Knockdown of electron transfer flavoprotein β subunit reduced TGF-β-induced α-SMA mRNA expression but not COL1A1 in fibroblast-populated three-dimensional collagen gel cultures

BackgroundThe inhibition of transforming growth factor β (TGF-β)-induced myofibroblast differentiation is a key objective for the treatment of hypertrophic scarring. We previously reported that knockdown of the electron transfer flavoprotein β subunit (ETFB) reduced mechanoregulated cell number in fibroblast-populated collagen gel cultures [1].ObjectiveTo characterize the effects of ETFB knockdown, we investigated gel contraction, TGF-β-induced collagen, α-SMA mRNA expression and stress fiber formation.MethodsFibroblasts were transfected with negative control or ETFB-specific siRNAs and embedded in collagen gels in an attached or detached condition. The gel contraction assay was performed in three different concentrations of collagen (0.5, 1.0 or 1.5 mg/mL) and was analyzed by measuring the changes in the gel area throughout the culture period. The attached collagen gel culture was performed in the presence of rTGF-β and the mRNA levels of α-SMA and COL1A1 were measured by qRT-PCR. The effect of ETFB knockdown on proliferation and stress fiber organization in monolayer cultures was investigated by conducting AlamarBlue assays and phalloidin staining.ResultsThe transfection of ETFB siRNA did not alter gel contraction compared to the negative control in all collagen concentrations. When the cells were treated with TGF-β under mechanical stress conditions, ETFB knockdown attenuated α-SMA mRNA expression to a level comparable to that observed in the absence of TGF-β. However, no inhibitory effect on COL1A1 mRNA levels was observed. The AlamarBlue assay indicated that the knockdown had no effect on the proliferation of cells cultured on plastic. Phalloidin staining of a monolayer culture showed that ETFB knockdown weakened the stress fiber organization induced by rTGF-β.ConclusionETFB knockdown can affect TGF-β-induced tissue remodeling and/or fibrotic processes in vitro.