Molecular mechanism responsible for sex differences in electrical activity of mouse pancreatic β cells
Noelia Jacobo-Piqueras, Tamara Theiner, Stefanie M. Geisler, Petronel Tuluc
Noelia Jacobo-Piqueras, Tamara Theiner, Stefanie M. Geisler, Petronel Tuluc
View: Text | PDF
Research Article Cell biology Endocrinology

Molecular mechanism responsible for sex differences in electrical activity of mouse pancreatic β cells

Abstract

In humans, type 2 diabetes mellitus shows a higher prevalence in men compared with women, a phenotype that has been attributed to a lower peripheral insulin sensitivity in men. Whether sex-specific differences in pancreatic β cell function also contribute is largely unknown. Here, we characterized the electrophysiological properties of β cells in intact male and female mouse islets. Elevation of glucose concentration above 5 mM triggered an electrical activity with a similar glucose dependence in β cells of both sexes. However, female β cells had a more depolarized membrane potential and increased firing frequency compared with males. The higher membrane depolarization in female β cells was caused by approximately 50% smaller Kv2.1 K+ currents compared with males but otherwise unchanged KATP, large-conductance and small-conductance Ca2+-activated K+ channels, and background TASK1/TALK1 K+ current densities. In female β cells, the higher depolarization caused a membrane potential–dependent inactivation of the voltage-gated Ca2+ channels (CaV), resulting in reduced Ca2+ entry. Nevertheless, this reduced Ca2+ influx was offset by a higher action potential firing frequency. Because exocytosis of insulin granules does not show a sex-specific difference, we conclude that the higher electrical activity promotes insulin release in females, improving glucose tolerance.

Authors

Noelia Jacobo-Piqueras, Tamara Theiner, Stefanie M. Geisler, Petronel Tuluc

×

Figure 5

Kv2.1 current density is higher in males compared with females and it modulates the MP.

Options: View larger image (or click on image) Download as PowerPoint
Kv2.1 current density is higher in males compared with females and it mo...
(A) The 3-pulse protocol used to characterize the voltage sensitivity of the Kv channel activation and inactivation. (B) The current density amplitude was significantly higher in males (black, n = 9; 3 mice) compared with females (red, n = 9; 3 mice). Inset showing the scatter plot of the Kv current density at +60 mV. (C) The Kv current voltage dependence of activation (empty symbols) and inactivation (full symbols) were not different between β cells of male and female mice. (D) Average trace of the K+ current measured in males (n = 9; 3 mice) and female (n = 9; 3 mice) in the absence or presence of 100 nM specific Kv2.1 blocker stromatoxin-1 (Strx-1) (males in gray; females in wine). (E) K+ current-voltage relationship without Strx-1 (full symbols) and after the addition of Strx-1 (empty symbols) in pancreatic β cells of both sexes. (F) Scatter plot showing the individual values of the K+ currents with and without Strx-1 in both male and female β cells at +80 mV. (G) Average trace of Strx-1–sensitive Kv2.1 K+ currents calculated by subtraction from panel D. (H) Current-voltage relationship of Kv2.1 currents. Inset shows the normalized conductance. (I) Scatter plot of the Kv2.1 current density at +80 mV. (J) Average of glucose-induced electrical activity of male β cells (n = 9; 3 mice) in intact islets with and without 100 nM Strx-1. (K) Scatter plot of the the average MP in male β cells with and without 100 nM Strx-1. All values are mean ± SEM. *P < 0.05; ***P < 0.001 by paired or unpaired, 2-tailed Student’s t test.