Phosphorylation of murine double minute-2 on Ser166 is downstream of VEGF-A in exercised skeletal muscle and regulates primary endothelial cell migration and FoxO gene expression.

We demonstrated in a previous study that murine double minute (Mdm)-2 is essential for exercise-induced skeletal muscle angiogenesis. In the current study, we investigated the mechanisms that regulate Mdm2 activity in response to acute exercise and identified VEGF-A as a key stimulator of Mdm2 phosphorylation on Ser(166) (p-Ser166-Mdm2). VEGF-A and p-Ser166-Mdm2 protein levels were measured in human and rodent muscle biopsy specimens after 1 bout of exercise. VEGF-A-dependent Mdm2 phosphorylation was demonstrated in vivo in mice harboring myofiber-specific deletion of VEGF-A (mVEGF(-/-)) and in vitro in primary human and rodent endothelial cells (ECs). Exercise increased VEGF-A and p-Ser166-Mdm2 protein levels respectively by 157 and 68% in human muscle vs. pre-exercise levels. Similar results were observed in exercised rodent muscles compared to sedentary controls; however, exercise-induced Mdm2 phosphorylation was significantly attenuated in mVEGF(-/-) mice. Recombinant VEGF-A elevated p-Ser166-Mdm2 by 50-125% and stimulated migration by 33% in ECs when compared to untreated cells, whereas the Mdm2 antagonist Nutlin-3a abrogated VEGF-driven EC migration. Finally, overexpression of a Ser166-Mdm2 phosphorylation mimetic increased EC migration, increased Mdm2 to FoxO1 binding (+55%), and decreased FoxO1-dependent gene expression compared with ECs overexpressing WT-Mdm2. Our results suggest that VEGF-mediated Mdm2 phosphorylation on Ser(166) is a novel proangiogenic pathway within the skeletal muscle.

Striated muscle angio-adaptation requires changes in Vasohibin-1 expression pattern.

Vasohibin-1 (VASH-1) was recently identified as a negative feedback regulator of angiogenesis. Here, we analyzed how the expression of the two active anti-angiogenic VASH-1 isoforms p36 and p42 was altered during physiological and pathological muscle angio-adaptation. Our results showed that VASH-1 protein expression was muscle-type specific, with higher levels detected in less vascularized muscles. In rat plantaris and heart muscles, the expression of VASH-1 protein was decreased in response to exercise training, a physiological pro-angiogenic stimulus leading to muscle capillary growth. Interestingly, expression patterns for p36 and p42 were different between plantaris and heart muscles. Next, we analyzed the time-course expression of VASH-1 isoforms in rat soleus muscles subjected to hindlimb unloading, a model that induces muscle capillary regression. Both p36 and p42 isoforms were increased, a signal in favor of some vessel destabilization and regression. Finally, we investigated VASH-1 expression in plantaris muscles from Zucker Diabetic Fatty rats (ZDF) that develop obesity and type-2 diabetes associated with a loss of capillaries in skeletal muscle. VASH-1 expression was higher in sedentary ZDF rats when compared to lean animals, suggesting its potential role during capillary regression. Interestingly, a physiological VASH-1 level was efficiently restored in spontaneously active ZDF animals where muscle capillarization was preserved. In conclusion, our results bring evidence that endogenous VASH-1 isoforms p36 and p42 are key actors of physiological and pathological muscle angio-adaptation.