Abstract
Smooth muscle cells (SMCs) in normal blood vessels exist in a highly differentiate state characterized by expression of SMC-specific contractile proteins (“contractile phenotype”). Following blood vessel injury in vivo or when cultured in vitro in the presence of multiple growth factors, SMC undergo a phenotype switch characterized by the loss of contractile markers and appearance of expression of non-muscle proteins (“proliferative phenotype”). While a number of factors have been reported to modulate this process, its regulation remains uncertain. Here we show that induction of SMC FGF signaling inhibits TGFβ signaling and converts contractile SMCs to the proliferative phenotype. Conversely, inhibition of SMC FGF signaling induces TGFβ signaling converting proliferating SMCs to the contractile phenotype, even in the presence of various growth factors in vitro or vascular injury in vivo. The importance of this signaling cross-talk is supported by in vivo data that show that an SMC deletion of a pan-FGF receptor adaptor Frs2α (fibroblast growth factor receptor substrate 2 alpha) in mice profoundly reduces neointima formation and vascular remodelling following carotid artery ligation. These results demonstrate that FGF-TGFβ signaling antagonism is the primary regulator of the SMC phenotype switch. Manipulation of this cross-talk may be an effective strategy for treatment of SMC-proliferation related diseases.
Highlights
Vascular smooth muscle cells (SMCs) are specialized blood vessel cells that play an important role in regulation of blood vessel tone, pressure, and flow
The downregulation of fibroblast growth factors (FGFs) signaling and upregulation of TGFβ activity during smooth muscle cell differentiation process was further confirmed in mouse vascular smooth muscle cells (VSMCs) isolated from the mouse aorta (Supplementary Fig. 1)
This report provides several lines of evidence to support the hypothesis that FGF-TGFβ signaling cross-talk is the key regulator of vascular SMC phenotype modulation
Summary
Vascular smooth muscle cells (SMCs) are specialized blood vessel cells that play an important role in regulation of blood vessel tone, pressure, and flow. Inhibition of FGF signaling upregulates TGFβR1 and downstream Smad2/3 activity while in vivo it leads to reduced SMC proliferation[23] These observations suggest that FGF signaling input may regulate the TGFβ-dependent proliferative to contractile SMC phenotype switch. We found that deletion of Frs2α in SMC increased SMC TGFβ signaling This led to a proliferative to contractile phenotype conversion even in the presence of high serum (in vitro) and blood vessel wall injury (in vivo). These results support the notion that FGF-TGFβ signaling antagonism is the key regulator of the SMC phenotype switch; manipulation of this cross-talk may be an effective strategy for treatment of SMC-proliferation related diseases
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