Distinct HIF1α and HIF2α functions control skeletal muscle metabolism and erythropoiesis
Junhyeong Lee, Merc Emil Matienzo, Sangyi Lim, Edzel Evallo, Yeongsin Kim, Sujin Jang, Keon Kim, Chang Hyeon Choi, Youn Ho Han, Chang-Min Lee, Tae-Il Jeon, Sang-Ik Park, Jun Wu, Dong-il Kim, Min-Jung Park
Junhyeong Lee, Merc Emil Matienzo, Sangyi Lim, Edzel Evallo, Yeongsin Kim, Sujin Jang, Keon Kim, Chang Hyeon Choi, Youn Ho Han, Chang-Min Lee, Tae-Il Jeon, Sang-Ik Park, Jun Wu, Dong-il Kim, Min-Jung Park
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Research Article Metabolism Muscle biology

Distinct HIF1α and HIF2α functions control skeletal muscle metabolism and erythropoiesis

Abstract

Skeletal muscle frequently encounters hypoxic stress, particularly during exercise, but the specific functions of the hypoxia-inducible factors HIF1α and HIF2α within myofibers remain unclear due to the lack of appropriate in vivo models. Here, we generated 3 complementary mouse models, myofiber-specific triple-PHD knockout (PHD mTKO) and inducible myofiber-specific overexpression of stabilized HIF1α or HIF2α, to delineate isoform-specific roles of HIFα signaling in skeletal muscle. HIF1α stabilization increased the proportion of oxidative fibers yet paradoxically impaired exercise capacity and mitochondrial function. In contrast, HIF2α activation protected against diet-induced obesity, improved glucose tolerance, and maintained mitochondrial function without altering fiber-type composition. Notably, HIF2α stabilization markedly elevated erythropoietin (EPO) expression in skeletal muscle and serum. Myofiber-specific deletion of EPO in the PHD mTKO background abolished polycythemia, demonstrating that this phenotype is driven specifically by muscle-derived EPO. Together, these findings uncover distinct roles of HIF1α and HIF2α in regulating muscle metabolism and mitochondrial function and establish the PHD–HIF2α axis as a myofiber-derived driver of systemic EPO production.

Authors

Junhyeong Lee, Merc Emil Matienzo, Sangyi Lim, Edzel Evallo, Yeongsin Kim, Sujin Jang, Keon Kim, Chang Hyeon Choi, Youn Ho Han, Chang-Min Lee, Tae-Il Jeon, Sang-Ik Park, Jun Wu, Dong-il Kim, Min-Jung Park

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Figure 1

PHD deficiency in skeletal muscle protects against glucose intolerance and diet-induced obesity.

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PHD deficiency in skeletal muscle protects against glucose intolerance a...
(A) Schematic of the PHD mTKO mice. (B) Representative immunoblots of PHD1, PHD2, PHD3, HIF1α, and HIF2α from the soleus. (C) mRNA levels of HIFα target genes in the soleus (PHD 1/2/3fl/fl, n = 6; PHD mTKO, n = 6). (D) Body weights of mice on an NCD (PHD 1/2/3fl/fl, n = 9; PHD mTKO, n = 4). (E) Weights of muscles and adipose tissues of mice on an NCD (PHD 1/2/3fl/fl, n = 6; PHD mTKO, n = 6). (F) GTT on 21-week-old mice on an NCD (left) and area under the curve of glucose levels (right) (PHD 1/2/3fl/fl, n = 6; PHD mTKO, n = 4). (G) Representative immunoblots from the soleus. (H) Fasting serum insulin levels (PHD 1/2/3fl/fl, n = 6; PHD mTKO, n = 6). (I) Body weights of male mice on an HFD (PHD 1/2/3fl/fl, n = 6; PHD mTKO, n = 5). (J) Representative images of body composition; red areas indicate fat depots. (K) GTT on 14-week-old HFD-fed mice (left) and area under the curve of glucose levels (right) (PHD 1/2/3fl/fl, n = 6; PHD mTKO, n = 5). (L) Representative immunoblots from the soleus. (M) Fasting serum insulin levels (PHD 1/2/3fl/fl, n = 5; PHD mTKO, n = 6). Data are shown as the mean ± SEM. Unpaired 2-tailed Student’s t test (C, E, F, H, K, and M) or 2-way ANOVA with Bonferroni’s post hoc test (D, F, I, and K) was used for statistical analyses. *P < 0.05, **P < 0.01, ***P < 0.001, and ****P < 0.0001. Quad., quadriceps; Gas., gastrocnemius; TA, tibialis anterior; iBAT, interscapular brown adipose tissue; iWAT, inguinal white adipose tissue.