TRPM7 kinase is required for insulin production and compensatory islet responses during obesity
Noushafarin Khajavi, Andreas Beck, Klea Riçku, Philipp Beyerle, Katharina Jacob, Sabrina F. Syamsul, Anouar Belkacemi, Peter S. Reinach, Pascale C.F. Schreier, Houssein Salah, Tanja Popp, Aaron Novikoff, Andreas Breit, Vladimir Chubanov, Timo D. Müller, Susanna Zierler, Thomas Gudermann
Noushafarin Khajavi, Andreas Beck, Klea Riçku, Philipp Beyerle, Katharina Jacob, Sabrina F. Syamsul, Anouar Belkacemi, Peter S. Reinach, Pascale C.F. Schreier, Houssein Salah, Tanja Popp, Aaron Novikoff, Andreas Breit, Vladimir Chubanov, Timo D. Müller, Susanna Zierler, Thomas Gudermann
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Research Article Cell biology

TRPM7 kinase is required for insulin production and compensatory islet responses during obesity

Abstract

Most overweight individuals do not develop diabetes due to compensatory islet responses to restore glucose homeostasis. Therefore, regulatory pathways that promote β cell compensation are potential targets for treatment of diabetes. The transient receptor potential cation channel subfamily M member 7 protein (TRPM7), harboring a cation channel and a serine/threonine kinase, has been implicated in controlling cell growth and proliferation. Here, we report that selective deletion of Trpm7 in β cells disrupted insulin secretion and led to progressive glucose intolerance. We indicate that the diminished insulinotropic response in β cell–specific Trpm7-knockout mice was caused by decreased insulin production because of impaired enzymatic activity of this protein. Accordingly, high-fat–fed mice with a genetic loss of TRPM7 kinase activity displayed a marked glucose intolerance accompanied by hyperglycemia. These detrimental glucoregulatory effects were engendered by reduced compensatory β cell responses because of mitigated protein kinase B (AKT)/ERK signaling. Collectively, our data identify TRPM7 kinase as a potentially novel regulator of insulin synthesis, β cell dynamics, and glucose homeostasis under obesogenic diet.

Authors

Noushafarin Khajavi, Andreas Beck, Klea Riçku, Philipp Beyerle, Katharina Jacob, Sabrina F. Syamsul, Anouar Belkacemi, Peter S. Reinach, Pascale C.F. Schreier, Houssein Salah, Tanja Popp, Aaron Novikoff, Andreas Breit, Vladimir Chubanov, Timo D. Müller, Susanna Zierler, Thomas Gudermann

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Figure 7

TRPM7 kinase disruption impairs glucose homeostasis in obese mice.

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TRPM7 kinase disruption impairs glucose homeostasis in obese mice. Adult...
Adult mice (Trpm7R/R and control littermates) maintained on an HFD for 16 weeks. (A) Cumulative food intake (n ≥ 6 mice per genotype), (B) body weight (n ≥ 14 mice per genotype), (C) blood glucose (mg/dL) in freely fed (n ≥ 14 mice per genotype) or fasted (n ≥ 12 mice per genotype), and (D) plasma insulin levels (ng/mL) in freely fed (n = 8 mice per genotype) or fasted (16 hours overnight) (n = 8 mice per genotype) in male and female Trpm7R/R and control littermate mice were measured. (E and F) Blood glucose levels (mg/dL) before and within 2 hours after i.p. injection of (E) glucose (2 g/kg of body weight) and (F) insulin (0.75 U/kg of body weight) in WT and Trpm7R/R mice (left panels) and area under the curves (AUC in mg/dL × min; right panels). For glucose tolerance test (GTT; E) mice were fasted overnight (n ≥ 20 mice per genotype) and for insulin tolerance test (ITT; F) mice were fasted for 4 hours at the onset of the light cycle (n ≥ 14 mice per genotype). Data show means ± SEM and statistical differences were assessed by unpaired 2-tailed Student’s t test (C, D, E right, and F right) or 2-way ANOVA (E and F, left panels). Circles in bar graphs represent single values. P values are shown above the bars.