Induction of α cell–restricted Gc in dedifferentiating β cells contributes to stress-induced β cell dysfunction
Taiyi Kuo, Manashree Damle, Bryan J. González, Dieter Egli, Mitchell A. Lazar, Domenico Accili
Taiyi Kuo, Manashree Damle, Bryan J. González, Dieter Egli, Mitchell A. Lazar, Domenico Accili
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Research Article Endocrinology Metabolism

Induction of α cell–restricted Gc in dedifferentiating β cells contributes to stress-induced β cell dysfunction

Abstract

Diabetic β cell failure is associated with β cell dedifferentiation. To identify effector genes of dedifferentiation, we integrated analyses of histone methylation as a surrogate of gene activation status and RNA expression in β cells sorted from mice with multiparity-induced diabetes. Interestingly, only a narrow subset of genes demonstrated concordant changes to histone methylation and RNA levels in dedifferentiating β cells. Notable among them was the α cell signature gene Gc, encoding a vitamin D–binding protein. Although diabetes was associated with Gc induction, Gc-deficient islets did not induce β cell dedifferentiation markers and maintained normal ex vivo insulin secretion in the face of metabolic challenge. Moreover, Gc-deficient mice exhibited a more robust insulin secretory response than normal controls during hyperglycemic clamp studies. The data are consistent with a functional role of Gc activation in β cell dysfunction and indicate that multiparity-induced diabetes is associated with altered β cell fate.

Authors

Taiyi Kuo, Manashree Damle, Bryan J. González, Dieter Egli, Mitchell A. Lazar, Domenico Accili

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Figure 1

FACS isolates a highly pure β cell population from WT and I-KO mice.

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FACS isolates a highly pure β cell population from WT and I-KO mice. (A)...
(A) Oral glucose tolerance test in normal glucose tolerance (NGT) (n = 11) and diabetes mellitus (DM) (n = 9) mice. (B) Area under the curve (AUC) in A. (C) Glucose levels of fasted and refed NGT (n ≥ 10) and DM (n ≥ 7) mice. (D) Insulin levels of fasted and refed NGT (n ≥ 9) and DM (n ≥ 6) mice. (E) Acute insulin secretion following glucose stimulation in NGT (n = 5) and DM (n = 6) mice. (F) Oral glucose tolerance test in 12M NP WT (n = 17) and I-KO (n = 14) mice. (G) AUC in F. (H) Glucose levels of fasted and refed 12M NP WT (n ≥ 10) and I-KO (n ≥ 10) mice. (I) Insulin levels of fasted and refed 12M NP WT (n ≥ 10) and I-KO (n ≥ 8) mice. (J) Oral glucose tolerance test in 3M WT (n = 6) and I-KO (n = 9) mice. (K) AUC in J. (L) Glucose levels of fasted and refed 3M WT (n ≥ 6) and I-KO (n ≥ 3) mice. (M) Insulin levels of fasted and refed 3M WT (n ≥ 7) and I-KO (n ≥ 6) mice. (N) Schematic of β cell collection and experimental design. (O) A representative flow cytometric plot pregated on Tomato fluorescence–positive cells, where SYTOX Red (x axis) distinguishes live from dead cells and PE-TR (y axis) indicates the level of Tomato fluorescence. FACS was performed more than 10 times. Gene expression by reverse transcription quantitative PCR for (P) Ins1, (Q) Ins2, and (R) Gcg in dispersed pancreatic islet cells as input and Tomato fluorescence–positive and –negative cell populations (n = 3). Error bars represent ± SEM, *P < 0.05, **P < 0.01, and ***P < 0.005 by Student’s t test and ANOVA.