Abstract
Progressive loss of pancreatic β-cell functional mass and anti-diabetic drug responsivity are classic findings in diabetes, frequently attributed to compensatory insulin hypersecretion and β-cell exhaustion. However, loss of β-cell mass and identity still occurs in mouse models of human KATP-gain-of-function induced Neonatal Diabetes Mellitus (NDM), in the absence of insulin secretion. Here we studied the temporal progression and mechanisms underlying glucotoxicity-induced loss of functional β-cell mass in NDM mice, and the effects of sodium-glucose transporter 2 inhibitors (SGLT2i) therapy. Upon tamoxifen induction of transgene expression, NDM mice rapidly developed severe diabetes followed by an unexpected loss of insulin content, decreased proinsulin processing and increased proinsulin at 2-weeks of diabetes. These early events were accompanied by a marked increase in β-cell oxidative and ER stress, without changes in islet cell identity. Strikingly, treatment with the SGLT2 inhibitor dapagliflozin restored insulin content, decreased proinsulin:insulin ratio and reduced oxidative and ER stress. However, despite reduction of blood glucose, dapagliflozin therapy was ineffective in restoring β-cell function in NDM mice when it was initiated at >40 days of diabetes, when loss of β-cell mass and identity had already occurred. Our data from mouse models demonstrate that: i) hyperglycemia per se, and not insulin hypersecretion, drives β-cell failure in diabetes, ii) recovery of β-cell function by SGLT2 inhibitors is potentially through reduction of oxidative and ER stress, iii) SGLT2 inhibitors revert/prevent β-cell failure when used in early stages of diabetes, but not when loss of β-cell mass/identity already occurred, iv) common execution pathways may underlie loss and recovery of β-cell function in different forms of diabetes. These results may have important clinical implications for optimal therapeutic interventions in individuals with diabetes, particularly for those with long-standing diabetes.
Highlights
Reduced pancreatic β-cell function and mass contribute to both type 1 diabetes (T1D) and type 2 diabetes (T2D) [1]
As expected by the presence of overactive ATP sensitive potassium channel (KATP)-channels in β-cells, neonatal diabetes mellitus (NDM) islets at 15 days of diabetes did not demonstrate an increase in cytosolic calcium in response to high glucose (Fig 1K), confirming previous results in islets from longstanding diabetic NDM mice [13]
Beta-cell oxidative and endoplasmic reticulum (ER) stress has been shown to be involved in β-cell failure in both T1D and T2D [36]
Summary
Reduced pancreatic β-cell function and mass contribute to both type 1 diabetes (T1D) and type 2 diabetes (T2D) [1]. Chronic high glucose induce β-cell membrane hyperexcitability, persistently elevated intracellular calcium concentration and insulin hypersecretion, all critically contributing to loss of β-cell mass in diabetes [6–8]. Loss of β-cell mass still occurs in KATP-gain-of-function (KATP-GOF) mouse model of human neonatal diabetes mellitus (NDM), in which all of these factors are absent due to KATP overactivity in pancreatic β-cells [9–13]. Most of the studies have been performed in human pancreases from T2D individuals and in animal models of T2D and obesity, and little is known about mechanisms underlying and temporal progression of loss of functional β-cell mass in monogenic diabetes, in the absence of compensatory increase in insulin secretion
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