Cover Story Current Issue

Excessive lipid accumulation in adipose tissue triggers hypertrophy and stress of adipocytes, leading to infiltration of proinflammatory immune cells, fibrosis and adipocyte cell death, collectively referred to as adipose tissue dysfunction. As consequence, adipocytes capacity to store lipids is impaired and fat is ectopically accumulated in organs such as muscle, liver and pancreas, a condition that promotes organ dysfunction and insulin resistance, contributing to the pathogenesis of type 2 diabetes (T2D).

Although fat accumulation in human pancreas was described decades ago, it has for long remained an underexplored facet of ectopic fat distribution. Pancreatic fat has been associated with improved insulin secretion in normoglycaemic subjects, but with impaired insulin secretion in patients at increased risk of T2D. Furthermore, T2D diabetes remission, i.e. recovery of beta cell function was accompanied by reduction of pancreatic fat. These clinical observations point to the controversial role of pancreatic fat in insulin secretion, and emphasize the need for experimental evidence demonstrating plausible lipolysis derived fatty acids-/secretome-mediated effects of pancreatic adipocytes in islets. To date, detailed studies on the mechanistic interactions between pancreatic adipocytes and insulin secretion remain sparse, as reliable in vitro models replicating the unique properties of these cells have been lacking.

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Current Issue

TGF-β antagonism synergizes with PPARγ agonism to reduce fibrosis and enhance beige adipogenesis

Young Jae Bahn, Yanling Wang, Pradeep Dagur, Nicholas Scott, ... Sushil G. Rane

TGF-β antagonism synergizes with PPARγ agonism to reduce fibrosis and enhance beige adipogenesis

 

Objectives

Adipose tissue depots vary markedly in their ability to store and metabolize triglycerides, undergo beige adipogenesis and susceptibility to metabolic disease. The molecular mechanisms that underlie such heterogeneity are not entirely clear. Previously, we showed that TGF-β signaling suppresses beige adipogenesis via repressing the recruitment of dedicated beige progenitors. Here, we find that TGF-β signals dynamically regulate the balance between adipose tissue fibrosis and beige adipogenesis.

Methods

We investigated adipose tissue depot-specific differences in activation of TGF-β signaling in response to dietary challenge. RNA-seq and fluorescence activated cell sorting was performed to identify and characterize cells responding to changes in TGF-β signaling status. Mouse models, pharmacological strategies and human adipose tissue analyses were performed to further define the influence of TGF-β signaling on fibrosis and functional beige adipogenesis.

Results

Elevated basal and high-fat diet inducible activation of TGF-β/Smad3 signaling was observed in the visceral adipose tissue depot. Activation of TGF-β/Smad3 signaling was associated with increased adipose tissue fibrosis. RNA-seq combined with fluorescence-activated cell sorting of stromal vascular fraction of epididymal white adipose tissue depot resulted in identification of TGF-β/Smad3 regulated ITGA5+ fibrogenic progenitors. TGF-β/Smad3 signal inhibition, genetically or pharmacologically, reduced fibrosis and increased functional beige adipogenesis. TGF-β/Smad3 antagonized the beneficial effects of PPARγ whereas TGF-β receptor 1 inhibition synergized with actions of rosiglitazone, a PPARγ agonist, to dampen fibrosis and promote beige adipogenesis. Positive correlation between TGF-β activation and ITGA5 was observed in human adipose tissue, with visceral adipose tissue depots exhibiting higher fibrosis potential than subcutaneous or brown adipose tissue depots.

Conclusions

Basal and high-fat diet inducible activation of TGF-β underlies the heterogeneity of adipose tissue depots. TGF-β/Smad3 activation promotes adipose tissue fibrosis and suppresses beige progenitors. Together, these dual mechanisms preclude functional beige adipogenesis. Controlled inhibition of TβRI signaling and concomitant PPARγ stimulation can suppress adipose tissue fibrosis and promote beige adipogenesis to improve metabolism.

 

Articles in Press

TGF-β antagonism synergizes with PPARγ agonism to reduce fibrosis and enhance beige adipogenesis

Young Jae Bahn, Yanling Wang, Pradeep Dagur, Nicholas Scott, ... Sushil G. Rane

TGF-β antagonism synergizes with PPARγ agonism to reduce fibrosis and enhance beige adipogenesis

 

Objectives

Adipose tissue depots vary markedly in their ability to store and metabolize triglycerides, undergo beige adipogenesis and susceptibility to metabolic disease. The molecular mechanisms that underlie such heterogeneity are not entirely clear. Previously, we showed that TGF-β signaling suppresses beige adipogenesis via repressing the recruitment of dedicated beige progenitors. Here, we find that TGF-β signals dynamically regulate the balance between adipose tissue fibrosis and beige adipogenesis.

Methods

We investigated adipose tissue depot-specific differences in activation of TGF-β signaling in response to dietary challenge. RNA-seq and fluorescence activated cell sorting was performed to identify and characterize cells responding to changes in TGF-β signaling status. Mouse models, pharmacological strategies and human adipose tissue analyses were performed to further define the influence of TGF-β signaling on fibrosis and functional beige adipogenesis.

Results

Elevated basal and high-fat diet inducible activation of TGF-β/Smad3 signaling was observed in the visceral adipose tissue depot. Activation of TGF-β/Smad3 signaling was associated with increased adipose tissue fibrosis. RNA-seq combined with fluorescence-activated cell sorting of stromal vascular fraction of epididymal white adipose tissue depot resulted in identification of TGF-β/Smad3 regulated ITGA5+ fibrogenic progenitors. TGF-β/Smad3 signal inhibition, genetically or pharmacologically, reduced fibrosis and increased functional beige adipogenesis. TGF-β/Smad3 antagonized the beneficial effects of PPARγ whereas TGF-β receptor 1 inhibition synergized with actions of rosiglitazone, a PPARγ agonist, to dampen fibrosis and promote beige adipogenesis. Positive correlation between TGF-β activation and ITGA5 was observed in human adipose tissue, with visceral adipose tissue depots exhibiting higher fibrosis potential than subcutaneous or brown adipose tissue depots.

Conclusions

Basal and high-fat diet inducible activation of TGF-β underlies the heterogeneity of adipose tissue depots. TGF-β/Smad3 activation promotes adipose tissue fibrosis and suppresses beige progenitors. Together, these dual mechanisms preclude functional beige adipogenesis. Controlled inhibition of TβRI signaling and concomitant PPARγ stimulation can suppress adipose tissue fibrosis and promote beige adipogenesis to improve metabolism.

 

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