Antagonism of T-type calcium channels inhibits high-fat diet–induced weight gain in mice
Victor N. Uebele, Anthony L. Gotter, Cindy E. Nuss, Richard L. Kraus, Scott M. Doran, Susan L. Garson, Duane R. Reiss, Yuxing Li, James C. Barrow, Thomas S. Reger, Zhi-Qiang Yang, Jeanine E. Ballard, Cuyue Tang, Joseph M. Metzger, Sheng-Ping Wang, Kenneth S. Koblan, John J. Renger
Victor N. Uebele, Anthony L. Gotter, Cindy E. Nuss, Richard L. Kraus, Scott M. Doran, Susan L. Garson, Duane R. Reiss, Yuxing Li, James C. Barrow, Thomas S. Reger, Zhi-Qiang Yang, Jeanine E. Ballard, Cuyue Tang, Joseph M. Metzger, Sheng-Ping Wang, Kenneth S. Koblan, John J. Renger
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Research Article Metabolism

Antagonism of T-type calcium channels inhibits high-fat diet–induced weight gain in mice

Abstract

The epidemics of obesity and metabolic disorders have well-recognized health and economic burdens. Pharmacologic treatments for these diseases remain unsatisfactory with respect to both efficacy and side-effect profiles. Here, we have identified a potential central role for T-type calcium channels in regulating body weight maintenance and sleep. Previously, it was shown that mice lacking CaV3.1 T-type calcium channels have altered sleep/wake activity. We found that these mice were also resistant to high-fat diet–induced weight gain, without changes in food intake or sensitivity to high-fat diet–induced disruptions of diurnal rhythm. Administration of a potent and selective antagonist of T-type calcium channels, TTA-A2, to normal-weight animals prior to the inactive phase acutely increased sleep, decreased body core temperature, and prevented high-fat diet–induced weight gain. Administration of TTA-A2 to obese rodents reduced body weight and fat mass while concurrently increasing lean muscle mass. These effects likely result from better alignment of diurnal feeding patterns with daily changes in circadian physiology and potentially an increased metabolic rate during the active phase. Together, these studies reveal what we believe to be a previously unknown role for T-type calcium channels in the regulation of sleep and weight maintenance and suggest the potential for a novel therapeutic approach to treating obesity.

Authors

Victor N. Uebele, Anthony L. Gotter, Cindy E. Nuss, Richard L. Kraus, Scott M. Doran, Susan L. Garson, Duane R. Reiss, Yuxing Li, James C. Barrow, Thomas S. Reger, Zhi-Qiang Yang, Jeanine E. Ballard, Cuyue Tang, Joseph M. Metzger, Sheng-Ping Wang, Kenneth S. Koblan, John J. Renger

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Figure 7

Effects of TTA-A2 on body weight, activity, and active wake.

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Effects of TTA-A2 on body weight, activity, and active wake. (A) Diet-in...
(A) Diet-induced obese mice were weighed prior to daily dosing with vehicle (filled squares) or 10 mg/kg TTA-A2 (open squares). #P < 0.05, §P < 0.001 versus vehicle, 2-way ANOVA. (B) Starting and ending body weights from A. *P < 0.01, TTA-A2 versus vehicle; unpaired 2-tailed Student’s t test. (C) Locomotor activity of animals dosed with vehicle (filled squares) or 10 mg/kg TTA-A2 (open squares) in 30-minute epochs. Data are averaged such that each point represents the mean of 8 days from 8 animals (64 data points). Gray bars above denote significant differences (P < 0.05, Bonferroni post-hoc analysis). (D) Sprague-Dawley rats (n = 8) were implanted with telemetry monitors, recorded in a 7-day crossover dosing paradigm, and scored for sleep stage. Gray bars above denote significant differences (P < 0.05, mixed ANOVA analysis). Gray inverted triangles indicate time of dosing; solid bars represent lights-off periods. Data are mean ± SEM.