Publications by Year: 2014

2014

Pensa, Neoh, Resemann, Kreuzaler, Abell, Clarke, Reinheckel, Kahn, and Watson. (2014) 2014. “The PI3K Regulatory Subunits P55α and P50α Regulate Cell Death in Vivo”. Cell Death Differ 21 (9): 1442-50. https://doi.org/10.1038/cdd.2014.59.
The phosphatidylinositol 3-kinase (PI3K) regulatory subunits p55α and p50α are coordinately transcriptionally upregulated by signal transducer and activator of transcription 3 (Stat3) at the onset of mammary gland involution, a process that requires Stat3. Deletion of both p55α and p50α subunits in vivo abrogated mammary epithelial cell death during involution. This was associated also with reduced cytosolic levels and activity of the cysteine protease cathepsin L, which is implicated in lysosomal-mediated programmed cell death (LM-PCD) and is upregulated in involution. Furthermore, involution is delayed in cathepsin L-deficient mice suggesting that the p55α/p50α subunits mediate cell death in part by elevating the level of cathepsin L resulting in increased cytosolic activity. Surprisingly, we found that p55α/p50α localize to the nucleus where they bind to chromatin and regulate transcription of a subset of inflammatory/acute phase genes that are also Stat3 targets. Our findings reveal a novel role for these PI3K regulatory subunits as regulators of LM-PCD in vivo.
Emanuelli, Brice, Sara Vienberg, Graham Smyth, Christine Cheng, Kristin Stanford, Manimozhiyan Arumugam, Mervyn Michael, Andrew Adams, Alexei Kharitonenkov, and Ronald Kahn. (2014) 2014. “Interplay Between FGF21 and Insulin Action in the Liver Regulates Metabolism”. J Clin Invest 124 (2): 515-27. https://doi.org/10.1172/JCI67353.
The hormone FGF21 regulates carbohydrate and lipid homeostasis as well as body weight, and increasing FGF21 improves metabolic abnormalities associated with obesity and diabetes. FGF21 is thought to act on its target tissues, including liver and adipose tissue, to improve insulin sensitivity and reduce adiposity. Here, we used mice with selective hepatic inactivation of the IR (LIRKO) to determine whether insulin sensitization in liver mediates FGF21 metabolic actions. Remarkably, hyperglycemia was completely normalized following FGF21 treatment in LIRKO mice, even though FGF21 did not reduce gluconeogenesis in these animals. Improvements in blood sugar were due in part to increased glucose uptake in brown fat, browning of white fat, and overall increased energy expenditure. These effects were preserved even after removal of the main interscapular brown fat pad. In contrast to its retained effects on reducing glucose levels, the effects of FGF21 on reducing circulating cholesterol and hepatic triglycerides and regulating the expression of key genes involved in cholesterol and lipid metabolism in liver were disrupted in LIRKO mice. Thus, FGF21 corrects hyperglycemia in diabetic mice independently of insulin action in the liver by increasing energy metabolism via activation of brown fat and browning of white fat, but intact liver insulin action is required for FGF21 to control hepatic lipid metabolism.
Boucher, Jeremie, Andre Kleinridders, and Ronald Kahn. 2014. “Insulin Receptor Signaling in Normal and Insulin-Resistant States”. Cold Spring Harb Perspect Biol 6 (1). https://doi.org/10.1101/cshperspect.a009191.
In the wake of the worldwide increase in type-2 diabetes, a major focus of research is understanding the signaling pathways impacting this disease. Insulin signaling regulates glucose, lipid, and energy homeostasis, predominantly via action on liver, skeletal muscle, and adipose tissue. Precise modulation of this pathway is vital for adaption as the individual moves from the fed to the fasted state. The positive and negative modulators acting on different steps of the signaling pathway, as well as the diversity of protein isoform interaction, ensure a proper and coordinated biological response to insulin in different tissues. Whereas genetic mutations are causes of rare and severe insulin resistance, obesity can lead to insulin resistance through a variety of mechanisms. Understanding these pathways is essential for development of new drugs to treat diabetes, metabolic syndrome, and their complications.
Neithercott, Tracey, Cherise Shockley, Ronald Kahn, Chris Smith, Dominique Wilkins, Theresa Garnero, Katie Hathaway, et al. (2014) 2014. “People to Know 2014”. Diabetes Forecast 67 (10): 40-9.
Pensa, Sara, Bethan Lloyd-Lewis, Timothy Sargeant, Henrike Resemann, Ronald Kahn, and Christine Watson. (2014) 2014. “Signal Transducer and Activator of Transcription 3 and the Phosphatidylinositol 3-Kinase Regulatory Subunits P55α and P50α Regulate Autophagy in Vivo”. FEBS J 281 (20): 4557-67. https://doi.org/10.1111/febs.13035.
Mammary gland involution involves a process that includes one of the most dramatic examples of cell death in an adult mammalian organism. We have previously shown that signal transducer and activator of transcription 3 (Stat3) regulates a lysosomal pathway of cell death in the first 48 h of involution and induces lysosome leakiness in mammary epithelial cells. Interestingly, Stat3 is associated also with the striking induction of autophagy that occurs concomitantly with cell death, presumably as a transient survival mechanism. The phosphatidylinositol 3-kinase regulatory subunits p55α and p50α are dramatically and specifically upregulated at the transcriptional level by Stat3 at the onset of involution. We show here that ablation of either Stat3 or p55α/p50α in vivo affects autophagy during involution. We used two different cell culture models (normal mammary epithelial cells and mouse embryonic fibroblasts) to further investigate the role of p55α/p50α in autophagy regulation. Our results demonstrate a direct role for p55α/p50α as inhibitors of autophagy mediated by p85α. Thus, Stat3 and its downstream targets p55α/p50α are key regulators of the balance between autophagy and cell death in vivo.
Samocha-Bonet, Dixit, Kahn, Leibel, Lin, Nieuwdorp, Pietiläinen, et al. (2014) 2014. “Metabolically Healthy and Unhealthy Obese--the 2013 Stock Conference Report”. Obes Rev 15 (9): 697-708. https://doi.org/10.1111/obr.12199.
Obesity is closely associated with cardiovascular diseases and type 2 diabetes, but some obese individuals, despite having excessive body fat, exhibit metabolic health that is comparable with that of lean individuals. The 'healthy obese' phenotype was described in the 1980s, but major advancements in its characterization were only made in the past five years. During this time, several new mechanisms that may be involved in health preservation in obesity were proposed through the use of transgenic animal models, use of sophisticated imaging techniques and in vivo measurements of insulin sensitivity. However, the main obstacle in advancing our understanding of the metabolically healthy obese phenotype and its related long-term health risks is the lack of a standardized definition. Here, we summarize the proceedings of the 13th Stock Conference of the International Association of the Study of Obesity. We describe the current research and highlight the unanswered questions and gaps in the field. Better understanding of metabolic health in obesity will assist in therapeutic decision-making and help identify therapeutic targets to improve metabolic health in obesity.
Vernochet, Cecile, Federico Damilano, Arnaud Mourier, Olivier Bezy, Marcelo Mori, Graham Smyth, Anthony Rosenzweig, Nils-Göran Larsson, and Ronald Kahn. (2014) 2014. “Adipose Tissue Mitochondrial Dysfunction Triggers a Lipodystrophic Syndrome With Insulin Resistance, Hepatosteatosis, and Cardiovascular Complications”. FASEB J 28 (10): 4408-19. https://doi.org/10.1096/fj.14-253971.
Mitochondrial dysfunction in adipose tissue occurs in obesity, type 2 diabetes, and some forms of lipodystrophy, but whether this dysfunction contributes to or is the result of these disorders is unknown. To investigate the physiological consequences of severe mitochondrial impairment in adipose tissue, we generated mice deficient in mitochondrial transcription factor A (TFAM) in adipocytes by using mice carrying adiponectin-Cre and TFAM floxed alleles. These adiponectin TFAM-knockout (adipo-TFAM-KO) mice had a 75-81% reduction in TFAM in the subcutaneous and intra-abdominal white adipose tissue (WAT) and interscapular brown adipose tissue (BAT), causing decreased expression and enzymatic activity of proteins in complexes I, III, and IV of the electron transport chain (ETC). This mitochondrial dysfunction led to adipocyte death and inflammation in WAT and a whitening of BAT. As a result, adipo-TFAM-KO mice were resistant to weight gain, but exhibited insulin resistance on both normal chow and high-fat diets. These lipodystrophic mice also developed hypertension, cardiac hypertrophy, and cardiac dysfunction. Thus, isolated mitochondrial dysfunction in adipose tissue can lead a syndrome of lipodystrophy with metabolic syndrome and cardiovascular complications.
Thrailkill, Kathryn, Clay Bunn, Charles Lumpkin, Elizabeth Wahl, Gael Cockrell, Lindsey Morris, Ronald Kahn, John Fowlkes, and Jeffry Nyman. (2014) 2014. “Loss of Insulin Receptor in Osteoprogenitor Cells Impairs Structural Strength of Bone”. J Diabetes Res 2014: 703589. https://doi.org/10.1155/2014/703589.
Type 1 diabetes mellitus (T1D) is associated with decreased bone mineral density, a deficit in bone structure, and subsequently an increased risk of fragility fracture. These clinical observations, paralleled by animal models of T1D, suggest that the insulinopenia of T1D has a deleterious effect on bone. To further examine the action of insulin signaling on bone development, we generated mice with an osteoprogenitor-selective (osterix-Cre) ablation of the insulin receptor (IR), designated OIRKO. OIRKO mice exhibited an 80% decrease in IR in osteoblasts. Prenatal elimination of IR did not affect fetal survival or gross morphology. However, loss of IR in mouse osteoblasts resulted in a postnatal growth-constricted phenotype. By 10-12 weeks of age, femurs of OIRKO mice were more slender, with a thinner diaphyseal cortex and, consequently, a decrease in whole bone strength when subjected to bending. In male mice alone, decreased metaphyseal trabecular bone, with thinner and more rodlike trabeculae, was also observed. OIRKO mice did not, however, exhibit abnormal glucose tolerance. The skeletal phenotype of the OIRKO mouse appeared more severe than that of previously reported bone-specific IR knockdown models, and confirms that insulin receptor expression in osteoblasts is critically important for proper bone development and maintenance of structural integrity.
Kleinridders, Andre, Heather Ferris, Weikang Cai, and Ronald Kahn. (2014) 2014. “Insulin Action in Brain Regulates Systemic Metabolism and Brain Function”. Diabetes 63 (7): 2232-43. https://doi.org/10.2337/db14-0568.
Insulin receptors, as well as IGF-1 receptors and their postreceptor signaling partners, are distributed throughout the brain. Insulin acts on these receptors to modulate peripheral metabolism, including regulation of appetite, reproductive function, body temperature, white fat mass, hepatic glucose output, and response to hypoglycemia. Insulin signaling also modulates neurotransmitter channel activity, brain cholesterol synthesis, and mitochondrial function. Disruption of insulin action in the brain leads to impairment of neuronal function and synaptogenesis. In addition, insulin signaling modulates phosphorylation of tau protein, an early component in the development of Alzheimer disease. Thus, alterations in insulin action in the brain can contribute to metabolic syndrome, and the development of mood disorders and neurodegenerative diseases.
Mori, Marcelo, Thomas Thomou, Jeremie Boucher, Kevin Lee, Susanna Lallukka, Jason Kim, Martin Torriani, et al. (2014) 2014. “Altered MiRNA Processing Disrupts Brown/White Adipocyte Determination and Associates With Lipodystrophy”. J Clin Invest 124 (8): 3339-51. https://doi.org/10.1172/JCI73468.
miRNAs are important regulators of biological processes in many tissues, including the differentiation and function of brown and white adipocytes. The endoribonuclease dicer is a major component of the miRNA-processing pathway, and in adipose tissue, levels of dicer have been shown to decrease with age, increase with caloric restriction, and influence stress resistance. Here, we demonstrated that mice with a fat-specific KO of dicer develop a form of lipodystrophy that is characterized by loss of intra-abdominal and subcutaneous white fat, severe insulin resistance, and enlargement and "whitening" of interscapular brown fat. Additionally, KO of dicer in cultured brown preadipocytes promoted a white adipocyte-like phenotype and reduced expression of several miRNAs. Brown preadipocyte whitening was partially reversed by expression of miR-365, a miRNA known to promote brown fat differentiation; however, introduction of other miRNAs, including miR-346 and miR-362, also contributed to reversal of the loss of the dicer phenotype. Interestingly, fat samples from patients with HIV-related lipodystrophy exhibited a substantial downregulation of dicer mRNA expression. Together, these findings indicate the importance of miRNA processing in white and brown adipose tissue determination and provide a potential link between this process and HIV-related lipodystrophy.