HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

J. Biol. Chem., Vol. 278, Issue 36, 33609-33612, September 5, 2003

This Article Full Text (PDF) Supplemental Data All Versions of this Article: 278/36/33609    most recent R300019200v1 Submit a Letter to Editor Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Minokoshi, Y. Articles by Kahn, B. B. Search for Related Content PubMed PubMed Citation Articles by Minokoshi, Y. Articles by Kahn, B. B. Social Bookmarking                      What's this?

Minireview

Tissue-specific Ablation of the GLUT4 Glucose Transporter or the Insulin Receptor Challenges Assumptions about Insulin Action and Glucose Homeostasis^*,

Yasuhiko Minokoshi , C. Ronald Kahn  and Barbara B. Kahn  ¶

From the Division of Endocrinology, Diabetes and Metabolism, Beth Israel Deaconess Medical Center and Department of Medicine, and Joslin Diabetes Center and Department of Medicine, Harvard Medical School, Boston, Massachusetts 02215

	INTRODUCTION

TOP INTRODUCTION Muscle-specific GLUT4-/- Mouse Muscle-specific Insulin... Adipocyte-specific GLUT4-/-... Adipocyte-specific Insulin... Conclusions REFERENCES

 
The prevalence of type 2 diabetes mellitus is growing worldwide. Most forms of type 2 diabetes are polygenic with complex inheritance patterns strongly influenced by environmental factors. The specific gene defects are unknown, but they affect both insulin action and insulin secretion. Glucose homeostasis is maintained by the fine orchestration of insulin secretion and insulin action to promote glucose transport into muscle and adipocytes and to inhibit hepatic glucose output. Resistance to these effects of insulin is a classic pathogenic feature of obesity and type 2 diabetes. Insulin action on lipid metabolism also has important effects on glucose homeostasis. Recent studies using tissue-specific gene targeting of the GLUT4 glucose transporter or the insulin receptor in mice reveal intercommunication among insulin target tissues which can modify the impact of genetic defects in individual tissues. These studies provide new concepts regarding the importance of adipose tissue versus muscle in whole-body insulin sensitivity and the role of proximal versus distal components of the insulin action cascade in the pathogenesis of obesity and type 2 diabetes.

The insulin receptor (IR)¹ is present in virtually all mammalian cells, and insulin binding results in activation of several phosphorylation-dephosphorylation cascades (1). The phosphoinositide 3-kinase cascade is necessary, albeit insufficient, for stimulation of glucose transport, and the mitogen-activated protein kinase cascade underlies the mitogenic effects of insulin. These insulin signaling cascades have pleiotrophic metabolic and growth-promoting effects (see Fig. 1 in Supplemental Material).

Insulin stimulation of glucose transport in muscle and adipose cells is essential for maintenance of glucose homeostasis. This is mediated by sodium-independent, facilitated-diffusion glucose transporters (GLUTs). In tissues with insulin-sensitive glucose transport (i.e. skeletal and cardiac muscle and adipose cells), GLUT4 is the predominant glucose transporter and GLUT1 plays a minor role. The large stimulatory effect of insulin in these tissues results from the translocation of GLUT4-containing vesicles from intracellular storage sites to the plasma membrane where they dock and fuse with the membrane (2, 3), markedly augmenting glucose transport into the cell.

GLUT4 is present primarily in white and brown adipocytes, skeletal muscle, and cardiac muscle, with expression in discrete areas of other tissues (e.g. brain and kidney) that are not traditionally thought to play a major role in glucose homeostasis (4). In insulin-resistant states including obesity and type 2 diabetes, GLUT4 expression is reduced in adipocytes but not in skeletal muscle (4, 5). This down-regulation in adipocytes was not thought to be important because skeletal muscle accounts for up to 85% of glucose disposal following a glucose infusion (6) and at least 50% following glucose ingestion (7), whereas adipose tissue accounts for much less. Glucose transport is the rate-controlling step in skeletal-muscle glucose metabolism in normal and type 2 diabetic subjects (8). Impaired glucose uptake in skeletal muscle is present even in non-diabetic relatives of type 2 diabetic subjects and is a risk factor for developing diabetes (9, 10). Defects in GLUT4 trafficking or function in skeletal muscle are thought to be most important in the development of insulin resistance.

To understand the role of IR and GLUT4 in glucose homeostasis, mice were engineered to destroy the function of these genes. Genetic ablation of IR in all tissues results in lethality at 4–5 days after birth due to severe diabetic ketoacidosis (11). When GLUT4 is "knocked out" of all tissues (GLUT4-null), mice are growth-retarded, with markedly reduced fat mass, cardiomegaly, and shortened lifespan but no diabetes (12). In contrast, at least 50% of heterozygous GLUT4-null mice developed diabetes by 6 months of age (13). Hence, to distinguish the role of the insulin receptor and GLUT4 in adipose tissue and muscle in glucose homeostasis, diabetes, and adiposity, tissue-specific knock-out mice were made using Cre/loxP gene targeting (14). These mice challenge long held concepts about the control of glucose homeostasis (Fig. 1).

View larger version (42K): [in this window] [in a new window]   FIG. 1. Changes in glucose homeostasis and adiposity with muscle-specific or adipose-specific ablation of GLUT4 or IR. A, muscle-G4KO mouse. Ablation of GLUT4 from muscle (green box) decreases both insulin- and exercise-induced glucose uptake in muscle resulting in hyperglycemia, hyperinsulinemia, and secondary insulin resistance in the liver and adipose tissue. Insulin resistance in the liver and adipose tissue may be caused, at least partly, by glucose toxicity (red curves) (see text). B, muscle-IRKO (or MIRKO) mouse. Ablation of IR in muscle (green box) decreases muscle mass but does not change plasma glucose or insulin levels or glucose tolerance. Contraction-stimulated glucose uptake remains normal. Increased glucose uptake into adipose tissue increases adipose mass, serum triglycerides, and free fatty acids. Whether muscle releases a factor that directly acts on adipose tissue is unknown (blue curve). C, adipose-G4KO mouse. Ablation of GLUT4 in adipose tissue (green box) does not alter adipose mass, but results in insulin resistance in liver and muscle and systemic hyperinsulinemia. This is most likely due to altered secretion of an unknown molecule(s) from adipose tissue (red curves). Blood glucose is increased in some of the adipose-G4KO mice (symbol ±). D, adipose-IRKO (or FIRKO) mouse. In contrast to the adipose-G4KO mouse, ablation of IR in adipose tissue (green box) decreases adipose mass, unmasks adipocyte heterogeneity, lowers fasting insulin levels, and may increase energy expenditure. This may, in part, be driven by changes in adipocyte-secreted molecules (blue arrow). Red, insulin resistance; blue, insulin action or sensitivity.

	Muscle-specific GLUT4–/– Mouse

TOP INTRODUCTION Muscle-specific GLUT4-/- Mouse Muscle-specific Insulin... Adipocyte-specific GLUT4-/-... Adipocyte-specific Insulin... Conclusions REFERENCES

 
Muscle-specific GLUT4 knock-out mice (muscle-G4KO) were made by breeding mice carrying the GLUT4 gene with exon 10 flanked by loxP sites to mice carrying a transgene encoding the Cre recombinase enzyme under the control of the muscle creatine kinase promoter/enhancer (15). GLUT4 protein levels were reduced about 95% in all skeletal muscles and heart. GLUT1 protein levels were normal in skeletal muscle but were increased by 1.5–2-fold in hearts of muscle-G4KO mice. An even greater induction of cardiac GLUT1 expression was seen in GLUT4-null mice (12) and in mice with cardiac-specific GLUT4 knock-out (cardiac-G4KO) (16).

In contrast to GLUT4-null mice (12), muscle-G4KO mice have normal body weight and fat pad weight at least until 6 months of age. Skeletal muscle mass is also normal. Heart weight is increased, consistent with GLUT4-null mice (12) and cardiac-G4KO mice (16). Lifespan is normal in muscle-G4KO mice in contrast to the shortened lifespan in GLUT4-null mice.

Ex vivo, basal, insulin-stimulated, and contraction-stimulated glucose transport are markedly reduced in both slow twitch, oxidative and fast twitch, glycolytic muscles of muscle-G4KO mice. These mice have hyperglycemia, glucose intolerance, and insulin resistance as early as 8 weeks of age, which persists for up to 1 year of age (15). A subset of mice have frank diabetes with severe insulin resistance. Muscle-G4KO mice do not develop dyslipidemia or other aspects of the metabolic syndrome, in contrast to mice with muscle-specific insulin receptor knock-out (muscle-IRKO, also MIRKO (17)) (see below).

Insulin-stimulated glucose transport in muscle in vivo is markedly reduced in muscle-G4KO mice (18). Surprisingly, insulin-stimulated glucose transport in adipose tissue and suppression of hepatic glucose production by insulin are also impaired. The effects in adipose tissue and liver appear to be at least partly due to glucose toxicity because phloridzin treatment, which normalizes blood glucose in diabetic animals by increasing glucose excretion by the kidney, normalized insulin action in adipose tissue and liver of muscle-G4KO mice (18). In muscle-G4KO and GLUT4-null mice, glucose uptake by the liver may partially compensate for impaired glucose uptake in muscle and other tissues (12, 15).

Why Is the Defect in Glucose Homeostasis in Muscle-G4KO Mice More Severe than in the Homozygous, Whole-body GLUT4-null Mice?—This may reflect differences in the developmental stage at which GLUT4 is deleted or in genetic background. Alternatively, the absence of GLUT4 from discrete regions of the brain, kidney, and other tissues may modify the phenotype in GLUT4-null mice. Additionally, the negative nutritional balance in GLUT4-null mice may prevent the emergence of diabetic features.

Heterozygous GLUT4^+/–-null mice become more diabetic than GLUT4-null mice (13). Moreover, diabetes is averted when GLUT4 expression is restored specifically in muscle of GLUT4^+/– mice (19), confirming the importance of GLUT4 in muscle to maintain glucose homeostasis. Transgenic overexpression of GLUT1 in skeletal muscle also increases basal glucose uptake and muscle glycogen synthesis but insulin-mediated glucose uptake is impaired (20, 21).

Effects of GLUT4 Ablation on the Heart—Muscle-G4KO, cardiac-G4KO, and GLUT4-null mice all develop cardiac hypertrophy. GLUT4-null homozygous (22) and heterozygous (13) mice show cardiac dysfunction under normal conditions. In contrast, cardiac-G4KO mice have normal contractile function under basal conditions (16) but decreased recovery after hypoxia (23). The increase in GLUT1 expression in the heart of these models clearly cannot compensate for the absence of GLUT4 suggesting that GLUT4 is essential for normal cardiac function at least under some conditions. Furthermore, cardiac-G4KO mice are normal metabolically, thus eliminating the possibility that hyperinsulinemia or other metabolic abnormalities play a major etiologic role in the cardiac hypertrophy. In GLUT4-null mice, however, metabolic abnormalities including alterations in cardiac substrate availability may contribute to impaired cardiac function.

	Muscle-specific Insulin Receptor–/– Mouse

TOP INTRODUCTION Muscle-specific GLUT4-/- Mouse Muscle-specific Insulin... Adipocyte-specific GLUT4-/-... Adipocyte-specific Insulin... Conclusions REFERENCES

 
Muscle-IRKO (also MIRKO (17)), created by breeding mice with exon 4 of the insulin receptor flanked by loxP sites to the muscle creatine kinase-Cre mice, exhibit a muscle-specific >95% reduction in insulin receptor content and early insulin signaling events (17). Insulin-stimulated glucose uptake and activation of glycogen synthase in muscle in vivo and in vitro are severely impaired. Despite this, muscle glycogen content is relatively normal or only mildly decreased. Unexpectedly, muscle-IRKO mice show no alteration in glucose tolerance in the awake state, and they maintain euglycemia for at least the first 11 months of life (17). Moreover, plasma insulin concentrations and the blood glucose lowering effect of exogenous insulin are normal. These data sharply contrast with the insulin resistance and glucose intolerance in muscle-G4KO (above) and adipose-G4KO mice (below). Euglycemic clamp studies reveal insulin resistance in muscle-IRKO mice (24), but this is not evident under ambient conditions (17).

In contrast to muscle-G4KO mice, muscle-IRKO mice have features of "the metabolic syndrome" including increased fat mass, serum triglycerides, and serum free fatty acids (Table I) (17). Glucose uptake in adipose tissue in vivo is increased 3-fold in muscle-IRKO mice whereas glucose uptake in adipocytes is normal in vitro (24). This in vivo repartitioning of glucose from muscle to adipose tissue suggests that impairment of insulin signaling in muscle, but not impairment of glucose uptake per se, can lead to altered adipose insulin sensitivity, increased adiposity, and abnormal plasma lipid profiles. This phenomenon illustrates that tissue "cross-talk" occurs when insulin action is impaired in one insulin target tissue. Interestingly, muscle-IRKO mice and cardiac-specific IRKO mice (25) have decreased cardiac size in contrast to the cardiac hypertrophy when GLUT4 is absent from the heart.

The data suggest that insulin signaling through its cognate receptor in muscle is not essential for the maintenance of glucose disposal in mice (17). The glucose intolerance in muscle-G4KO mice (15), but not in muscle-IRKO mice, suggests that insulin-independent glucose uptake contributes importantly to the maintenance of glucose homeostasis. Unlike mice with muscle-G4KO, mice with muscle-IRKO retain normal basal and contraction-stimulated glucose transport (26). Indeed, muscle-IRKO mice display normal exercise-stimulated glucose uptake and a normal synergistic action of exercise plus insulin on muscle glucose uptake. In contrast, contraction-induced glucose uptake is severely impaired in muscle-G4KO mice (15). Therefore, contraction of postural muscles and other forms of physical activity that elicit non-insulin-dependent glucose uptake could contribute to the maintenance of glucose tolerance in muscle-IRKO mice.

In addition, signaling through the insulin-like growth factor-1 (IGF-1) receptor in muscle may become important when IR is absent. Interference with both IR and IGF-1 receptor signaling with a dominant-negative IGF-1 receptor expressed in muscle leads to insulin resistance and type 2 diabetes (27), and deletion of the IGF-1 gene leads to severe muscle insulin resistance (28).

	Adipocyte-specific GLUT4–/– Mouse

TOP INTRODUCTION Muscle-specific GLUT4-/- Mouse Muscle-specific Insulin... Adipocyte-specific GLUT4-/-... Adipocyte-specific Insulin... Conclusions REFERENCES

 
Adipose-G4KO mice were made by crossing mice carrying the "floxed" GLUT4 allele with transgenic mice expressing Cre recombinase driven by the adipose-specific fatty acid binding protein (aP2) promoter/enhancer (29). GLUT4 protein levels were reduced by 70–99% in both brown and white adipose tissue whereas GLUT4 levels were preserved in skeletal muscle and heart. In adipocytes from adipose-G4KO mice, basal glucose uptake tends to be reduced, and insulin-stimulated glucose uptake is markedly blunted. Unlike the global GLUT4-null mice (12), reduction of GLUT4 selectively in adipose tissue does not result in growth retardation or decreased adipose mass or adipocyte size (29). The latter suggests that the small amount of glucose transported by GLUT1 in adipocytes may be adequate for the formation of glycerol 3-phosphate required for triglyceride synthesis. Heart weight is also normal in adipose-G4KO mice in contrast to the cardiomegaly observed in GLUT4-null mice and in cardiac-specific (16) and muscle-specific (15) G4KO mice.

Although white adipose tissue accounts for less than 10% of whole-body glucose uptake (30), adipose-G4KO mice have insulin resistance and glucose intolerance, and a subset of these mice develops extreme insulin resistance and diabetes. The range in severity of the phenotype is expected when studying outbred strains with a mixture of genetic modifiers. Hyperinsulinemic/euglycemic clamp studies reveal an 50% reduction in whole-body glucose uptake in adipose-G4KO mice. As expected, insulin-stimulated 2-deoxyglucose uptake into white and brown adipose in vivo is markedly reduced. However, unexpectedly, glucose uptake into skeletal muscle in vivo is also impaired despite preserved GLUT4 expression in muscle. As basal and insulin-stimulated glucose uptake are normal in muscle from these mice ex vivo, it appears that this defect is secondary to the in vivo milieu. Furthermore, in addition to the insulin resistance in muscle, the insulin-induced suppression of hepatic glucose production is impaired in adipose-G4KO mice. Insulin-stimulated activation of phosphoinositide 3-kinase is impaired in muscle and liver of adipose-G4KO mice in vivo (29) and could contribute to the defective insulin responses in these tissues.

These data suggest that reduction of insulin-stimulated glucose transport in adipocytes secondarily induces insulin resistance in other insulin target tissues. Adipocytes can indirectly regulate insulin action and substrate metabolism in muscle and liver and insulin secretion from pancreatic -cells by altered release of free fatty acids, leptin, tumor necrosis factor-, resistin, and adiponectin (31, 32). However, serum levels of these molecules are not altered in adipose-G4KO mice (Table I) (29).² Insulin resistance also occurs by increasing lipid depots in muscle and liver, but these were not increased in adipose-G4KO mice. Thus, the insulin resistance in muscle and liver of adipose-G4KO mice is likely to be caused by altered secretion of an as yet unidentified adipocyte-derived molecule that affects insulin action in other tissues (Fig. 1). Additional evidence for a "systemic impact" of adipose-GLUT4 is the fact that adipose-specific overexpression of GLUT4 results in enhanced glucose disposal and insulin sensitivity in vivo (33).

	Adipocyte-specific Insulin Receptor–/– Mouse

TOP INTRODUCTION Muscle-specific GLUT4-/- Mouse Muscle-specific Insulin... Adipocyte-specific GLUT4-/-... Adipocyte-specific Insulin... Conclusions REFERENCES

 
Adipocyte-specific insulin receptor knock-out (adipose-IRKO, also FIRKO (34)) mice were generated by breeding insulin receptor-floxed mice (17) with transgenic mice that express Cre recombinase driven by the aP2 promoter/enhancer. Whereas basal glucose uptake in adipocytes from adipose-IRKO mice is unchanged, insulin-stimulated glucose uptake is reduced by 90% (34). Insulin also failed to stimulate glucose metabolism or suppress lipolysis in these adipocytes. Growth is normal in adipose-IRKO mice up to 4 weeks of age. By 8 weeks, however, these mice gained less weight than controls. In contrast to adipose-G4KO mice that have normal adipose mass, adipose-IRKO mice have reduced white adipose and brown adipose tissue mass and whole-body triglyceride content (34).

Blood glucose concentrations were not altered in adipose-IRKO mice at 2–8 months, but fasting plasma insulin concentrations were lower suggesting increased insulin sensitivity (Table I). Serum triglyceride levels were also reduced. Glucose and insulin tolerance tests were normal at 2 and 10 months of age, whereas control mice showed age-related glucose intolerance and insulin resistance. Thus, adipose-IRKO mice are protected against age-related glucose intolerance as well as obesity.

Serum adiponectin concentration was increased in adipose-IRKO mice. Furthermore, plasma leptin levels expressed per mg of fat pad were 3-fold elevated, and the linear relationship between leptin levels and body weight seen in normal mice was lost. Leptin protein levels were normal in adipose tissue of adipose-IRKO mice. Thus, the absence of IR in adipose tissue alters leptin and adiponectin synthesis, secretion, or clearance.

Adipose-IRKO Mice Are Resistant to Obesity—Mice were injected with gold thioglucose (GTG), which ablates glucose-sensing neurons in the ventromedial hypothalamus. GTG treatment increased food intake in both adipose-IRKO and control mice (34), and as previously observed, control mice treated with GTG became obese. Despite hyperphagia, adipose-IRKO mice did not develop obesity, diabetes, or steatosis in contrast to GTG-injected controls. Thus, adipose-IRKO protects against GTG-induced, as well as age-related, obesity and obesity-related diabetes, and insulin resistance. The protection from obesity could be explained by the lack of the lipogenic and anti-lipolytic effects of insulin in adipocytes. However, it is also likely that energy expenditure is enhanced, because adipose IRKO mice are lean despite hyperphagia.

The reduced adipose mass in adipose-IRKO mice is not due to fewer adipocytes. Histology showed polarization of adipocytes into small and large in contrast to a normal distribution in control mice (34). IR expression in both large and small adipocytes of adipose-IRKO mice is reduced by 85–99%, indicating that the heterogeneity is not due to differences in efficiency of gene recombination. However, expression levels of some proteins, e.g. fatty-acid synthase and the adipogenic transcription factors SREBP-1 and C/EBP, are different in small and large adipocytes, and this may contribute to the heterogeneity.

In contrast to adipose-IRKO mice, brown adipocyte-specific insulin receptor knock-out (BAT-IRKO) mice exhibit an age-dependent loss of brown adipose tissue that is associated with impaired glucose tolerance without insulin resistance (35). This appears to be primarily due to loss of -cell mass and defective insulin secretion. Thus, absence of IR in white adipose tissue has a protective effect over the impaired glucose homeostasis resulting from the absence of IR in brown adipose tissue alone. In addition, brown adipose tissue may affect pancreatic -cell mass and function.

Adipose-IRKO Mice Have Enhanced Longevity—Surprisingly, mean lifespan in adipose-IRKO mice is increased by 134 days (18%) (36) in contrast to the shortened lifespan in GLUT4-null mice. Calorie restriction in many species is associated with increased longevity, but it has not been clear whether this is due to decreased food intake or the resultant leanness. Because adipose-IRKO mice do not eat less, the effect of calorie restriction on longevity is likely to be due to reduced adipose mass per se. Combined with data showing that decreased signaling through an insulin-like pathway increases longevity in Caenorhabditis elegans and Drosophila melanogaster (37), these new data imply that selective reduction of insulin signaling in certain metabolically important organs such as adipose tissue could result in extended longevity (36).

	Conclusions

TOP INTRODUCTION Muscle-specific GLUT4-/- Mouse Muscle-specific Insulin... Adipocyte-specific GLUT4-/-... Adipocyte-specific Insulin... Conclusions REFERENCES

 
Tissue-conditional knock-out mice advance our understanding of the mechanisms underlying insulin resistance. Marked reduction of GLUT4 in muscle or adipose tissue causes insulin resistance in other insulin target tissues secondarily and increases the risk for diabetes. Hence, there is cross-talk among insulin target tissues. This may have implications for the genetics of type 2 diabetes because a single genetic defect in one insulin target tissue can result in insulin resistance in other tissues, leading to type 2 diabetes. This may explain, at least in part, the surprising finding that reduction of GLUT4 in adipose tissue causes a similar degree of insulin resistance as reduction of GLUT4 in muscle. In contrast, ablation of IR in adipose tissue or muscle has only a subtle direct impact on glucose homeostasis, possibly due to compensation by IGF-1 receptor signaling and by insulin-independent stimulation of glucose transport by contraction. However, IR in both muscle and adipose tissue is critical for the regulation of adiposity.

These models demonstrate a central role for adipose tissue as an endocrine organ in the maintenance of insulin sensitivity and energy balance. The importance of GLUT4 in adipose tissue is particularly relevant in light of selective reduction of adipocyte-GLUT4 expression in obesity and diabetes (4, 5). Data from adipose-G4KO mice indicate that this could contribute to the pathogenesis of insulin resistance in obesity and diabetes, probably by altering the release of novel adipocyte-secreted molecules. Thus, studies using tissue-conditional knock-outs reveal the complexity of glucose homeostasis and suggest that "inter-tissue communication" can modify the impact of specific genetic defects in individual tissues on the pathogenesis of obesity and type 2 diabetes.

	FOOTNOTES

 
^* This minireview will be reprinted in the 2003 Minireview Compendium, which will be available in January, 2004. This work was supported by National Institutes of Health R01 Grants DK43051 and DK33201. This is the sixth article of six in the "New Animal Models for Study of Metabolism" Minireview Series.

The on-line version of this article (available at http://www.jbc.org) contains a supplemental figure.

^¶ To whom correspondence should be addressed: Endocrine Division-Research North 325E, Beth Israel Deaconess Medical Center, 99 Brookline Ave., Boston, MA 02215. Tel.: 617-667-5422; Fax: 617-667-2927; E-mail: bkahn{at}caregroup.harvard.edu.

¹ The abbreviations used are: IR, insulin receptor; GLUT, glucose transporter; G4KO, GLUT4 knock-out; IRKO, insulin receptor knock-out; IGF, insulin-like growth factor; GTG, gold thioglucose.

² B. B. Kahn, unpublished results.

	ACKNOWLEDGMENTS

 
We thank E. Rosen for very helpful suggestions on the manuscript, G. I. Shulman and J. K. Kim for stimulating collaborations, and present and former members of the laboratories of B. B. Kahn and C. R. Kahn for outstanding work, especially E. D. Abel, J. C. Brüning, O. D. Peroni, A. Zisman, and M. Blüher.

	REFERENCES

TOP INTRODUCTION Muscle-specific GLUT4-/- Mouse Muscle-specific Insulin... Adipocyte-specific GLUT4-/-... Adipocyte-specific Insulin... Conclusions REFERENCES

 

1. Saltiel, A. R., and Kahn, C. R. (2001) Nature 414, 799–806[CrossRef][Medline] [Order article via Infotrieve]
2. Bryant, N., Govers, R., and James, D. (2002) Nat. Rev. Mol. Cell. Biol. 3, 267–277[CrossRef][Medline] [Order article via Infotrieve]
3. Khan, A., and Pessin, J. E. (2002) Diabetologia 45, 1475–1483[CrossRef][Medline] [Order article via Infotrieve]
4. Shepherd, P. R., Abel, E. D., and Kahn, B. B. (2000) in Diabetes Mellitus: A Fundamental and Clinical Text (LeRoith, D. R., Olefsky, J. M., and Taylor, S. I., eds) pp. 627–641, J. P. Lippincott Co., Philadelphia
5. Shepherd, P. R., and Kahn, B. B. (1999) N. Engl. J. Med. 341, 248–257[Free Full Text]
6. DeFronzo, R., Jacot, E., Jequier, E., Maeder, E., Wahren, J., and Felber, J. (1981) Diabetes 30, 1000–1007[Medline] [Order article via Infotrieve]
7. Basu, A., Basu, R., Shah, P., Vella, A., Johnson, C. M., Jensen, M., Nair, K. S., Schwenk, W. F., and Rizza, R. A. (2001) Diabetes 50, 1351–1362[Abstract/Free Full Text]
8. Cline, G. W., Petersen, K. F., Krssak, M., Shen, J., Hundal, R. S., Trajanoski, Z., Inzucchi, S., Dresner, A., Rothman, D. L., and Shulman, G. I. (1999) N. Engl. J. Med. 341, 240–246[Abstract/Free Full Text]
9. Kahn, B. B., and Rossetti, L. (1998) Nat. Genet. 20, 223–225[CrossRef][Medline] [Order article via Infotrieve]
10. DeFronzo, R. A. (1997) Diabetes Rev. 5, 177–269
11. Accili, D., Drago, J., Lee, E. J., Johnson, M. D., Cool, M. H., Salvatore, P., Asico, L. D., Jose, P. A., Taylor, S. I., and Westphal, H. (1996) Nat. Genet. 12, 106–109[CrossRef][Medline] [Order article via Infotrieve]
12. Katz, E., Stenbit, A., Hatton, K., DePinho, R., and Charron, J. (1995) Nature 377, 151–155[CrossRef][Medline] [Order article via Infotrieve]
13. Stenbit, A. E., Tsao, T. S., Li, J., Burcelin, R., Geenen, D. L., Factor, S. M., Houseknecht, K., Katz, E. B., and Charron, M. J. (1997) Nat. Med. 3, 1096–1101[CrossRef][Medline] [Order article via Infotrieve]
14. Gu, H., Zou, Y., and Rajewsky, K. (1993) Cell 73, 1155–1164[CrossRef][Medline] [Order article via Infotrieve]
15. Zisman, A., Peroni, O. D., Abel, E. D., Michael, M. D., Mauvais-Jarvis, F., Lowell, B. B., Wojtaszewski, J. F., Hirshman, M. F., Virkamaki, A., Goodyear, L. J., Kahn, C. R., and Kahn, B. B. (2000) Nat. Med. 6, 924–928[CrossRef][Medline] [Order article via Infotrieve]
16. Abel, E. D., Kaulbach, H. C., Tian, R., Hopkins, J., Duffy, J., Doetschman, T., Minnemann, T., Boers, M.-E., Hadro, E., Oberste-Berghaus, C., Quist, W., Lowell, B. B., Ingwall, J. S., and Kahn, B. B. (1999) J. Clin. Invest. 104, 1703–1714[Medline] [Order article via Infotrieve]
17. Brüning, J. C., Michael, M. D., Winnay, J. N., Hayashi, T., Horsch, D., Accili, D., Goodyear, L. J., and Kahn, C. R. (1998) Mol. Cell 2, 559–569[CrossRef][Medline] [Order article via Infotrieve]
18. Kim, J. K., Zisman, A., Fillmore, J. J., Peroni, O. D., Kotani, K., Perret, P., Zong, H., Dong, J., Kahn, C. R., Kahn, B. B., and Shulman, G. I. (2001) J. Clin. Invest. 108, 153–160[CrossRef][Medline] [Order article via Infotrieve]
19. Tsao, T.-S., Stenbit, A. E., Factor, S. M., Chen, W., Rossetti, L., and Charron, M. J. (1999) Diabetes 48, 775–782[Abstract]
20. Gulve, E., Ren, J., Marshall, B., Gao, J., Hansen, P., Holloszy, J., and Mueckler, M. (1994) J. Biol. Chem. 269, 18366–18370[Abstract/Free Full Text]
21. Marshall, B. A., and Mueckler, M. M. (1994) Am. J. Physiol. 267, E738–E744
22. Weiss, R. G., Chatham, J. C., Georgakopolous, D., Charron, M. J., Wallimann, T., Kay, L., Walzel, B., Wang, Y., Kass, D. A., Gerstenblith, G., and Chacko, V. P. (2002) FASEB J. 16, 613–615[Free Full Text]
23. Tian, R., and Abel, E. D. (2001) Circulation 103, 2961–2966[Abstract/Free Full Text]
24. Kim, J. K., Michael, M. D., Previs, S. F., Peroni, O. D., Mauvais-Jarvis, F., Neschen, S., Kahn, B. B., Kahn, C. R., and Shulman, G. I. (2000) J. Clin. Invest. 105, 1791–1797[Medline] [Order article via Infotrieve]
25. Belke, D., Betuing, S., Tuttle, M., Graveleau, C., Young, M., Pham, M., Zhang, D., Cooksey, R., McClain, D., Litwin, S., Taegtmeyer, H., Severson, D., Kahn, C. R., and Abel, E. D. (2002) J. Clin. Invest. 109, 629–639[CrossRef][Medline] [Order article via Infotrieve]
26. Wojtaszewski, J. F., Higaki, Y., Hirshman, M. F., Michael, M. D., Dufresne, S. D., Kahn, C. R., and Goodyear, L. J. (1999) J. Clin. Invest. 104, 1257–1264[Medline] [Order article via Infotrieve]
27. Fernandez, A. M., Kim, J. K., Yakar, S., Dupont, J., Hernandez-Sanchez, C., Castle, A. L., Filmore, J., Shulman, G. I., and Le Roith, D. (2001) Genes Dev. 15, 1926–1934[Abstract/Free Full Text]
28. Yakar, S., Liu, J. L., Fernandez, A. M., Wu, Y., Schally, A. V., Frystyk, J., Chernausek, S. D., Mejia, W., and Le Roith, D. (2001) Diabetes 50, 1110–1118[Abstract/Free Full Text]
29. Abel, E. D., Peroni, O. D., Kim, J. K., Kim, Y.-B., Boss, O., Hadro, E., Minnemann, T., Shulman, G. I., and Kahn, B. B. (2001) Nature 409, 729–733[CrossRef][Medline] [Order article via Infotrieve]
30. James, D., Burleigh, K., and Kraegen, E. (1985) Diabetes 34, 1049–1054[Abstract]
31. Kahn, B. B., and Flier, J. S. (2000) J. Clin. Invest. 106, 473–481[Medline] [Order article via Infotrieve]
32. Frühbeck, G., Gómez-Ambrosi, J., Muruzábal, F. J., and Burrell, M. A. (2001) Am. J. Physiol. 280, E827–E847
33. Shepherd, P. R., Gnudi, L., Tozzo, E., Yang, H., Leach, F., and Kahn, B. B. (1993) J. Biol. Chem. 268, 22243–22246[Abstract/Free Full Text]
34. Blüher, M., Michael, M., Peroni, O. D., Ueki, K., Carter, N., Kahn, B. B., and Kahn, C. R. (2002) Dev. Cell 3, 25–38[CrossRef][Medline] [Order article via Infotrieve]
35. Guerra, C., Navarro, P., Valverde, A. M., Arribas, M., Bruning, J., Kozak, L. P., Kahn, C. R., and Benito, M. (2001) J. Clin. Invest. 108, 1205–1213[CrossRef][Medline] [Order article via Infotrieve]
36. Blüher, M., Kahn, B. B., and Kahn, C. R. (2003) Science 299, 572–574[Abstract/Free Full Text]
37. Guarente, L., and Kenyon, C. (2000) Nature 408, 255–262[CrossRef][Medline] [Order article via Infotrieve]

CiteULike

Complore

Connotea

Del.icio.us

Digg

Reddit

Technorati

This article has been cited by other articles:

				S. Dash, H. Sano, J. J. Rochford, R. K. Semple, G. Yeo, C. S. S. Hyden, M. A. Soos, J. Clark, A. Rodin, C. Langenberg, et al. A truncation mutation in TBC1D4 in a family with acanthosis nigricans and postprandial hyperinsulinemia PNAS, June 9, 2009; 106(23): 9350 - 9355. [Abstract] [Full Text] [PDF]

				L. Feng, L. Gao, Q. Guan, X. Hou, Q. Wan, X. Wang, and J. Zhao Long-term moderate ethanol consumption restores insulin sensitivity in high-fat-fed rats by increasing SLC2A4 (GLUT4) in the adipose tissue by AMP-activated protein kinase activation J. Endocrinol., October 1, 2008; 199(1): 95 - 104. [Abstract] [Full Text] [PDF]

				A. Shisheva Phosphoinositides in insulin action on GLUT4 dynamics: not just PtdIns(3,4,5)P3 Am J Physiol Endocrinol Metab, September 1, 2008; 295(3): E536 - E544. [Abstract] [Full Text] [PDF]

				E. Karnieli and M. Armoni Transcriptional regulation of the insulin-responsive glucose transporter GLUT4 gene: from physiology to pathology Am J Physiol Endocrinol Metab, July 1, 2008; 295(1): E38 - E45. [Abstract] [Full Text] [PDF]

				H. C. Cha, N. R. Oak, S. Kang, T.-A. Tran, S. Kobayashi, S.-H. Chiang, D. G. Tenen, and O. A. MacDougald Phosphorylation of CCAAT/Enhancer-binding Protein {alpha} Regulates GLUT4 Expression and Glucose Transport in Adipocytes J. Biol. Chem., June 27, 2008; 283(26): 18002 - 18011. [Abstract] [Full Text] [PDF]

				M. Serino, R. Menghini, L. Fiorentino, R. Amoruso, A. Mauriello, D. Lauro, P. Sbraccia, M. L. Hribal, R. Lauro, and M. Federici Mice Heterozygous for Tumor Necrosis Factor-{alpha} Converting Enzyme Are Protected From Obesity-Induced Insulin Resistance and Diabetes Diabetes, October 1, 2007; 56(10): 2541 - 2546. [Abstract] [Full Text] [PDF]

				A Corbould Chronic testosterone treatment induces selective insulin resistance in subcutaneous adipocytes of women J. Endocrinol., March 1, 2007; 192(3): 585 - 594. [Abstract] [Full Text] [PDF]

				F. Moloney, S. Toomey, E. Noone, A. Nugent, B. Allan, C. E. Loscher, and H. M. Roche Antidiabetic Effects of cis-9, trans-11-Conjugated Linoleic Acid May Be Mediated via Anti-Inflammatory Effects in White Adipose Tissue Diabetes, March 1, 2007; 56(3): 574 - 582. [Abstract] [Full Text] [PDF]

				J. B. Flowers, A. T. Oler, S. T. Nadler, Y. Choi, K. L. Schueler, B. S. Yandell, C. M. Kendziorski, and A. D. Attie Abdominal obesity in BTBR male mice is associated with peripheral but not hepatic insulin resistance Am J Physiol Endocrinol Metab, March 1, 2007; 292(3): E936 - E945. [Abstract] [Full Text] [PDF]

				T. Alquier, C. Leloup, A. Lorsignol, and L. Penicaud Translocable Glucose Transporters in the Brain: Where Are We in 2006? Diabetes, December 1, 2006; 55(Supplement_2): S131 - S138. [Abstract] [Full Text] [PDF]

				K. Uno, H. Katagiri, T. Yamada, Y. Ishigaki, T. Ogihara, J. Imai, Y. Hasegawa, J. Gao, K. Kaneko, H. Iwasaki, et al. Neuronal pathway from the liver modulates energy expenditure and systemic insulin sensitivity. Science, June 16, 2006; 312(5780): 1656 - 1659. [Abstract] [Full Text] [PDF]

				B. M. Sebastian and L. E. Nagy Decreased insulin-dependent glucose transport by chronic ethanol feeding is associated with dysregulation of the Cbl/TC10 pathway in rat adipocytes Am J Physiol Endocrinol Metab, December 1, 2005; 289(6): E1077 - E1084. [Abstract] [Full Text] [PDF]

				M. Widmer, M. Uldry, and B. Thorens GLUT8 Subcellular Localization and Absence of Translocation to the Plasma Membrane in PC12 Cells and Hippocampal Neurons Endocrinology, November 1, 2005; 146(11): 4727 - 4736. [Abstract] [Full Text] [PDF]

				R. D. Rudic, P. McNamara, D. Reilly, T. Grosser, A.-M. Curtis, T. S. Price, S. Panda, J. B. Hogenesch, and G. A. FitzGerald Bioinformatic Analysis of Circadian Gene Oscillation in Mouse Aorta Circulation, October 25, 2005; 112(17): 2716 - 2724. [Abstract] [Full Text] [PDF]

				E. Carvalho, K. Kotani, O. D. Peroni, and B. B. Kahn Adipose-specific overexpression of GLUT4 reverses insulin resistance and diabetes in mice lacking GLUT4 selectively in muscle Am J Physiol Endocrinol Metab, October 1, 2005; 289(4): E551 - E561. [Abstract] [Full Text] [PDF]

				S. A Bayol, B. H Simbi, and N. C Stickland A maternal cafeteria diet during gestation and lactation promotes adiposity and impairs skeletal muscle development and metabolism in rat offspring at weaning J. Physiol., September 15, 2005; 567(3): 951 - 961. [Abstract] [Full Text] [PDF]

				Y.-H. Yu and H. N. Ginsberg Adipocyte Signaling and Lipid Homeostasis: Sequelae of Insulin-Resistant Adipose Tissue Circ. Res., May 27, 2005; 96(10): 1042 - 1052. [Abstract] [Full Text] [PDF]

				F. G. Haj, J. M. Zabolotny, Y.-B. Kim, B. B. Kahn, and B. G. Neel Liver-specific Protein-tyrosine Phosphatase 1B (PTP1B) Re-expression Alters Glucose Homeostasis of PTP1B-/-Mice J. Biol. Chem., April 15, 2005; 280(15): 15038 - 15046. [Abstract] [Full Text] [PDF]

				C. Kurlawalla-Martinez, B. Stiles, Y. Wang, S. U. Devaskar, B. B. Kahn, and H. Wu Insulin Hypersensitivity and Resistance to Streptozotocin-Induced Diabetes in Mice Lacking PTEN in Adipose Tissue Mol. Cell. Biol., March 15, 2005; 25(6): 2498 - 2510. [Abstract] [Full Text] [PDF]

				L. Puljak, M. J Pagliassotti, Y. Wei, I. Qadri, V. Parameswara, V. Esser, J. G. Fitz, and G. Kilic Inhibition of cellular responses to insulin in a rat liver cell line. A role for PKC in insulin resistance J. Physiol., March 1, 2005; 563(2): 471 - 482. [Abstract] [Full Text] [PDF]

				P. K. Saha, H. Kojima, J. Martinez-Botas, A. L. Sunehag, and L. Chan Metabolic Adaptations in the Absence of Perilipin: INCREASED {beta}-OXIDATION AND DECREASED HEPATIC GLUCOSE PRODUCTION ASSOCIATED WITH PERIPHERAL INSULIN RESISTANCE BUT NORMAL GLUCOSE TOLERANCE IN PERILIPIN-NULL MICE J. Biol. Chem., August 20, 2004; 279(34): 35150 - 35158. [Abstract] [Full Text] [PDF]

				J. M. Zabolotny, F. G. Haj, Y.-B. Kim, H.-J. Kim, G. I. Shulman, J. K. Kim, B. G. Neel, and B. B. Kahn Transgenic Overexpression of Protein-tyrosine Phosphatase 1B in Muscle Causes Insulin Resistance, but Overexpression with Leukocyte Antigen-related Phosphatase Does Not Additively Impair Insulin Action J. Biol. Chem., June 4, 2004; 279(23): 24844 - 24851. [Abstract] [Full Text] [PDF]

				K. A. Lamia, O. D. Peroni, Y.-B. Kim, L. E. Rameh, B. B. Kahn, and L. C. Cantley Increased Insulin Sensitivity and Reduced Adiposity in Phosphatidylinositol 5-Phosphate 4-Kinase {beta}-/- Mice Mol. Cell. Biol., June 1, 2004; 24(11): 5080 - 5087. [Abstract] [Full Text] [PDF]

This Article Full Text (PDF) Supplemental Data All Versions of this Article: 278/36/33609    most recent R300019200v1 Submit a Letter to Editor Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Minokoshi, Y. Articles by Kahn, B. B. Search for Related Content PubMed PubMed Citation Articles by Minokoshi, Y. Articles by Kahn, B. B. Social Bookmarking                      What's this?