recerca St Pau IR SANT PAU, Barcelona, Spain

 Univ Barcelona UB, Fac Farm & Ciencies Alimentacio, Barcelona, Spain

Peña, E:
 Inst Recerca St Pau IR SANT PAU, Barcelona, Spain

 Inst Salud Carlos III, Ctr Invest Biomed Red Cardiovasc CIBER CV, Madrid, Spain

Bejar, MT:
 Inst Recerca St Pau IR SANT PAU, Barcelona, Spain

 Univ Cambridge, Cambridge Stem Cell Inst, Cambridge, England

Moscatiello, F:
 Clin Teknon, Grp Quiron Salut, Barcelona, Spain

Vilahur, G:
 Inst Recerca St Pau IR SANT PAU, Barcelona, Spain

 Inst Salud Carlos III, Ctr Invest Biomed Red Cardiovasc CIBER CV, Madrid, Spain

Badimon, L:
 Inst Recerca St Pau IR SANT PAU, Barcelona, Spain

 Inst Salud Carlos III, Ctr Invest Biomed Red Cardiovasc CIBER CV, Madrid, Spain

 Univ VIC UCC, Sch Med, Barcelona, Spain

 Cardiovasc Res Fdn Hlth Prevent & Innovat FICSI, Barcelona, Spain

Arderiu, G:
 Inst Recerca St Pau IR SANT PAU, Barcelona, Spain

 Inst Salud Carlos III, Ctr Invest Biomed Red Cardiovasc CIBER CV, Madrid, Spain
ISSN: 0012186X





DIABETOLOGIA
Editorial
SPRINGER, 233 SPRING ST, NEW YORK, NY 10013 USA, Alemania
Tipo de documento: Article
Volumen: 68 Número: 12
Páginas: 2682-2695
WOS Id: 001563962300001
ID de PubMed: 40905998
imagen Green Submitted, hybrid

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