Akt3 inhibits adipogenesis and protects from diet-induced obesity via WNK1/SGK1 signaling
Liang Ding, Lifang Zhang, Sudipta Biswas, Rebecca C. Schugar, J. Mark Brown, Tatiana Byzova, Eugene Podrez
Liang Ding, Lifang Zhang, Sudipta Biswas, Rebecca C. Schugar, J. Mark Brown, Tatiana Byzova, Eugene Podrez
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Research Article Metabolism

Akt3 inhibits adipogenesis and protects from diet-induced obesity via WNK1/SGK1 signaling

Abstract

Three Akt isoforms, encoded by 3 separate genes, are expressed in mammals. While the roles of Akt1 and Akt2 in metabolism are well established, it is not yet known whether Akt3 plays a role in metabolic diseases. We now report that Akt3 protects mice from high-fat diet–induced obesity by suppressing an alternative pathway of adipogenesis via with no lysine protein kinase-1 (WNK1) and serum/glucocorticoid-inducible kinase 1 (SGK1). We demonstrate that Akt3 specifically phosphorylates WNK1 at T58 and promotes its degradation via the ubiquitin-proteasome pathway. A lack of Akt3 in adipocytes increases the WNK1 protein level, leading to activation of SGK1. SGK1, in turn, promotes adipogenesis by phosphorylating and inhibiting transcription factor FOXO1 and, subsequently, activating the transcription of PPARγ in adipocytes. Akt3-deficient mice have an increased number of adipocytes and, when fed a high-fat diet, display increased weight gain, white adipose tissue expansion, and impaired glucose homeostasis. Pharmacological blockade of SGK1 in high-fat diet–fed Akt3-deficient mice suppressed adipogenesis, prevented excessive weight gain and adiposity, and ameliorated metabolic parameters. Thus, Akt3/WNK1/SGK1 represents a potentially novel signaling pathway controlling the development of obesity.

Authors

Liang Ding, Lifang Zhang, Sudipta Biswas, Rebecca C. Schugar, J. Mark Brown, Tatiana Byzova, Eugene Podrez

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Figure 5

Deficiency of Akt3 promotes white adipose tissue deposition and weight gain in mice.

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Deficiency of Akt3 promotes white adipose tissue deposition and weight g...
(A) Body weight of sex-matched WT and Akt3–/– mice fed a chow diet at 4, 8, 10, 12, 14, 16, 18, 20, and 22 weeks of age. n = 20 (10 male, 10 female). (B) Body weight changes in sex-matched WT and Akt3–/– mice fed an HFD. n = 16 (8 male, 8 female). (C) Body weight of male and female WT and Akt3–/– mice fed an HFD for 0 and 16 weeks. n = 8 (4 male, 4 female). (D) Body fat percentage of WT and Akt3–/– mice fed a chow diet or HFD. n = 10 (5 male, 5 female). (E) Weight of white adipose tissue (WAT) of WT and Akt3–/– mice on a chow diet or an HFD. n = 10 (5 male, 5 female). (F) Weight of gonadal (gon), retroperitoneal (retro), and s.c. (sub) white adipose tissue from WT and Akt3–/– mice fed a chow diet or an HFD. n = 10 (5 male, 5 female). (G) Abdominal fat image of representative 10-month-old female WT and Akt3–/– mice on a chow diet (upper panel). Lower panel shows gonadal (gon), retroperitoneal (retro), and s.c. (sub) fat pad isolated from WT and Akt3–/– mice on a chow diet. (H) Lean mass was calculated by subtracting the fat mass from body weight of mice fed a chow diet or HFD. n = 10. (I) H&E-stained paraffin-embedded sections of gonadal WAT from 8-week-old female WT and Akt3–/– mice fed a chow diet. Graph to the right shows size distribution of adipocytes. n = 5. Data represent means ± SEM. *P < 0.05 by ANOVA with Bonferroni post-hoc test (A and B) and 2-tailed Student’s t test (C–H).