Department of Physiology and Biophysics, Keck School of Medicine, University of Southern California, Los Angeles, California 90089-9142
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ABSTRACT |
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We have shown that insulin controls endogenous glucose production (EGP) indirectly, via suppression of adipocyte lipolysis. Free fatty acids (FFA) and EGP are suppressed proportionately, and when the decline in FFA is prevented during insulin infusion, suppression of EGP is also prevented. The present study tested the hypothesis that suppression of lipolysis under conditions of constant insulin would yield a suppression of EGP. N6-cyclohexyladenosine (CHA) was used to selectively suppress adipocyte lipolysis during euglycemic clamps in conscious male dogs. FFA suppression by CHA caused suppression of EGP. Liposyn control experiments, which maintained FFA levels above basal during CHA infusion, completely prevented the decline in EGP, whereas glycerol control experiments, which maintained glycerol levels close to basal, did not prevent a decline in EGP. These controls suggest that the EGP suppression was secondary to the suppression of FFA levels specifically. A difference in the sensitivity of FFA and EGP suppression (FFA were suppressed ~85% whereas EGP only declined ~40%) was possibly caused by confounding effects of CHA, including an increase in catecholamine and glucagons levels during CHA infusion. Thus suppression of lipolysis under constant insulin causes suppression of EGP, despite a significant rise in catecholamines.
free fatty acids; hepatic glucose output; catecholamines; adenosine
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INTRODUCTION |
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EVIDENCE FROM OUR LABORATORY (1, 5, 25, 29) and others (14, 17, 23) indicates that insulin acts to suppress endogenous glucose production (EGP) primarily via an indirect mechanism. We hypothesized that insulin does not suppress the liver directly but first traverses the tight capillary endothelium of nonhepatic insulin-sensitive tissues to modulate some blood-borne second signal, which in turn signals the liver to lower glucose production ("The Single Gateway Hypothesis"). Because of the high correlation between free fatty acids (FFA) and EGP suppression by insulin (25), FFA were suggested as the putative second signal in this hypothesis. In support of this idea, infusion of Liposyn and heparin to maintain FFA levels prevented suppression of EGP during hyperinsulinemic euglycemic clamps (26) as well as after oral glucose (15). This evidence supports the concept that plasma FFA are the second signal of insulin suppression of liver glucose production.
Numerous studies (7, 10, 11, 16, 24, 27, 32) have examined the relationship between FFA and EGP suppression, using pharmacological means to lower FFA levels. The results of these studies are conflicting. Inhibition of lipolysis has been shown to decrease (10, 16, 27, 32), not change (24), or even increase (11) EGP. Some of this inconsistency may be due to different experimental protocols; specifically, some studies did not maintain glucose-regulating hormones, such as insulin and glucagon, constant (10, 11). There may also be confounding effects of some lipid-lowering drugs to increase the levels of counterregulatory hormones, such as glucagon (21), growth hormone (11, 13, 21), cortisol (7, 11, 24), and/or catecholamines (7, 21).
The present study attempts to reexamine whether acute suppression of lipolysis will cause suppression of EGP in vivo. This study was performed under conditions of clamped insulin, glucagon, and glucose. Insulin was underreplaced to maximize the range of FFA levels achieved. N6-cyclohexyladenosine (CHA), an A1-selective adenosine agonist, was employed to suppress lipolysis. CHA is a potent antilipolytic agent that acts via the inhibition of adenylate cyclase, causing a decrease in cAMP levels in the adipocyte (31). This mechanism of CHA action is distinct from that of nicotinic acid derivatives. Liposyn control infusions were used to distinguish the effects of lipolysis suppression from other possible effects of CHA on EGP. Glycerol control experiments were also performed to test for the relationship between glycerol and EGP. Finally, saline control experiments were done to separate the effects of CHA from those of the pancreatic clamps themselves.
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METHODS |
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Animals. Experiments were performed on male mongrel dogs (23.9 ± 1.3 kg). The maintenance of and surgery on the animals have been previously described (25). Chronic catheters were implanted at least 7 days before experiments. One catheter was inserted into the jugular vein and advanced to the right atrium for sampling of central venous blood. A second catheter was placed in the portal vein 4 cm upstream from the porta hepatis for portal replacement infusions of glucagon and insulin. We have previously shown that infusions given at this upstream site are overall equally distributed among the lobes of the liver (4). A third catheter was placed in the femoral vein and advanced to the inferior vena cava for the infusion of [3H] glucose, somatostatin, and CHA. On the morning of the experiment, acute catheters were inserted into the saphenous veins for the variable infusion of labeled glucose, and when necessary, Liposyn plus heparin or glycerol.
Euglycemic clamp protocol.
Nine dogs underwent CHA dose-response experiments, performed as
follows. After a fasting sample was taken at
t = 150, infusions of somatostatin (SRIF, 1 µg · kg
1 · min
1, Bachem
California, Torrance, CA) and HPLC-purified
D-[3-3H]glucose (25 µCi + 0.25 µCi/min, NEN Research Products Du Pont, Boston, MA) were begun into
the femoral catheter. Portal infusions of insulin (0.2 mU · kg
1 · min
1,
Novo-Nordisk, Copenhagen, Denmark) and glucagon (1.0 ng · kg
1 · min
1, porcine
glucagon, Sigma, St. Louis, MO) were also initiated at this time. This
insulin dose was designed to underreplace insulin levels so that FFA
concentrations would be at or above basal at the onset of CHA infusion.
Growth hormone was not replaced in these studies. Glucose was clamped
at basal by a variable glucose infusion, which was labeled with
D-[3-3H]glucose (1.8 µCi/g) to stabilize
specific activity (12). At t =
60, samples
were taken every 20 min until t = 0, at which time CHA
infusion was initiated. CHA was infused for 60 min at consecutive
increasing doses (0.167, 0.500, and 1.667 µg · kg
1 · min
1, CHA,
Sigma). Samples were taken at 5-min intervals for the first 20 min of
each CHA dose and then at 30, 45, and 60 min into each CHA infusion.
All samples were assayed for glucose, insulin, glucagon, FFA, and
glycerol (see Assays).
Assays.
Samples for insulin, glucagon, and tracer assay were collected in tubes
coated with lithium fluoride and heparin. Trasylol (aprotinin; 75 µl/ml blood; FBA Pharmaceuticals, New York, NY) was added to the
samples for glucagon assay. Samples for assay of FFA and glycerol were
collected in EDTA and paraoxon (Sigma) to suppress lipoprotein lipase
activity (35). Samples for FFA, glycerol, glucose, and
tracer were immediately centrifuged, and the plasma was separated and
kept on ice for processing that day. Plasma for insulin assay was
stored at 20°C, and plasma for glucagon assay was stored at
70°C. Glucose was measured immediately after sampling with a YSI
2700 autoanalyzer (Yellow Springs Instrument, Yellow Springs, OH).
Samples for tracer assay were deproteinized using barium hydroxide and
zinc sulfate. The supernatants were then evaporated in a vacuum,
reconstituted in water, and counted in Ready Safe scintillation fluid
(Beckman liquid scintillation counter; Beckman, Fullerton, CA). Tracer
infusates were processed identically to plasma samples. Insulin was
measured by an ELISA originally developed for human serum or plasma by
Novo-Nordisk and adapted for dog plasma. The method is based on two
murine monoclonal antibodies that bind to different epitopes on insulin but not to proinsulin. Materials for the insulin assay, including the
dog standard, were kindly provided by Novo-Nordisk. Glucagon was
measured using a Linco RIA kit (Linco Research, St. Charles, MO) with
glucagon standards from Novo-Nordisk. FFA were measured using a kit
from Wako (NEFA C; Wako Pure Chemical Industries, Richmond, VA), which
utilizes a colorometric assay based on the acylation of
coenzyme-A. Glycerol was measured using a colorometric triglyceride kit from Sigma (GPO-Trinder), which uses glycerol kinase
and glycerol phosphate oxidase. This assay was modified to enhance
sensitivity (100, rather than 10 µl, was used for each sample, and
the assay mixture was centrifuged at 3,000 g for 5 min to
remove visible precipitates before reading at 540 nm).
Calculations.
Basal values were defined as the average of the t = 20 and t = 0 time points, and steady state was defined as
the average of the final two samples taken during each CHA dose period
(t = 45 and t = 60 min into each period).
EGP and glucose uptake were calculated using the equations of Finegood
et al. (12). To control for effects of CHA infusion on EGP
other than suppression of lipolysis, the change in EGP during CHA
infusion was subtracted from the average change in EGP during CHA + LI infusion. This calculation was also performed on the CHA + GLY experiments.
Statistics. All outcome variables were measured by general linear model ANOVA, which tested for an effect of animal, protocol, CHA dose, and an interaction between protocol and CHA dose. When a significant effect of CHA dose was identified, the ANOVA was repeated on each protocol individually, and when significance was reached, Dunnett's t-tests were used to compare individual doses to basal while correcting for multiple comparisons. When a significant effect of protocol was identified, ANOVA was repeated on each dose individually, and Tukey's t-test was used to make multiple comparisons between protocols when significance was reached. Linear trend tests were performed to examine dose dependency of outcome variables by CHA. Linear regression analysis between EGP and FFA was performed for both protocols. Paired t-tests were performed to compare replacement levels of insulin and glucagon to fasting levels. All statistics were performed using Minitab for Windows, release 12.22 (Minitab, State College, PA), except for linear trend tests and paired t-tests, which were performed using Microsoft Excel 2000; all calculations and statistics were done on an IBM-compatible computer.
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RESULTS |
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Euglycemic clamp values.
Glucose was clamped at its basal value throughout, with an average
coefficient of variation (CV) of 4.2%, and was not affected by
protocol or CHA dose [P = nonsignificant (NS); Table
1; Fig. 1]. Likewise, glucose specific activity
did not change significantly from its basal value (P = NS,
average CV=6%). Insulin was underreplaced by portal infusion of 0.2 mU · kg1 · min
1 (31 ± 2 vs. 99 ± 8 pM, basal vs. fasting, P < 0.001, paired t-test, Fig. 2) but
remained constant over the experimental protocol (P = NS). Basal glucagon levels were underreplaced from fasting levels (53 ± 6 vs. 73 ± 5 pg/ml, P < 0.001, paired t-test); however, glucagon levels increased over the
course of CHA infusion (P < 0.001). This increase in
glucagon tended to occur in the SAL control experiments as well (Table
2, P = 0.052).
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FFA and glycerol.
FFA were suppressed by CHA infusion in a dose-dependent manner
(P < 0.001 ANOVA, P < 0.005 linear
trend test; Table 1; Fig. 3). This
suppression was completely prevented by Liposyn and heparin infusion
(no effect of CHA dose on FFA levels in LI experiments, P = NS). Glycerol infusion did not alter CHA
suppression of FFA levels (P = NS vs. CHA protocol).
FFA levels tended to decline slightly during SAL controls, from
886 ± 173 to 541 ± 126 µM (P = 0.058).
Glycerol levels were also suppressed in a dose-dependent manner during
CHA infusion, from 0.80 ± 0.12 to 0.58 ± 0.09, 0.26 ± 0.10, and 0.19 ± 0.07 mg/dl (P < 0.001 ANOVA,
P < 0.05 linear trend test) but declined only slightly
and not significantly from 0.76 ± 0.16 to 0.60 ± 0.15, 0.69 ± 0.24, and 0.53 ± 0.11 mg/dl in the CHA + GLY
protocol (no effect of CHA dose, P = 0.31). Glycerol levels were not measured in the CHA + LI protocol due to
interference with the glycerol assay; however, they were likely
elevated above their basal levels due to the high glycerol content of
Liposyn and the lipolytic effect of heparin. Glycerol declined slightly during SAL control experiments (P < 0.05).
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Catecholamines.
CHA infusion alone caused an increase in mean epinephrine
(P = 0.07) and norepinephrine (P < 0.001), although the former did not quite reach significance secondary
to variable basal levels (Table 1). As a percentage of their basal
values, both catecholamines increased significantly with CHA infusion
(P < 0.01 for both comparisons, Fig.
4).
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Glucose fluxes.
Glucose fluxes did not change significantly during SAL control
experiments (Table 2). Glucose uptake increased significantly with CHA
dose, from 3.4 ± 0.2 to 3.8 ± 0.3, 3.9 ± 0.3, and
4.3 ± 0.4 mg·kg1·min
1 with
successive CHA doses (26% overall increase, P < 0.01 ANOVA, P < 0.05 linear trend test, Fig.
5). Glucose uptake was not different among the CHA only, CHA + LI, and CHA + GLY protocols. EGP
was significantly suppressed in a dose-dependent manner by CHA infusion alone (P < 0.001 ANOVA, P < 0.005, linear trend test; Fig. 6). Liposyn
infusion prevented the suppression of EGP (P < 0.05 vs. CHA protocol periods 2 and 3) and, in fact,
was associated with a tendency for EGP to increase (P = 0.08). EGP suppression was not changed by maintaining glycerol levels
near basal (P = NS vs. CHA only). To separate the
effects of lipolysis suppression from those of CHA itself, the
difference in EGP between the CHA + LI and the CHA only and
CHA + GLY protocols was calculated (Fig. 7, see METHODS). This net
suppression of EGP increased from 0.6 ± 0.2, 1.2 ± 0.2, and
1.6 ± 0.2 mg·kg
1·min
1 over the
three consecutive CHA doses and was not different with glycerol
infusion.
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DISCUSSION |
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Historically, insulin was believed to be an exclusively direct regulator of liver glucose production. However, recent evidence from this laboratory (1, 20, 25, 26, 29) and others (14, 17, 23) has suggested that at least some of insulin's effect may be indirect and may be mediated by the lowering of plasma FFA. To further examine this indirect (Single Gateway) mechanism, the present study was designed to test whether pharmacological suppression of FFA with constant insulinemia will reduce EGP. The adenosine agonist CHA was used to suppress lipolysis. When FFA was suppressed in a dose-response manner, EGP was suppressed as well. In fact, the relative suppression of EGP was strongly correlated with the suppression of FFA. Suppression of EGP occurred during constant insulin and glucose, slightly increasing glucagon, implying that EGP suppression was causally related to the suppression of lipolysis. This conclusion was supported by Liposyn plus heparin infusions, which maintained FFA and glycerol levels during CHA infusion and completely prevented CHA suppression of EGP. It appears that the majority of the effect of CHA to suppress EGP was due to a decrease in FFA levels, as maintenance of glycerol levels alone did not prevent CHA's effect.
Despite the correlation between FFA and EGP, the suppression of EGP was only ~40% complete with ~85% suppression of FFA (Fig. 8). This implies that either EGP is under only partial control of FFA or that CHA infusion had a separate confounding effect to bolster EGP in the face of FFA suppression. In previous studies from this laboratory (25, 26), we have found a more proportional relationship between FFA and EGP. Thus it seems likely that CHA must cause an increase in EGP separate from its effect on lipolysis. This is supported by the fact that EGP actually increased in the present Liposyn control experiments.
The effect of CHA to increase EGP could represent a direct effect of this drug on the liver or an indirect effect mediated by counterregulatory hormones. CHA has previously been demonstrated to directly stimulate glycogenolysis in the perfused rat liver (6). This likely is an effect of CHA to stimulate adenlyate cyclase, which occurs with a 50% effective dose (ED50) of 580 nM (28). Although CHA concentrations were not measured in the present study, they can be estimated. We are unaware of published data on the clearance of CHA in the dog; however, the effect of bolus injections of CHA (1-1,000 µg/kg) on vascular conductance in anesthetized dogs completely subsided within 20 min (A. S. Clanachan, personal communication). Although clearance cannot be assessed from biological effectiveness alone, these data suggest that CHA is cleared rapidly [half-time (t1/2) < 20 min]. Assuming a conservative estimate of t1/2 = 20 min, the expected CHA concentrations in the dose-response experiments are ~80, 240, and 800 nM for each successive dose. Thus, based on the ED50 of CHA stimulation of adenylate cyclase in vitro, it is quite possible that a direct effect of CHA to stimulate glycogenolysis was present to some degree, especially during the highest dose of CHA.
Supporting the possibility that there is an indirect effect of CHA to
stimulate EGP, both epinephrine and norepinephrine were elevated with
CHA infusion. The dose-response infusion of CHA caused an ~75 pg/ml
increase in epinephrine levels and ~150 pg/ml increase in
norepinephrine. Stevenson et al. (30) have shown that an
increase in epinephrine levels of 300 pg/ml can cause a transient 1 mg · kg1 · min
1 increase in
EGP. A similar rise in norepinephrine levels did not significantly
increase EGP (8); however, local norepinephrine release by
hepatic sympathetic nerves may have a greater effect on EGP than
suggested by the systemic levels. Glucagon levels also increased
slightly, from 58 ± 10 to 86 ± 13 ng/l. Although only
modest changes in systemic catecholamine and glucagon levels were seen
in the present study, these levels do not necessarily reflect the local
hepatic levels of these and other unmeasured counterregulatory
hormones. Additionally, growth hormone was suppressed and not replaced
or measured in this study. Therefore, it is not possible to rule out a
permissive or confounding effect of growth hormone in these
experiments. However, growth hormone should have differed between the
SAL control experiment and the CHA experiments only to the extent that
CHA affected its secretion or clearance.
These two effects of CHA to potentially increase EGP, direct stimulation of adenylate cyclase and stimulation of catecholamine levels, could have masked any effects of suppressed FFA levels to lower EGP. Therefore, the effect of CHA to lower EGP is even more impressive, given that it occurred in the face of elevated catecholamine levels and despite having a demonstrated direct effect to stimulate glycogenolysis in vitro.
In the present study, both FFA and glycerol levels were suppressed from their basal values by CHA infusion. Since Liposyn plus heparin increases both FFA and glycerol, control experiments were performed in which glycerol levels were clamped during CHA infusion (CHA + GLY). In these experiments, FFA were suppressed slightly but not significantly further than the CHA only experiments. EGP suppression was nearly identical in these two protocols, implying that the suppression of glycerol by CHA had little if any effect on EGP. This agrees with our previous finding that insulin suppression of EGP is prevented by Liposyn plus heparin infusion but is unaffected by glycerol infusion (26). Thus it appears that FFA play the primary role in modulating both insulin and CHA suppression of EGP.
Although we and others have shown that insulin suppression of EGP and FFA is well correlated and that preventing the fall in FFA will also prevent the fall in EGP (15, 16A, 25, 26), the Single Gateway Hypothesis remains to be proven unequivocally. To prove causality, it is also necessary to show that suppression of FFA levels, independent of changes in insulin, will cause a suppression of EGP. Many studies have addressed this question, yet a consensus remains elusive. The suppression of FFA levels has been shown to enhance hepatic suppression by insulin in normal rats (16) and in human subjects with non-insulin-dependent diabetes mellitus (27, 32) or cirrhosis (10); however, none of these studies showed a decline in EGP brought about by the lowering of FFA themselves. Fery et al. (11) found that the suppression of lipolysis with acipimox in normal humans raised whole body glucose production; however, this was likely due to declining insulin and increasing glucagon levels during this study (11). The inconsistency of previous studies may be related to lack of precise hormonal control, differences in species or population, and different time periods examined. Several studies have also shown that antilipolytic drugs such as nicotinic acid and acipimox can cause increases in glucagon, growth hormone, cortisol, and possibly catecholamines (11, 13, 21, 24).
The results of the present study agree in part with those from a recent study by Chen et al. (7) in which nicotinic acid administration to humans caused a suppression of FFA levels and gluconeogenesis, with no change in EGP due to a compensatory increase in glycogenolysis (7). The decline in gluconeogenesis was prevented by infusion of Liposyn and heparin. Like the present study, suppression of lipolysis resulted in an increase in plasma epinephrine levels, which likely contributed to the increase in glycogenolysis.
There are several possible mechanisms whereby FFA might control EGP. FFA have long been known to stimulate gluconeogenesis in vitro (9, 33). The precise mechanism of this stimulation is unknown, but several possibilities have been proposed. One involves the production of reducing equivalents by FFA oxidation in the hepatocyte (33, 34). In fact, several key enzymes in the gluconeogenesis pathway are stimulated by an increase in the NADH-to-NAD ratio (33). The oxidation of FFA also yields energy in the form of ATP, which can act to stimulate gluconeogenesis and inhibit glycolysis (34). Acetyl-CoA, the end product of FFA oxidation, has been shown to stimulate pyruvate carboxylase, a key regulatory enzyme for the activation of gluconeogenesis (34). Acetyl-CoA also reacts with oxaloacetate to form citrate, which inhibits phosphofructokinase (PFK-1), a key step in glycolysis. FFA might also raise cAMP levels (9), which would stimulate gluconeogenesis by well-defined mechanisms.
However, it is not likely that FFA control EGP solely by modulating gluconeogenesis. Puhakainen and Yki-Järvinen (24) demonstrated that suppression of gluconeogenesis alone does not decrease total hepatic glucose output, implying some sort of autoregulation that maintains EGP constant. If this is the case, then FFA must either regulate both gluconeogenesis and glycogenolysis separately or control flux through the glucose-6-phosphatase enzyme. In fact, glucose-6-phosphatase gene expression is stimulated by FFA both in vivo and in vitro (18, 19). Evidence for or against the acute regulation of glucose-6-phosphatase by FFA is elusive, as the measurement of this enzyme's activity in vivo remains problematic.
An important caveat in this study is that insulin was underreplaced during these experiments, although levels were maintained constant before and during CHA infusion. Thus hepatic underinsulinization may have had a permissive effect that allowed FFA to control EGP. Because we have previously shown that insulin has both direct and indirect effects on the liver to control EGP (20), minimizing hepatic insulin should minimize the direct effect, thereby increasing the power to observe an effect of FFA on EGP. Indeed, this may in part explain why some studies did not observe an effect of FFA suppression on EGP. Further studies are needed to fully elucidate the interaction between insulin and FFA on hepatic glucose metabolism.
Glucose uptake was increased by CHA infusion by ~25%. This was not changed by Liposyn or glycerol control infusion and therefore was not likely due to the effect of CHA to lower FFA or glycerol. It is possible that CHA had some direct effect on peripheral tissues to increase glucose uptake, perhaps by increasing regional blood flow (3).
In summary, we have shown that the suppression of FFA, independent of changes in glucose, insulin, or glucagon levels, can elicit suppression of EGP. With FFA suppression, EGP was suppressed ~40%, despite an approximate doubling of catecholamine levels. This relationship between lipolysis and glucose production can have important implications for the treatment of insulin resistance and diabetes. Perhaps treatment of these conditions should focus on the resistance of the adipocyte rather than that of the liver.
The stimulation of counterregulatory hormones (glucagon, growth hormone, and catecholamines) confounds direct testing of the Single Gateway Hypothesis using antilipolytic drugs such as CHA and nicotinic acid analogs. Therefore, additional studies linking FFA as a precise moment-to-moment regulator of EGP are justified.
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ACKNOWLEDGEMENTS |
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The authors would like to thank You-Yin Fu and Lisa Getty for their assistance with the experiments described in this study. We would also like to thank Beth Dunning for suggesting the use of CHA for this study. We are also indebted to Doug A. Davis, Donna M. Moore, and Erlinda Kirkman for their expert technical assistance.
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FOOTNOTES |
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This work was supported by research grants from the National Institute of Diabetes and Digestive and Kidney Diseases (DK-27619 and DK-29867). S.D. Mittelman performed this work while he was a predoctoral trainee supported by the National Institutes of Aging (T32-AG-00093) and a postdoctoral fellow supported by a mentor-based grant from the American Diabetes Association.
Address for reprint requests and other correspondence: R. N. Bergman, Diabetes Research Center, Keck School of Medicine, Dept. of Physiology and Biophysics, Univ. of Southern California, MMR 626, 1333 San Pablo St., Los Angeles CA 90089-9142 (E-mail: rbergman{at}usc.edu).
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.
Received 14 June 1999; accepted in final form 25 April 2000.
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