Glucose homeostasis is achieved via complex interactions between the endocrine pancreas and other peripheral tissues and glucoregulatory neurocircuits in the brain that remain incompletely defined. Within the brain, neurons in the hypothalamus appear to play a particularly important role. Consistent with this notion, we report evidence that (pro)renin receptor (PRR) signaling within a subset of tyrosine hydroxylase (TH) neurons located in the hypothalamic paraventricular nucleus (PVNTH neurons) is a physiological determinant of the defended blood glucose level. Specifically, we demonstrate that PRR deletion from PVNTH neurons restores normal glucose homeostasis in mice with diet-induced obesity (DIO). Conversely, chemogenetic inhibition of PVNTH neurons mimics the deleterious effect of DIO on glucose. Combined with our finding that PRR activation inhibits PVNTH neurons, these findings suggest that in mice, (a) PVNTH neurons play a physiological role in glucose homeostasis, (b) PRR activation impairs glucose homeostasis by inhibiting these neurons, and (c) this mechanism plays a causal role in obesity-associated metabolic impairment.
Shiyue Pan, Lucas A.C. Souza, Caleb J. Worker, Miriam E. Reyes Mendez, Ariana Julia B. Gayban, Silvana G. Cooper, Alfredo Sanchez Solano, Richard N. Bergman, Darko Stefanovski, Gregory J. Morton, Michael W. Schwartz, Yumei Feng Earley
AMP-activated protein kinase (AMPK) plays a crucial role in maintaining ATP homeostasis in photoreceptor neurons. AMPK is a heterotrimeric protein consisting of alpha, beta, and gamma subunits. The independent functions of the two isoforms of the catalytic alpha subunit, PRKAA1 and PRKAA2, are uncharacterized in specialized neurons such as photoreceptors. Here we demonstrate in mice that rod photoreceptors lacking PRKAA2, but not PRKAA1, show altered levels of cGMP, GTP, and ATP, suggesting isoform-specific regulation of photoreceptor metabolism. Furthermore, PRKAA2 deficient mice display visual functional deficits on electroretinography and photoreceptor outer segment structural abnormalities on transmission electron microscopy consistent with neuronal dysfunction, but not neurodegeneration. Phosphoproteomics identified inosine monophosphate dehydrogenase (IMPDH) as a molecular driver of PRKAA2-specific photoreceptor dysfunction, and inhibition of IMPDH improved visual function in Prkaa2 rod photoreceptor knockout mice. These findings highlight a novel, therapeutically targetable PRKAA2 isoform-specific function of AMPK in regulating photoreceptor metabolism and function through a previously uncharacterized mechanism affecting IMPDH activity.
Tae Jun Lee, Yo Sasaki, Philip A. Ruzycki, Norimitsu Ban, Joseph B. Lin, Hung-Ting Wu, Andrea Santeford, Rajendra S. Apte
BACKGROUND. Obesity is a multi-factorial disease with adverse health implications including insulin resistance (IR). In patients with obesity, the presence of high circulating levels of leptin, deemed hyperleptinemia, is associated with IR. Recent data in mice with diet-induced-obesity (DIO) shows a partial reduction in leptin levels improves IR. Additional animal studies demonstrate IL-4 decreases leptin levels. In rodents, resident adipose tissue (AT) eosinophils (EOS) are the main source of IL-4 and are instrumental in maintaining metabolic homeostasis. A marked reduction in AT-EOS content is observed in animal models of DIO. These observations have not been explored in humans. METHODS. We analyzed AT from individuals with obesity and age-matched lean counterparts for AT-EOS content, IL-4, circulating leptin levels and measures of IR. RESULTS. Our results showed that individuals with obesity (n=15) had a significant reduction in AT-EOS content (P<0.01), decreased AT-IL-4 gene expression (P=0.02), and decreased IL-4 plasma levels (P<0.05) in addition to expected IR (P<0.001) and hyperleptinemia (P<0.01) compared to lean subjects (n=15). AT-EOS content inversely correlated with BMI (P=0.002) and IR (P=0.005). Ex vivo AT explants and in vitro cell culture of primary, human mature adipocytes exposed to either IL-4 or EOS conditioned media produced less leptin (P<0.05). CONCLUSIONS. Our results suggested for IL-4 to act as a link between EOS, AT, and leptin production. Future studies exploring this interaction may identify a new avenue for the treatment of obesity and its complications through amelioration of hyperleptinemia. TRIAL REGISTRATION. Clinicaltrials.gov NCT02378077 & NCT04234295. FUNDING. Dr. Eleanna De Filippis received support by Arizona Department of Health Services, Arizona Biomedical Research Commission (ABRC) (ADHS14-00003606), the Katryn H. and Roger Penske Career Development Award in Endocrinology in Honor of Dr. Ian Hay, and Mayo Foundation, KL2 TR002379-02-01 CTSA UL1 TR002377 NCATS/NIH. Dr. Elizabeth A. Jacobsen received support from NIAID AI132840 and Mayo Foundation
James D. Hernandez, Ting Li, Hamza Ghannam, Cassandra M. Rau, Mia Y. Masuda, James A. Madura, Elizabeth A. Jacobsen, Eleanna De Filippis
Depletion of torsinA from hepatocytes leads to reduced liver triglyceride secretion and marked hepatic steatosis. TorsinA is an atypical ATPase that lacks intrinsic activity unless it is bound to its activators lamina-associated polypeptide 1 (LAP1) or luminal domain-like LAP1 (LULL1). We previously demonstrated that depletion of LAP1 from hepatocytes has more modest effects on liver triglyceride secretion and steatosis development than depletion of torsinA. We now show that depletion of LULL1 alone does not significantly decrease triglyceride secretion or cause steatosis. However, simultaneous depletion of both LAP1 and LULL1 leads to defective triglyceride secretion and marked steatosis similar to that observed with depletion of torsinA. Depletion of both LAP1 and torsinA from hepatocytes generated phenotypes similar to those observed with only torsinA depletion, implying that the two proteins act in the same pathway in liver lipid metabolism. Our results demonstrate that torsinA and its activators dynamically regulate hepatic lipid metabolism.
Antonio Hernandez-Ono, Yi Peng Zhao, John W. Murray, Cecilia Östlund, Michael J. Lee, Angsi Shi, William T. Dauer, Howard J. Worman, Henry N. Ginsberg, Ji-Yeon Shin
Hyperuricemia is implicated in numerous pathologies but the mechanisms underlying uric acid production are poorly understood. Using a combination of mouse studies, cultured cell studies, and human serum samples, we sought to determine the cellular source of uric acid. In mice, fasting and glucocorticoid treatment increased serum uric acid and uric acid release from ex vivo incubated skeletal muscle. In vitro, glucocorticoids and the transcription factor FoxO3 increased purine nucleotide degradation and purine release from differentiated muscle cells, which coincided with the transcriptional upregulation of AMP deaminase 3, a rate-limiting enzyme in adenine nucleotide degradation. Heavy isotope tracing during co-culture experiments revealed that oxidation of muscle purines to uric acid required their transfer from muscle cells to a cell type that expresses xanthine oxidoreductase, such as endothelial cells. Lastly, in healthy women, matched for age and body composition, serum uric acid was greater in individuals scoring below average on standard physical function assessments. Together, these studies reveal skeletal muscle purine degradation is an underlying driver of uric acid production, with the final step of uric acid production occurring primarily in a non-muscle cell type. This suggests that skeletal muscle fiber purine degradation may represent a therapeutic target to reduce serum uric acid and treat numerous pathologies.
Spencer G. Miller, Catalina Matias, Paul S. Hafen, Andrew S. Law, Carol A. Witczak, Jeffrey J. Brault
Interorgan crosstalk via secreted hormones and metabolites is a fundamental aspect of mammalian metabolic physiology. Beyond the highly specialized endocrine cells, peripheral tissues are emerging as an important source of metabolic hormones that influence energy and nutrient metabolism and contribute to disease pathogenesis. Neuregulin 4 (Nrg4) is a fat-derived hormone that protects mice from nonalcoholic steatohepatitis (NASH) and NASH-associated liver cancer by shaping hepatic lipid metabolism and the liver immune microenvironment. Despite its enriched expression in brown fat, whether NRG4 plays a role in thermogenic response and mediates the metabolic benefits of cold exposure remain unexplored. Here we show that Nrg4 expression in inguinal white adipose tissue (iWAT) is highly responsive to chronic cold exposure. Nrg4 deficiency impairs beige fat induction and renders mice more susceptible to diet-induced metabolic disorders under mild cold conditions. Using mice with adipocyte and hepatocyte-specific Nrg4 deletion, we reveal that adipose tissue-derived NRG4, but not hepatic NRG4, is essential for beige fat induction following cold acclimation. Furthermore, treatment with recombinant NRG4-Fc fusion protein promotes beige fat induction in iWAT and improves metabolic health in diet-induced obese mice. These findings highlight a critical role of NRG4 in mediating beige fat induction and preserving metabolic health under mild cold conditions.
Zhimin Chen, Peng Zhang, Tongyu Liu, Xiaoxue Qiu, Siming Li, Jiandie D. Lin
Increased mitochondrial function may render some cancers vulnerable to mitochondrial inhibitors. Since mitochondrial function is regulated partly by mitochondrial DNA copy number (mtDNAcn), accurate measurements of mtDNAcn could help reveal which cancers are driven by increased mitochondrial function and may be candidates for mitochondrial inhibition. However, prior studies have employed bulk macrodissections that fail to account for cell type-specific or tumor cell heterogeneity in mtDNAcn. These studies have often produced unclear results, particularly in prostate cancer. Herein, we developed a multiplex in situ method to spatially quantify cell type specific mtDNAcn. We show that mtDNAcn is increased in luminal cells of high-grade prostatic intraepithelial neoplasia (HGPIN), is increased in prostatic adenocarcinomas (PCa), and is further elevated in metastatic castration-resistant prostate cancer. Increased PCa mtDNAcn was validated by two orthogonal methods and is accompanied by increases in mtRNAs and enzymatic activity. Mechanistically, MYC inhibition in prostate cancer cells decreases mtDNA replication and expression of several mtDNA replication genes, and MYC activation in the mouse prostate leads to increased mtDNA levels in the neoplastic prostate cells. Our in situ approach also revealed elevated mtDNAcn in precancerous lesions of the pancreas and colon/rectum, demonstrating generalization across cancer types using clinical tissue samples.
Jiayu Chen, Qizhi Zheng, Jessica L. Hicks, Levent Trabzonlu, Busra Ozbek, Tracy Jones, Ajay M. Vaghasia, Tatianna C. Larman, Rulin Wang, Mark C. Markowski, Samuel R. Denmeade, Kenneth J. Pienta, Ralph H. Hruban, Emmanuel S. Antonarakis, Anuj Gupta, Chi V. Dang, Srinivasan Yegnasubramanian, Angelo M. De Marzo
Previous studies have implicated the orexigenic hormone ghrelin as a mediator of exercise endurance and the feeding response post-exercise. Specifically, plasma ghrelin levels nearly double in mice when they are submitted to an hour-long bout of high-intensity interval exercise (HIIE) using treadmills. Also, GHSR (ghrelin receptor)-null mice exhibit decreased food intake following HIIE and a diminished running distance (time until exhaustion) during a longer, step-wise exercise endurance protocol. To investigate whether ghrelin-responsive mediobasal hypothalamus (MBH) neurons mediate these effects, we stereotaxically delivered the inhibitory DREADD virus AAV2-hSyn-DIO-hM4(Gi)-mCherry to the MBH of Ghsr-IRES-Cre mice, which express Cre-recombinase directed by the Ghsr promoter. We found that chemogenetic inhibition of GHSR-expressing MBH neurons [upon delivery of clozapine-N-oxide (CNO)] 1) suppressed food intake following HIIE by 31.3%, 2) reduced maximum running distance by 20.7%-22.7% and raised blood glucose and blood lactate levels by 18.4%-51.5% and 24.6%-39.2%, respectively, during an exercise endurance protocol, 3) reduced food intake following ghrelin administration by 57.2%, but 4) did not affect glucose tolerance. Further, HIIE increased MBH Ghsr expression. These results indicate that activation of ghrelin-responsive MBH neurons is required for the normal feeding response to HIIE and the usual amount of running exhibited during an exercise endurance protocol.
Omprakash Singh, Sean B. Ogden, Salil Varshney, Kripa Shankar, Deepali Gupta, Subhojit Paul, Sherri Osborne-Lawrence, Corine P. Richard, Nathan P. Metzger, Connor Lawrence, Luis León-Mercado, Jeffrey M. Zigman
Fibroblast growth factor 23 (FGF23) is a phosphate (Pi)-regulating hormone produced by bone. Hereditary hypophosphatemic disorders are associated with FGF23 excess, impaired skeletal growth and osteomalacia. Blocking FGF23 became an effective therapeutic strategy in X-linked hypophosphatemia, but testing remains limited in autosomal recessive hypophosphatemic rickets (ARHR). This study investigates the effects of Pi repletion and bone specific deletion of Fgf23 on bone and mineral metabolism in the Dmp1 knockout (Dmp1KO) mouse model of ARHR.At 12 weeks, Dmp1KO mice showed increased serum FGF23 and PTH levels, hypophosphatemia, impaired growth, rickets and osteomalacia. Six weeks of dietary Pi supplementation exacerbated FGF23 production, hyperparathyroidism, renal Pi excretion and osteomalacia. In contrast, osteocyte-specific deletion of Fgf23 resulted in a partial correction of FGF23 excess, which was sufficient to fully restore serum Pi levels, but only partially corrected the bone phenotype. In vitro, we show that FGF23 directly impairs osteoprogenitors differentiation and that DMP1 deficiency contributes to impaired mineralization independently of FGF23 or Pi levels. In conclusion, FGF23-induced hypophosphatemia is only partially responsible for the bone defects observed in Dmp1KO mice. Our data suggest that combined DMP1 repletion and FGF23 blockade could effectively correct ARHR-associated mineral and bone disorders.
Guillaume Courbon, Dominik Kentrup, Jane Joy Thomas, Xueyan Wang, Hao-Hsuan Tsai, Jadeah J. Spindler, John Von Drasek, Laura Mazudie Ndjonko, Marta Martinez-Calle, Sana Lynch, Lauriane Hivert, Xiaofang Wang, Wenhan Chang, Jian Q. Feng, Valentin David, Aline Martin
Emerging evidence shows that KRAS-mutant colorectal cancer (CRC) depends on glutamine (Gln) for survival and progression, indicating that targeting Gln metabolism may be a promising therapeutic strategy for KRAS-mutant CRC. However, the precise mechanism by which Gln metabolism reprogramming promotes and coordinates KRAS-mutant CRC progression remains to be fully investigated. Here, we discovered that solute carrier 25 member 21 (SLC25A21) expression was downregulated in KRAS-mutant CRC, and that SLC25A21 downregulation was correlated with poor survival of KRAS-mutant CRC patients. SLC25A21 depletion selectively accelerated the growth, invasion, migration, and metastasis of KRAS-mutant CRC cells in vitro and in vivo, and inhibited Gln-derived α-ketoglutarate (α-KG) efflux from mitochondria, thereby potentiating Gln replenishment, accompanied by increased GTP availability for persistent KRAS activation in KRAS-mutant CRC. The restoration of SLC25A21 expression impaired the KRAS-mutation-mediated resistance to cetuximab in KRAS-mutant CRC. Moreover, the arrested α-KG efflux that occurred in response to SLC25A21 depletion inhibited the activity of α-KG–dependent DNA demethylases, resulting in a further decrease in SLC25A21 expression. Our studies demonstrate that SLC25A21 plays a significant role as a tumor suppressor in KRAS-mutant CRC by antagonizing Gln-dependent anaplerosis to limit GTP availability for KRAS activation, which suggests potential alternative therapeutic strategies for KRAS-mutant CRC.
Sha-Sha Hu, Yue Han, Tian-Yuan Tan, Hui Chen, Jia-Wen Gao, Lan Wang, Min-Hui Yang, Li Zhao, Yi-Qing Wang, Yan-Qing Ding, Shuang Wang
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