Moreover, changes in capillary recruitment statistically explaine

Moreover, changes in capillary recruitment statistically explained ∼29% of the association between changes in FFA levels and insulin-mediated glucose uptake [21].

A defect involving FFA-induced impaired insulin signaling through the same PKC-θ mechanism in endothelial cells, which in turn may negatively influence the balance between insulin-mediated vasodilatation and vasoconstriction, may be responsible for the impaired capillary recruitment. In support of such a mechanism, PKC-θ has been shown to be present in the endothelium of muscle resistance arteries of both mice and humans, and to be activated by physiological levels of insulin and pathophysiological levels of palmitic acid [4]. By genetic and pharmacological inhibition of PKC-θ activity in mice, it was demonstrated that activated PKC-θ induces insulin-mediated check details vasoconstriction by the inhibition of insulin-mediated Akt activation, which results in a reduction of vasodilatation, and by the stimulation of insulin-mediated ERK1/2 activation, resulting in enhanced ET-1-dependent vasoconstriction (Figure 3) [4]. These data are consistent with a role for FFA-induced microvascular dysfunction in the development of obesity-associated disorders [21]. Vascular insulin resistance and AngII.  Another potential mechanism between adipose tissue and the microvasculature

is RAS. Obese individuals LY2835219 in vitro Glutathione peroxidase are characterized by increased activity of the RAS [93]. Adipocytes are rich sources of angiotensinogen, the precursor protein of AngII, and possess all the enzymes necessary to produce AngII [90]. These findings suggest the existence of a local RAS in adipose

tissue. Moreover, the amount of angiotensinogen mRNA in adipose tissue is 68% of that in the liver, supporting an important role for adipose angiotensinogen in AngII production [79]. AngII causes vasoconstriction via the AT1R and vasodilatation through the AT2R. Both are expressed in muscle microvasculature [12] and in vitro studies have repeatedly shown that AngII impairs vascular insulin signaling and reduces insulin-stimulated NO production via the AT1R [2,111,117]. AngII also increases the expression of IL-6 and TNF-α, as well as oxidative stress via the nuclear factor B pathway, which may also impair insulin signaling. Therefore, insulin resistance and RAS activation could cooperatively facilitate microvascular vasoconstriction. This provides a plausible explanation for repeated clinical trial findings that AT1R blockade decreases blood pressure and improves insulin sensitivity in patients with insulin resistance [50,76,82]. Surprisingly, acutely raising AngII systemically also improves muscle glucose disposal thought to be secondary to the hemodynamic effects of AngII [9,49]. Neither study, however, examined the microvascular changes.

Comments are closed.