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
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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

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Figure 4

Ca2+-activated K+ current amplitude is similar in β cells of both sexes but shows different kinetics and Ca2+ dependence.

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Ca2+-activated K+ current amplitude is similar in β cells of both sexes ...
(A) Protocol used for measuring Ca2+-activated K+ current, which consisted of a variable-length Ca2+-loading prepulse to 0 mV (P1), with each sweep increasing in length by 90 ms, followed by a test pulse (P2) to +80 mV to measure K+ currents. (B and C) Average trace of total, BK, SK, and Kv currents from male (n = 12; 3 mice) (B) and female (n = 16; 4 mice) (C) β cells at P1 = 90 ms. (D) The BK (full symbols) and SK (empty symbols) current components were obtained by subtraction from the total K+ current after the sequential addition of 1 μM paxilline and 200 nM apamin. (E) The remaining current after BK and SK block represents the Kv current component. (F) Scatter plot showing the significantly higher SK (left) and KV currents (right) at P1 = 90 ms. (G) The BK current kinetics following a P1 = 90 ms or (H) P1 = 1620 ms prepulse recorded in male and female β cells. (I) The remaining BK current at the end of the 600 ms P2 pulse is significantly larger in male β cells compared with females if the P1 prepulse is shorter than 800 ms. All values are mean ± SEM. *P < 0.05 by Mann-Whitney test (D and F) or 2-tailed Student’s t test (E, F, and I).