Physiological mechanisms of sustained fumagillin-induced weight loss
Jie An, Liping Wang, Michael L. Patnode, Vanessa K. Ridaura, Jonathan M. Haldeman, Robert D. Stevens, Olga Ilkayeva, James R. Bain, Michael J. Muehlbauer, Erin L. Glynn, Steven Thomas, Deborah Muoio, Scott A. Summers, James E. Vath, Thomas E. Hughes, Jeffrey I. Gordon, Christopher B. Newgard
Jie An, Liping Wang, Michael L. Patnode, Vanessa K. Ridaura, Jonathan M. Haldeman, Robert D. Stevens, Olga Ilkayeva, James R. Bain, Michael J. Muehlbauer, Erin L. Glynn, Steven Thomas, Deborah Muoio, Scott A. Summers, James E. Vath, Thomas E. Hughes, Jeffrey I. Gordon, Christopher B. Newgard
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Research Article Metabolism Therapeutics

Physiological mechanisms of sustained fumagillin-induced weight loss

Abstract

Current obesity interventions suffer from lack of durable effects and undesirable complications. Fumagillin, an inhibitor of methionine aminopeptidase-2, causes weight loss by reducing food intake, but with effects on weight that are superior to pair-feeding. Here, we show that feeding of rats on a high-fat diet supplemented with fumagillin (HF/FG) suppresses the aggressive feeding observed in pair-fed controls (HF/PF) and alters expression of circadian genes relative to the HF/PF group. Multiple indices of reduced energy expenditure are observed in HF/FG but not HF/PF rats. HF/FG rats also exhibit changes in gut hormones linked to food intake, increased energy harvest by gut microbiota, and caloric spilling in the urine. Studies in gnotobiotic mice reveal that effects of fumagillin on energy expenditure but not feeding behavior may be mediated by the gut microbiota. In sum, fumagillin engages weight loss–inducing behavioral and physiologic circuits distinct from those activated by simple caloric restriction.

Authors

Jie An, Liping Wang, Michael L. Patnode, Vanessa K. Ridaura, Jonathan M. Haldeman, Robert D. Stevens, Olga Ilkayeva, James R. Bain, Michael J. Muehlbauer, Erin L. Glynn, Steven Thomas, Deborah Muoio, Scott A. Summers, James E. Vath, Thomas E. Hughes, Jeffrey I. Gordon, Christopher B. Newgard

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Figure 8

Feeding rhythms and hepatic torpor and Clock gene expression of gnotobiotic mice receiving cecal microbiota transplants from HF/FG or HF/PF rats.

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Feeding rhythms and hepatic torpor and Clock gene expression of gnotobio...
All of the experiments in A–F, are from n = 5 mice/group. (A) Daily accumulated food intake of mice colonized with the cecal microbiota of a HF/FG rat. HF diet was provided ad libitum. (B) Daily accumulated food intake of mice colonized with the cecal microbiota of a HF/PF rat. HF diet was provided ad libitum. (C) Daily accumulated food intake of mice colonized with the cecal microbiota from a HF/FG rat. HF diet was provided ad libitum from experimental day 1–5 and then restricted by 10% from day 6–10. (D) Daily accumulated food intake of mice that were the recipients of a cecal microbiota transplant from a HF/PF rat. HF diet was provided ad libitum from day 1–5 and then restricted by 10% from day 6–10. (E) Expression of hepatic torpor genes in mice from the studies shown in A–D. +P = 0.06 when compared with HF/FG ad libitum/CR group. (F) Expression of hepatic circadian genes in mice from the studies shown in A–D. *P < 0.05 when compared with the corresponding calorically restricted groups. In E and F, data are presented as mean ± SD, and 2-tailed, unpaired t tests were performed. P < 0.05 with a Bonferroni correction was used to define statistical significance among groups.