A metabolic redox relay supports ER proinsulin export in pancreatic islet β cells
Kristen E. Rohli, Nicole J. Stubbe, Emily M. Walker, Gemma L. Pearson, Scott A. Soleimanpour, Samuel B. Stephens
Kristen E. Rohli, Nicole J. Stubbe, Emily M. Walker, Gemma L. Pearson, Scott A. Soleimanpour, Samuel B. Stephens
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Research Article Cell biology Endocrinology

A metabolic redox relay supports ER proinsulin export in pancreatic islet β cells

Abstract

ER stress and proinsulin misfolding are heralded as contributing factors to β cell dysfunction in type 2 diabetes, yet how ER function becomes compromised is not well understood. Recent data identify altered ER redox homeostasis as a critical mechanism that contributes to insulin granule loss in diabetes. Hyperoxidation of the ER delays proinsulin export and limits the proinsulin supply available for insulin granule formation. In this report, we identified glucose metabolism as a critical determinant in the redox homeostasis of the ER. Using multiple β cell models, we showed that loss of mitochondrial function or inhibition of cellular metabolism elicited ER hyperoxidation and delayed ER proinsulin export. Our data further demonstrated that β cell ER redox homeostasis was supported by the metabolic supply of reductive redox donors. We showed that limiting NADPH and thioredoxin flux delayed ER proinsulin export, whereas thioredoxin-interacting protein suppression restored ER redox and proinsulin trafficking. Taken together, we propose that β cell ER redox homeostasis is buffered by cellular redox donor cycles, which are maintained through active glucose metabolism.

Authors

Kristen E. Rohli, Nicole J. Stubbe, Emily M. Walker, Gemma L. Pearson, Scott A. Soleimanpour, Samuel B. Stephens

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Figure 4

Mitochondrial dysfunction impairs ER-Golgi proinsulin trafficking.

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Mitochondrial dysfunction impairs ER-Golgi proinsulin trafficking. Clec1...
Clec16afl/fl (WT) and Clec16afl/fl Ins1-Cre (Clec16a-KO) mice were used as follows. (AC) Islets from 13- to 18-week-old male mice were treated with AdRIP-proCpepSNAP. At 48 hours after infection, islets were pulse-labeled with SNAP-505 (green), chased for 10 minutes, immunostained for BiP (red) and GM130 (magenta), and counterstained with DAPI (blue). (A) Representative images are shown. (B) The ratio of proCpepSNAP fluorescence coincident with the Golgi (GM130) compared with ER (BiP) was quantified (n = 5–6). (C) Total fluorescence intensity of proCpepSNAP was quantified. (DF) Islets from 8- to 10-week-old male and female mice expressing proCpepRUSH (AdRIP) were treated with biotin (200 μM) to initiate trafficking. At 3 hours after biotin addition, cells were fixed, immunostained for GM130 (Golgi, magenta), and counterstained with DAPI (blue). (D) Representative images are shown. (E) The number of insulin granules per cell was quantified (n = 8). (F) Insulin granule distance from the nearest point on the Golgi was quantified as a frequency per binned distance (n = 8). Data represent the mean ± SEM. *P < 0.05 by 2-tailed Student’s t test (B, C, and E) or 2-way ANOVA with Holm-Šídák posttest analysis (F). Scale bar = 5 μm.