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Sex-specific brain erythropoietin regulation of mouse metabolism and hypothalamic inflammation
Soumyadeep Dey, Zhenzhong Cui, Oksana Gavrilova, Xiaojie Zhang, Max Gassmann, Constance T. Noguchi
Soumyadeep Dey, Zhenzhong Cui, Oksana Gavrilova, Xiaojie Zhang, Max Gassmann, Constance T. Noguchi
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Research Article Inflammation Metabolism

Sex-specific brain erythropoietin regulation of mouse metabolism and hypothalamic inflammation

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Abstract

The blood hormone erythropoietin (EPO), upon binding to its receptor (EpoR), modulates high-fat diet–induced (HFD-induced) obesity in mice, improves glucose tolerance, and prevents white adipose tissue inflammation. Transgenic mice with constitutive overexpression of human EPO solely in the brain (Tg21) were used to assess the neuroendocrine EPO effect without increasing the hematocrit. Male Tg21 mice resisted HFD-induced weight gain; showed lower serum adrenocorticotropic hormone, corticosterone, and C-reactive protein levels; and prevented myeloid cell recruitment to the hypothalamus compared with WT male mice. HFD-induced hypothalamic inflammation (HI) and microglial activation were higher in male mice, and Tg21 male mice exhibited a lower increase in HI than WT male mice. Physiological EPO function in the brain also showed sexual dimorphism in regulating HFD response. Female estrogen production blocked reduced weight gain and HI. Targeted deletion of EpoR gene expression in neuronal cells worsened HFD-induced glucose intolerance in both male and female mice but increased weight gain and HI in the hypothalamus in male mice only. Both male and female Tg21 mice kept on normal chow and HFD showed significantly improved glycemic control. Our data indicate that cerebral EPO regulates weight gain and HI in a sex-dependent response, distinct from EPO regulation of glycemic control, and independent of erythropoietic EPO response.

Authors

Soumyadeep Dey, Zhenzhong Cui, Oksana Gavrilova, Xiaojie Zhang, Max Gassmann, Constance T. Noguchi

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Figure 2

Reduced hypothalamus inflammatory response and microglial cell activation in Tg21 male mice compared with WT male mice.

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Reduced hypothalamus inflammatory response and microglial cell activatio...
(A and B) Representative hypothalamic sections of age-matched (8 weeks) male WT and Tg21 mice during NCD (A) or after 3 weeks of HFD feeding (B) stained for the nuclear marker, DAPI; inflammatory marker, TNF-α; and microglial cell marker, Iba1. 3V, third ventricle. Scale bar: 100 μm. Original magnification, ×40. (C and D) Quantification of A and B to denote TNF-α+ and Iba1+ cells. (E and F) Representative fields of view in HFD-fed WT and Tg21 mice (scale bar: 20 μm) (E), analyzed for quantification of fluorescence intensity of Iba1 (F). (G and H) Representative hypothalamic sections of age-matched (8 weeks) male WT and Tg21 mice after 3 weeks of HFD feeding stained for activated microglial cell markers, CD68 and DAPI (scale bar: 100 μm; original magnification, ×40) (G), and quantification of CD68+ cells (H). Each image is representative of n = 8–10/group. (I) Gene expression of markers Ccl2, Il6, and Il1β in the hypothalamus of age-matched (8 weeks) male Tg21 and WT mice on NCD or after 3 weeks of HFD, as determined by quantitative RT-PCR, normalized to WT control on NCD and adjusted to Gapdh gene expression (n = 8–10/group). In box-and-whisker plots, bounds denote the 25th to 75th percentile, the lines represent the medians, and whiskers indicate the range from minimum to maximum values and includes outliers. **P < 0.01, ***P < 0.001 (2-way ANOVA).

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