The IRE1α/XBP1s Pathway Is Essential for the Glucose Response and Protection of ß Cells.

Although glucose uniquely stimulates proinsulin biosynthesis in ß cells, surprisingly little is known of the underlying mechanism(s). Here, we demonstrate that glucose activates the unfolded protein response transducer inositol-requiring enzyme 1 alpha (IRE1α) to initiate X-box-binding protein 1 (Xbp1) mRNA splicing in adult primary ß cells. Using mRNA sequencing (mRNA-Seq), we show that unconventional Xbp1 mRNA splicing is required to increase and decrease the expression of several hundred mRNAs encoding functions that expand the protein secretory capacity for increased insulin production and protect from oxidative damage, respectively. At 2 wk after tamoxifen-mediated Ire1α deletion, mice develop hyperglycemia and hypoinsulinemia, due to defective ß cell function that was exacerbated upon feeding and glucose stimulation. Although previous reports suggest IRE1α degrades insulin mRNAs, Ire1α deletion did not alter insulin mRNA expression either in the presence or absence of glucose stimulation. Instead, ß cell failure upon Ire1α deletion was primarily due to reduced proinsulin mRNA translation primarily because of defective glucose-stimulated induction of a dozen genes required for the signal recognition particle (SRP), SRP receptors, the translocon, the signal peptidase complex, and over 100 other genes with many other intracellular functions. In contrast, Ire1α deletion in ß cells increased the expression of over 300 mRNAs encoding functions that cause inflammation and oxidative stress, yet only a few of these accumulated during high glucose. Antioxidant treatment significantly reduced glucose intolerance and markers of inflammation and oxidative stress in mice with ß cell-specific Ire1α deletion. The results demonstrate that glucose activates IRE1α-mediated Xbp1 splicing to expand the secretory capacity of the ß cell for increased proinsulin synthesis and to limit oxidative stress that leads to ß cell failure.

Development of cell therapy strategies to overcome copper toxicity in the LEC rat model of Wilson disease.

AIMS: Therapeutic replacement of organs with healthy cells requires disease-specific strategies. As copper toxicosis due to ATP7B deficiency in Wilson disease produces significant liver injury, disease-specific study of transplanted cell proliferation will offer insights into cell and gene therapy mechanisms. MATERIALS & METHODS: We used Long-Evans Cinnamon (LEC) rats to demonstrate the effects of liver preconditioning with radiation and ischemia reperfusion, followed by transplantation of healthy Long-Evans Agouti rat hepatocytes and analysis of hepatic atp7b mRNA, bile copper, liver copper and liver histology. RESULTS: LEC rats without cell therapy or after transplantation of healthy cells without liver conditioning accumulated copper and showed liver disease during the study period. Liver conditioning incorporating hepatic radiation promoted transplanted cell proliferation and reversed Wilson disease parameters, although with interindividual variations and time lags for improvement, which were different from previous results of liver repopulation in healthy animals. CONCLUSION: Cell therapy will correct genetic disorders characterized by organ damage. However, suitable mechanisms for inducing transplanted cell proliferation will be critical for therapeutic success.