1 Department of Medicine, Division of Endocrinology and Metabolism, University of California, San Diego, La Jolla, California
2 San Diego VA HealthCare System, Research Service, San Diego, California
3 Whittier Diabetes Institute, La Jolla, California
![]() |
ABSTRACT |
---|
![]() ![]() ![]() ![]() ![]() ![]() |
---|
Endothelin-1 (ET-1) is a 21-amino acid polypeptide produced by endothelial cells (1). ET-1 belongs to a family of endothelin polypeptides along with ET-2 and ET-3 (2). Although encoded by different genes, endothelin peptides are believed to be structurally and functionally similar in nature. Endothelin peptides bind to two known heptahelical transmembrane G protein-coupled receptors, namely ETA and ETB, and ET-1 binds most strongly to ETA (3). ET-1 has potent vasoactive effects in vascular smooth muscle important for blood pressure regulation. However, ETA and ETB receptors are expressed in a variety of tissues, besides vascular tissue, suggesting that ET-1 has additional biological effects. We (46) and others (7,8) have previously demonstrated that ET-1 has an insulin-like effect that is mediated through ETA in 3T3-L1 adipocytes in vitro. Our past work showed that ET-1, like insulin, can promote GLUT4 translocation and stimulate glucose transport through a signaling pathway involving Gq/11 and phosphatidylinositol 3-kinase (PI3K) (6).
In addition to acute effects of ET-1, we have previously shown that chronic ET-1 treatment of 3T3-L1 cells induces cellular insulin resistance. This heterologous desensitization of insulin action is associated with downregulation of IRS-I and Gq/11 with loss of insulins ability to stimulate GLUT4 translocation (5). As with 3T3-L1 cells in vitro, it seems that ET-1 may be detrimental to insulin action pathways in physiologic tissues in vivo as well. Thus, when administered acutely in high amounts, ET-1 seems to attenuate insulin action in humans (9). Acute ET-1 treatment can also impair insulin action in conscious male Sprague-Dawley rats (10). Because elevated ET-1 levels have been reported in various insulin-resistant and diabetic states in both humans (1114) and animals (15), it is possible that chronic increases in ET-1 concentrations can promote insulin resistance.
Skeletal muscle is the most important tissue for whole-body glucose disposal (16), and it is not known whether chronically elevated levels of ET-1 in vitro or in vivo can negatively effect insulin action in this tissue. In the current studies, we show that in vitro ET-1 pretreatment leads to decreased insulin-stimulated skeletal muscle glucose transport. Furthermore, chronic in vivo ET-1 administration leads to in vivo insulin resistance with a decrease in skeletal muscle glucose uptake and inhibition of the insulin signaling pathway.
![]() |
RESEARCH DESIGN AND METHODS |
---|
![]() ![]() ![]() ![]() ![]() ![]() |
---|
Animal use.
For in vivo experiments, animals used were normotensive WKY rats (Charles River Laboratories, Wilmington, MA) weighing 175200 g. For in vitro experiments, smaller male rats weighing 100110 g were used. Animals were provided with a normal rodent diet and tap water and were individually housed. The local committee on animal care at the University of California, San Diego approved the animal experiments.
Determination of 2-deoxyglucose uptake in isolated soleus muscle strips.
Soleus muscles with tendons still attached were isolated in the animals hindquarter and removed rapidly. Isolated muscles were stripped lengthwise. Stripping soleus muscles is known to make these muscles more suitable for glucose uptake measurements (17). Strips were placed in a Krebs-Henseleit buffer (KHB) solution containing 32 mmol/l mannitol, 8 mmol/l D-glucose, and 0.1% BSA. Strips were incubated without additions (basal) or with 140 nmol/l ET-1 alone or with 14 nmol/l insulin (Novo Nordisk) alone at 29°C for 30 min. In experiments in which ET-1 and insulin were together, muscle strips were pretreated (for 1 h) with ET-1 or ET-1 plus 1 µmol/l BQ610 before the inclusion of insulin. Before glucose transport measurements, D-glucose was removed by washing strips two times for 5 min each in a glucose-free KHB with 38 mmol/l mannitol and 2 mmol/l pyruvate. For determining 2-deoxyglucose (2-DOG) uptake, strips were incubated with (1.5 µCi) 2-deoxy-D-[3H]glucose (1 mmol/l) and (0.1 µCi) 14C-mannitol (37 mmol/l) for 20 min. Strips were removed rapidly, rinsed, blotted, and snap-frozen in liquid N2. Muscles were analyzed for 14C and 3H in digested muscle extract.
Surgery and hyperinsulinemic-euglycemic clamp procedure.
Rats were placed under single-dose anesthesia (42 mg/kg ketamine HCl, 5 mg/kg xylazine, and 0.75 mg/kg acepromazine maleate) and cannulated with carotid artery cannulae for blood sampling and dual jugular vein cannulae for glucose and insulin infusions. Cannulae were tunneled underneath the skin, sutured to the outside, and encased in silastic tubing (0.2-cm ID) for protection. In addition, miniosmotic pumps (Alzet model #2002) containing 0.2 mg/ml ET-1 were chronically implanted in the animals intra-abdominal cavity for the total duration of the treatment period. ET-1 was delivered in a saline vehicle at 8.2 ng · kg-1 · min-1. Control rats received saline pumps. Immediately after surgery, rats were provided with light warmth and permitted to recover fully for 5 days. Six hours before the euglycemic-hyperinsulinemic clamp procedure was performed, food was withdrawn from cages. All rats were subjected to the same general insulin-clamp procedure as we have previously described in detail (18). A terminal dose of Nembutal (100 mg/kg i.v.) was administered after clamping to dissect red tibialis anterior (RTA) muscles from killed rats. For obtaining basal muscle, one set of rats were rested, provided with food and water, and then allowed to recover for 2 days. Recovered rats were killed by CO2 asphyxiation, and muscles were collected for ex vivo glucose transport (soleus) and Western blotting measurements (RTA).
Immunoprecipitation of IRS-1 protein.
RTA muscles were homogenized in ice-cold homogenization buffer containing 150 mmol/l NaCl, 50 mmol/l Tris (pH 7.5), 30 mmol/l sodium pyrophosphate, 10 mmol/l sodium fluoride, 1 mmol/l DTT, 10% [vol/vol] glycerol, 1% triton-X-100, plus complete protease inhibitor cocktail (1 tablet/50 ml). Muscle homogenate was centrifuged at 4°C (15,000g for 20 min) to remove unwanted insoluble material. Homogenates at this stage were cleared further by gentle rotation with protein A/G agarose beads. Precleared sample (1 mg) was subjected to overnight immunoprecipitation by 4 µl of anti-IRS-1 and protein A/G beads. We have previously done the same with sample made from cell extracts (5).
Detection of IRS-1, IRS-1-associated PI3K (p110), and AKT phosphorylation by Western blotting.
Samples were separated by SDS-polyacrylamide electrophoresis and transferred to an Immobilon membrane by electromembrane transfer. Membranes were blocked overnight in 5% nonfat dry milk (NFDM) made in Tris-buffered saline (pH 7.6). Proteins were detected by incubating blocked membranes with primary antibody at a dilution recommended by the manufacturer in nonfat dry milk/Tris-buffered saline (pH 7.6) followed by incubating with horseradish peroxidase-linked secondary antibodies diluted (1:2,000). Visualization of Western blots was done using an enhanced chemiluminescence system. Bands were quantified using a Macintosh connected with an Arcus scanner and NIH-Image 1.6 software.
Blood chemistry analysis.
Plasma glucose was assayed by the glucose oxidase method (YSI). Plasma insulin was measured via a radioimmunoassay kit (Linco Research, St. Charles, MO). Plasma free fatty acids (FFAs) were measured enzymatically using a commercially available kit (NEFA C; Wako Chemicals USA, Richmond, VA).
Calculations and statistical analysis.
Hepatic glucose output (HGO) and glucose disposal rate (GDR) were calculated using Steeles equation (19). Data obtained from in vitro glucose transport experiments were analyzed using two-way ANOVA. One- and two-tailed t tests were used as appropriate for all other assays. All data are reported as means ± SE.
![]() |
RESULTS |
---|
![]() ![]() ![]() ![]() ![]() ![]() |
---|
|
|
To extend the results of the in vitro experiments to the in vivo situation, we performed hyperinsulinemic-euglycemic clamp studies to assess insulin-stimulated GDRs in male and female WKY rats that had been chronically treated with ET-1 (8.2 ng · kg-1 · min-1) for 5 days using miniosmotic pumps. These results are summarized in Fig. 2, which shows that both male and female ET-1-treated animals demonstrate a 3040% decrease in insulin-stimulated GDR compared with saline controls after chronic in vivo ET-1 administration. In addition, we assessed the ability of insulin to suppress HGO. As seen in Fig. 2C, insulin was able to lower HGO by 66% in control animals (P < 0.05), whereas HGO suppression was substantially less in animals that were chronically treated with ET-1 (25%).
|
|
|
PI3K is an upstream activator of AKT, and recent evidence indicates an important role for AKT in insulin-stimulated glucose transport (21). Consequently, we measured phospho AKT levels in muscle lysates obtained from animals in the basal state and at the end of the hyperinsulinemic-euglycemic clamp. As seen in Fig. 5, insulin leads to a marked stimulation of AKT phosphorylation in the control animals, and this effect is blunted in the muscles from the chronic ET-1-treated group.
|
![]() |
DISCUSSION |
---|
![]() ![]() ![]() ![]() ![]() ![]() |
---|
Several reports have shown that circulating ET-1 levels are elevated in insulin-resistant individuals with obesity (24,25) and/or type 2 diabetes (1114). In addition, ET-1 levels are increased in various rodent models of insulin resistance and diabetes (15). In light of the in vitro evidence for heterologous desensitization of insulin action by chronic ET-1 stimulation (5), the elevated levels of ET-1 in obesity and diabetes raise the possibility that chronically increased circulating levels of ET-1 may contribute to the development of insulin resistance in pathophysiologic states. In the current studies, we tested this hypothesis by chronically treating normal animals with ET-1 by use of implanted osmotic minipumps. Our results show that 5 days of ET-1 treatment leads to an overall state of insulin resistance, as measured by a 25% decrease in insulin-stimulated GDR during hyperinsulinemic-euglycemic glucose clamps. Because skeletal muscle accounts for the majority of in vivo glucose uptake, these results are consistent with in vivo ET-1-induced skeletal muscle insulin resistance. To demonstrate this directly, we isolated soleus muscle strips for ex vivo measurements of insulin action. We found that in vitro treatment of muscle strips with ET-1 leads to a subsequent decrease in insulin-stimulated glucose uptake. More important, when muscle strips were isolated from saline- versus ET-1-treated animals and studied ex vivo, a striking decrease in insulin-stimulated glucose transport was observed in the muscle strips obtained from the ET-1 group. Taken together, these data provide strong evidence that chronic ET-1 treatment, either in vitro or in vivo, can lead to a state of skeletal muscle insulin resistance.
It is interesting that the ET-1-induced state of in vivo insulin resistance was not confined to skeletal muscle. Another important effect of insulin in vivo is to inhibit hepatic glucose production, and this effect of insulin was blunted during the glucose clamp studies in the ET-1-treated animals. Because ET-1 receptors can mediate calcium activation of glycogenolysis in hepatocytes (26), chronic stimulation of the hepatic ETA receptor is a likely mechanism of the hepatic insulin resistance.
On the basis of the in vitro effects of ET-1 to cause insulin resistance in muscle, shown in the current studies, and in adipocytes, as shown in previous studies (5), it seems most likely that the ET-1-associated insulin-resistant state in vivo reflects a direct effect of ET-1 on insulin target tissues. In our preliminary work, we noted that concentrations of ET-1 (10 nmol/l) that induce insulin resistance in vitro in adipocytes in 24 h were not effective at causing insulin resistance in muscle strips in 1 h (data not shown). Because 3T3-L1 adipocytes can be studied for several days, whereas muscle strips begin to lose viability by 23 h, we used higher doses of ET-1 to achieve effects by 1 h of incubation. It is of interest that in muscle strips studied ex vivo from ET-1-treated animals, we found decreased IRS-1 levels, decreased IRS-1-associated PI3-kinase, and decreased insulin-stimulated AKT phosphorylation. When ET-1 was added directly in vitro to muscle strips for 1 h, muscle insulin resistance to glucose transport stimulation was clearly produced, but total IRS-1 levels were unchanged, whereas decreased AKT activation was still observed. This suggests that in vivo, the decreased IRS-1 levels may not be the sole cause of the insulin resistance. Furthermore, the ET-1-treated animals became hyperinsulinemic, and because elevated insulin levels can cause a decrease in IRS-1, it is not clear whether the in vivo decreases in IRS-1 content are a direct effect of ET-1 or secondary to hyperinsulinemia.
ET-1 is a vasoactive peptide that, at least when given acutely, can decrease capillary blood flow (9). Because blood flow to skeletal muscle tissues is an additional determinant of skeletal muscle glucose uptake, the possibility can be raised that chronic ET-1 administration reduced skeletal muscle blood flow and that this could contribute to the insulin resistance that we have observed. Although we cannot completely rule out this possibility, we think that it is unlikely or, at best, only a contributory factor for several reasons. First, the insulin-resistant state induced by chronic ET-1 treatment in our studies was not confined to skeletal muscle, because we observed decreased insulin-induced suppression of HGO as well as elevated circulating FFA levels, indicating both hepatic and adipose tissue insulin resistance. Second, our previous studies demonstrated direct in vitro effects of ET-1 to cause insulin resistance in adipocytes, and the current studies show that ET-1 administration in vitro also causes insulin resistance in skeletal muscle strips. Third, when studied ex vivo, skeletal muscle strips from the chronic ET-1-treated animals maintained the insulin-resistant state, a finding that would be incompatible with effects simply because of altered in vivo blood flow. Fourth, the insulin signaling defects that we demonstrated in skeletal muscle from the ET-1-treated animals were comparable to the earlier in vitro results in adipocytes. Furthermore, one would not expect these kinds of signaling defects in insulin action to persist ex vivo if reduced blood flow was the main cause of ET-1-induced insulin resistance.
It has been shown that insulin can promote ET-1 gene expression (27) and release (28). Thus, one possibility is that insulin resistance leads to hyperinsulinemia, which causes increased circulating ET-1 levels, which then further exacerbates the insulin-resistant state. In this way, a positive feedback system may exist in vivo, in which insulin resistance begets more insulin resistance through the ET-1 system. At this point in our knowledge, this sequence of events is speculative, and future experiments will be needed to determine whether this feed-forward concept can occur.
In summary, we have shown that acute in vitro treatment of skeletal muscle with ET-1 can mimic insulin action on glucose transport, whereas a longer pretreatment period leads to a state of heterologous desensitization of insulin action with decreased insulin-stimulated glucose transport. Consistent with this, chronic in vivo treatment of normal rats with ET-1 leads to overall in vivo insulin resistance at the level of skeletal muscle, as well as the liver, with decreased insulin-stimulated glucose transport and insulin signaling in ex vivo studied soleus muscle strips. These results suggest that chronically elevated levels of ET-1 may contribute to or exacerbate insulin resistance in pathophysiologic states.
![]() |
ACKNOWLEDGMENTS |
---|
Address correspondence and reprint requests to Jason Wilkes, Department of Medicine (0673), UCSD, 9500 Gilman Dr., La Jolla, CA 92093. E-mail: jawilkes{at}ucsd.edu
Received for publication August 27, 2002 Revision received April 21, 2003. and accepted in revised form April 21, 2003
2-DOG, 2-deoxyglucose; ET-1, endothelin-1; FFA, free fatty acid; GDR, glucose disposal rate; HGO, hepatic glucose output; KHB, Krebs-Henseleit buffer; PI3K, phosphatidylinositol 3-kinase; RTA, red tibialis anterior
![]() |
REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() |
---|