Stress-impaired transcription factor expression and insulin secretion in transplanted human islets
Chunhua Dai, Nora S. Kayton, Alena Shostak, Greg Poffenberger, Holly A. Cyphert, Radhika Aramandla, Courtney Thompson, Ioannis G. Papagiannis, Christopher Emfinger, Masakazu Shiota, John M. Stafford, Dale L. Greiner, Pedro L. Herrera, Leonard D. Shultz, Roland Stein, Alvin C. Powers
Chunhua Dai, Nora S. Kayton, Alena Shostak, Greg Poffenberger, Holly A. Cyphert, Radhika Aramandla, Courtney Thompson, Ioannis G. Papagiannis, Christopher Emfinger, Masakazu Shiota, John M. Stafford, Dale L. Greiner, Pedro L. Herrera, Leonard D. Shultz, Roland Stein, Alvin C. Powers
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Research Article Endocrinology

Stress-impaired transcription factor expression and insulin secretion in transplanted human islets

Abstract

Type 2 diabetes is characterized by insulin resistance, hyperglycemia, and progressive β cell dysfunction. Excess glucose and lipid impair β cell function in islet cell lines, cultured rodent and human islets, and in vivo rodent models. Here, we examined the mechanistic consequences of glucotoxic and lipotoxic conditions on human islets in vivo and developed and/or used 3 complementary models that allowed comparison of the effects of hyperglycemic and/or insulin-resistant metabolic stress conditions on human and mouse islets, which responded quite differently to these challenges. Hyperglycemia and/or insulin resistance impaired insulin secretion only from human islets in vivo. In human grafts, chronic insulin resistance decreased antioxidant enzyme expression and increased superoxide and amyloid formation. In human islet grafts, expression of transcription factors NKX6.1 and MAFB was decreased by chronic insulin resistance, but only MAFB decreased under chronic hyperglycemia. Knockdown of NKX6.1 or MAFB expression in a human β cell line recapitulated the insulin secretion defect seen in vivo. Contrary to rodent islet studies, neither insulin resistance nor hyperglycemia led to human β cell proliferation or apoptosis. These results demonstrate profound differences in how excess glucose or lipid influence mouse and human insulin secretion and β cell activity and show that reduced expression of key islet-enriched transcription factors is an important mediator of glucotoxicity and lipotoxicity.

Authors

Chunhua Dai, Nora S. Kayton, Alena Shostak, Greg Poffenberger, Holly A. Cyphert, Radhika Aramandla, Courtney Thompson, Ioannis G. Papagiannis, Christopher Emfinger, Masakazu Shiota, John M. Stafford, Dale L. Greiner, Pedro L. Herrera, Leonard D. Shultz, Roland Stein, Alvin C. Powers

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Figure 5

Amyloid deposition in human grafts is increased in NSG-HFD mice.

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Amyloid deposition in human grafts is increased in NSG-HFD mice. (A) Rel...
(A) Relative mRNA level of IAPP in human grafts (n = 5/diet). *P < 0.05. (B) Representative images of amyloid in human grafts labeled with insulin (green) and thioflavin S (red). Original magnification, ×20. (C) Measurement of thioflavin S area of human grafts (n = 12 grafts/diet, **P < 0.01). Human, but not mouse, β cells accumulate intracellular lipid droplets. Electron microscopy images of β cells from human graft (D and E), mouse graft (F and G), and mouse pancreas (H and I). Arrows point to lipid droplet(s). N, nuclear, G, granule. Scale bar: 3 μm. (JL) The number of lipid droplets per β cell in human grafts (β cell n = 45–70), mouse grafts (n = 50–71), and mouse pancreatic β cells (n = 56–74). *P < 0.05. Unpaired 2-tailed Student’s t test was used for analysis of statistical significance. Darker bars represent mouse data; lighter bars represent human data.