Notch-mediated Ephrin signaling disrupts islet architecture and β cell function
Alberto Bartolomé, Nina Suda, Junjie Yu, Changyu Zhu, Jinsook Son, Hongxu Ding, Andrea Califano, Domenico Accili, Utpal B. Pajvani
Alberto Bartolomé, Nina Suda, Junjie Yu, Changyu Zhu, Jinsook Son, Hongxu Ding, Andrea Califano, Domenico Accili, Utpal B. Pajvani
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Research Article Endocrinology

Notch-mediated Ephrin signaling disrupts islet architecture and β cell function

Abstract

Altered islet architecture is associated with β cell dysfunction and type 2 diabetes (T2D) progression, but molecular effectors of islet spatial organization remain mostly unknown. Although Notch signaling is known to regulate pancreatic development, we observed “reactivated” β cell Notch activity in obese mouse models. To test the repercussions and reversibility of Notch effects, we generated doxycycline-dependent, β cell–specific Notch gain-of-function mice. As predicted, we found that Notch activation in postnatal β cells impaired glucose-stimulated insulin secretion and glucose intolerance, but we observed a surprising remnant glucose intolerance after doxycycline withdrawal and cessation of Notch activity, associated with a marked disruption of normal islet architecture. Transcriptomic screening of Notch-active islets revealed increased Ephrin signaling. Commensurately, exposure to Ephrin ligands increased β cell repulsion and impaired murine and human pseudoislet formation. Consistent with our mouse data, Notch and Ephrin signaling were increased in metabolically inflexible β cells in patients with T2D. These studies suggest that β cell Notch/Ephrin signaling can permanently alter islet architecture during a morphogenetic window in early life.

Authors

Alberto Bartolomé, Nina Suda, Junjie Yu, Changyu Zhu, Jinsook Son, Hongxu Ding, Andrea Califano, Domenico Accili, Utpal B. Pajvani

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Figure 1

β Cell Notch activation induces glucose intolerance and loss of β cell maturity.

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β Cell Notch activation induces glucose intolerance and loss of β cell m...
(A) Generation of β-tetO-NICD mice. (B) Hes1 expression in islets that were cultured overnight in the presence or absence of 1 μg/mL doxycycline (Dox). n = 3 mice per genotype. (C) Glucose tolerance test (GTT) in 8-week-old Cre, β-tetO-NICD, and Cre+ Rosa26-rtTA mice, prior to Dox exposure (n = 6–7 mice/group). AUC, area under the curve (mg × dL/min). (D) GTT in male and (E) female β-tetO-NICD and Cre controls after 8 weeks’ Dox (n = 7–9 mice/group). (F) Serum insulin after oral glucose challenge in male β-tetO-NICD and Cre controls, after 8 weeks’ Dox (n = 5 mice/group). (G) Gene expression in islets isolated from β-tetO-NICD and Cre mice after 8 weeks’ Dox. Notch targets (left) and β cell maturity genes (right) (n = 4–5 mice/group). (H) Representative images of pancreatic sections from Cre and Cre+ Rosa26-rtTA+ tetO-NICD control and β-tetO-NICD mice after 8 weeks’ Dox, with antibodies directed against Hes1 (top) or Mafa (bottom) and insulin, with quantitation of β cell nuclear Hes1 and Mafa fluorescence intensity (n = 5 mice/group). Scale bars: 20 μm. (I) Experimental schematic used in Dox-on at weaning (top) or in older mice (bottom). (J and K) GTT in 24-week-old control and β-tetO-NICD males prior to (J) or after (K) Dox (n = 5–6 mice/group). All data are shown with group means ± SEM; *, P < 0.05, **, P < 0.01, ***, P < 0.001, ****, P < 0.0001 by 2-tailed t test.