Publications

2001

Saltiel, and Kahn. 2001. “Insulin Signalling and the Regulation of Glucose and Lipid Metabolism”. Nature 414 (6865): 799-806. https://doi.org/10.1038/414799a.
The epidemic of type 2 diabetes and impaired glucose tolerance is one of the main causes of morbidity and mortality worldwide. In both disorders, tissues such as muscle, fat and liver become less responsive or resistant to insulin. This state is also linked to other common health problems, such as obesity, polycystic ovarian disease, hyperlipidaemia, hypertension and atherosclerosis. The pathophysiology of insulin resistance involves a complex network of signalling pathways, activated by the insulin receptor, which regulates intermediary metabolism and its organization in cells. But recent studies have shown that numerous other hormones and signalling events attenuate insulin action, and are important in type 2 diabetes.
Guerra, Navarro, Valverde, Arribas, Brüning, Kozak, Kahn, and Benito. (2001) 2001. “Brown Adipose Tissue-Specific Insulin Receptor Knockout Shows Diabetic Phenotype Without Insulin Resistance”. J Clin Invest 108 (8): 1205-13. https://doi.org/10.1172/JCI13103.
Although insulin regulates metabolism in both brown and white adipocytes, the role of these tissues in energy storage and utilization is quite different. Recombination technology using the Cre-loxP approach allows inactivation of the insulin receptor in a tissue-specific manner. Mice lacking insulin receptors in brown adipocytes show an age-dependent loss of interscapular brown fat but increased expression of uncoupling protein-1 and -2. In parallel, these mice develop an insulin-secretion defect resulting in a progressive glucose intolerance, without insulin resistance. This model provides direct evidence for not only a role for the insulin receptors in brown fat adipogenesis, the data also suggest a novel role of brown adipose tissue in the regulation of insulin secretion and glucose homeostasis.
Yoon, Puigserver, Chen, Donovan, Wu, Rhee, Adelmant, et al. 2001. “Control of Hepatic Gluconeogenesis through the Transcriptional Coactivator PGC-1”. Nature 413 (6852): 131-8. https://doi.org/10.1038/35093050.
Blood glucose levels are maintained by the balance between glucose uptake by peripheral tissues and glucose secretion by the liver. Gluconeogenesis is strongly stimulated during fasting and is aberrantly activated in diabetes mellitus. Here we show that the transcriptional coactivator PGC-1 is strongly induced in liver in fasting mice and in three mouse models of insulin action deficiency: streptozotocin-induced diabetes, ob/ob genotype and liver insulin-receptor knockout. PGC-1 is induced synergistically in primary liver cultures by cyclic AMP and glucocorticoids. Adenoviral-mediated expression of PGC-1 in hepatocytes in culture or in vivo strongly activates an entire programme of key gluconeogenic enzymes, including phosphoenolpyruvate carboxykinase (PEPCK) and glucose-6-phosphatase, leading to increased glucose output. Full transcriptional activation of the PEPCK promoter requires coactivation of the glucocorticoid receptor and the liver-enriched transcription factor HNF-4alpha (hepatic nuclear factor-4alpha) by PGC-1. These results implicate PGC-1 as a key modulator of hepatic gluconeogenesis and as a central target of the insulin-cAMP axis in liver.
Magré, Delépine, Khallouf, Gedde-Dahl, Van Maldergem, Sobel, Papp, et al. (2001) 2001. “Identification of the Gene Altered in Berardinelli-Seip Congenital Lipodystrophy on Chromosome 11q13”. Nat Genet 28 (4): 365-70. https://doi.org/10.1038/ng585.
Congenital generalized lipodystrophy, or Berardinelli-Seip syndrome (BSCL), is a rare autosomal recessive disease characterized by a near-absence of adipose tissue from birth or early infancy and severe insulin resistance. Other clinical and biological features include acanthosis nigricans, hyperandrogenism, muscular hypertrophy, hepatomegaly, altered glucose tolerance or diabetes mellitus, and hypertriglyceridemia. A locus (BSCL1) has been mapped to 9q34 with evidence of heterogeneity. Here, we report a genome screen of nine BSCL families from two geographical clusters (in Lebanon and Norway). We identified a new disease locus, designated BSCL2, within the 2.5-Mb interval flanked by markers D11S4076 and D11S480 on chromosome 11q13. Analysis of 20 additional families of various ethnic origins led to the identification of 11 families in which the disease cosegregates with the 11q13 locus; the remaining families provide confirmation of linkage to 9q34. Sequence analysis of genes located in the 11q13 interval disclosed mutations in a gene homologous to the murine guanine nucleotide-binding protein (G protein), gamma3-linked gene (Gng3lg) in all BSCL2-linked families. BSCL2 is most highly expressed in brain and testis and encodes a protein (which we have called seipin) of unknown function. Most of the variants are null mutations and probably result in a severe disruption of the protein. These findings are of general importance for understanding the molecular mechanisms underlying regulation of body fat distribution and insulin resistance.
Leibiger, Leibiger, Moede, Kemper, Kulkarni, Kahn, Vargas, and Berggren. (2001) 2001. “Selective Insulin Signaling through A and B Insulin Receptors Regulates Transcription of Insulin and Glucokinase Genes in Pancreatic Beta Cells”. Mol Cell 7 (3): 559-70.
Insulin signaling is mediated by a complex network of diverging and converging pathways, with alternative proteins and isoforms at almost every step in the process. We show here that insulin activates the transcription of its own gene and that of the beta cell glucokinase gene (betaGK) by different mechanisms. Whereas insulin gene transcription is promoted by signaling through insulin receptor A type (Ex11-), PI3K class Ia, and p70s6k, insulin stimulates the betaGK gene by signaling via insulin receptor B type (Ex11+), PI3K class II-like activity, and PKB (c-Akt). Our data provide evidence for selectivity in insulin action via the two isoforms of the insulin receptor, the molecular basis being preferential signaling through different PI3K and protein kinases.
Kim, Zisman, Fillmore, Peroni, Kotani, Perret, Zong, et al. (2001) 2001. “Glucose Toxicity and the Development of Diabetes in Mice With Muscle-Specific Inactivation of GLUT4”. J Clin Invest 108 (1): 153-60. https://doi.org/10.1172/JCI10294.
Using cre/loxP gene targeting, transgenic mice with muscle-specific inactivation of the GLUT4 gene (muscle GLUT4 KO) were generated and shown to develop a diabetes phenotype. To determine the mechanism, we examined insulin-stimulated glucose uptake and metabolism during hyperinsulinemic-euglycemic clamp in control and muscle GLUT4 KO mice before and after development of diabetes. Insulin-stimulated whole body glucose uptake was decreased by 55% in muscle GLUT4 KO mice, an effect that could be attributed to a 92% decrease in insulin-stimulated muscle glucose uptake. Surprisingly, insulin's ability to stimulate adipose tissue glucose uptake and suppress hepatic glucose production was significantly impaired in muscle GLUT4 KO mice. To address whether these latter changes were caused by glucose toxicity, we treated muscle GLUT4 KO mice with phloridzin to prevent hyperglycemia and found that insulin-stimulated whole body and skeletal muscle glucose uptake were decreased substantially, whereas insulin-stimulated glucose uptake in adipose tissue and suppression of hepatic glucose production were normal after phloridzin treatment. In conclusion, these findings demonstrate that a primary defect in muscle glucose transport can lead to secondary defects in insulin action in adipose tissue and liver due to glucose toxicity. These secondary defects contribute to insulin resistance and to the development of diabetes.

2000

Kahn, Brüning, Michael, and Kulkarni. (2000) 2000. “Knockout Mice Challenge Our Concepts of Glucose Homeostasis and the Pathogenesis of Diabetes Mellitus”. J Pediatr Endocrinol Metab 13 Suppl 6: 1377-84.
The failure of insulin to stimulate muscle glucose uptake and suppress hepatic glucose production represents two of the fundamental pathophysiologic lesions in type 2 diabetes mellitus (DM). Defining insulin action at the molecular level, therefore, provides the critical background against which to elucidate the mechanisms of insulin resistance that underlie type 2 DM, obesity and many other disorders. Over the past two decades substantial progress has been made in identifying many of the molecular mechanisms involved in insulin signaling. Much of this progress has been due to the use of homologous recombinant gene targeting. The present review examines the various insights that have been provided by studies of knockout mice strains. Taken together, the results present the possibility of a unifying hypothesis for type 2 DM, in which insulin resistance in the beta-cell synergizes with insulin resistance in the periphery to produce the two classic defects of this disease: relative hypoinsulinemia and peripheral insulin resistance.
The development of type 2 diabetes is linked to insulin resistance coupled with a failure of pancreatic B-cells to compensate by adequate insulin secretion. Here, we review studies obtained from genetically engineered mice that have helped dissect the pathophysiology of this disease. Transgenic/knockout models with monogenic impairment in insulin action and insulin secretion have highlighted potential molecular mechanisms for insulin resistance and suggested a mechanism for the development of MODY in humans. Polygenic models have strengthened the idea that minor defects in insulin secretion and insulin action, when combined, can lead to diabetes, pointing out the importance of interactions of different genetic loci in the production of diabetes. Tissue-specific knockouts of the insulin receptor have challenged current concepts on the regulation of glucose homeostasis and have highlighted the importance of insulin action in pancreatic B-cells and brain. The impact of the genetic background on insulin action, insulin secretion and the incidence of diabetes is also evident in these models. These findings highlight potential new therapeutic targets in the treatment of type 2 diabetes.
Mauvais-Jarvis, Virkamaki, Michael, Winnay, Zisman, Kulkarni, and Kahn. (2000) 2000. “A Model to Explore the Interaction Between Muscle Insulin Resistance and Beta-Cell Dysfunction in the Development of Type 2 Diabetes”. Diabetes 49 (12): 2126-34.
Type 2 diabetes is a polygenic disease characterized by defects in both insulin secretion and insulin action. We have previously reported that isolated insulin resistance in muscle by a tissue-specific insulin receptor knockout (MIRKO mouse) is not sufficient to alter glucose homeostasis, whereas beta-cell-specific insulin receptor knockout (betaIRKO) mice manifest severe progressive glucose intolerance due to loss of glucose-stimulated acute-phase insulin release. To explore the interaction between insulin resistance in muscle and altered insulin secretion, we created a double tissue-specific insulin receptor knockout in these tissues. Surprisingly, betaIRKO-MIRKO mice show an improvement rather than a deterioration of glucose tolerance when compared to betaIRKO mice. This is due to improved glucose-stimulated acute insulin release and redistribution of substrates with increased glucose uptake in adipose tissue and liver in vivo, without a significant decrease in muscle glucose uptake. Thus, insulin resistance in muscle leads to improved glucose-stimulated first-phase insulin secretion from beta-cells and shunting of substrates to nonmuscle tissues, collectively leading to improved glucose tolerance. These data suggest that muscle, either via changes in substrate availability or by acting as an endocrine tissue, communicates with and regulates insulin sensitivity in other tissues.