1 Division of Endocrinology/Diabetes/Metabolism and the General Clinical Research Center, Temple University Health Sciences Center, Philadelphia, Pennsylvania 19140; and 2 Department of Surgery, University of Medicine and Dentistry of New Jersey, School of Osteopathic Medicine, Stratford, New Jersey 08084
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ABSTRACT |
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Free fatty acids (FFA) have
been shown to inhibit insulin suppression of endogenous glucose
production (EGP). To determine whether this is the result of
stimulation by FFA of gluconeogenesis (GNG) or glycogenolysis (GL) or a
combination of both, we have determined rates of GNG and GL (with
2H2O) and EGP in 16 healthy nondiabetic
volunteers (11 males, 5 females) during euglycemic-hyperinsulinemic
(~450 pM) clamping performed either with or without simultaneous
intravenous infusion of lipid plus heparin. During insulin infusion,
FFA decreased from 571 to 30 µmol/l (P < 0.001), EGP
from 15.7 to 2.0 µmol · kg1 · min
1
(P < 0.01), GNG from 8.2 to 3.7 µmol · kg
1 · min
1
(P < 0.05), and GL from 7.4 to
1.7
µmol · kg
1 · min
1
(P < 0.02). During insulin plus lipid/heparin
infusion, FFA increased from 499 to 1,247 µmol/l (P < 0.001). EGP decreased 64% less than during insulin alone
(
5.1 ± 0.7 vs.
13.7 ± 3.4 µmol · kg
1 · min
1).
The decrease in GNG was not significantly different from the decrease
of GNG during insulin alone (
2.6 vs.
4.5
µmol · kg
1 · min
1, not
significant). In contrast, GL decreased 66% less than during insulin
alone (
3.1 vs.
9.2
µmol · kg
1 · min
1,
P < 0.05). We conclude that insulin suppressed EGP by
inhibiting GL more than GNG and that elevated plasma FFA levels
attenuated the suppression of EGP by interfering with insulin
suppression of GL.
gluconeogenesis; endogenous glucose production; glucagon; euglycemic-hyperinsulinemic clamping; free fatty acid
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INTRODUCTION |
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SEVERAL STUDIES HAVE SHOWN that raising plasma free fatty acid (FFA) partially inhibited insulin-induced suppression of endogenous glucose production (EGP; see Refs. 1, 4, 11, 12, 29, 32, 34). The mechanism for this FFA-mediated "hepatic insulin resistance" has remained uncertain. Because EGP is derived from gluconeogenesis (GNG) and glycogenolysis (GL), FFA could theoretically interfere with the inhibitory action of insulin on GNG or GL or a combination of both. There had been, until recently, no reliable information on FFA effects on either of these actions of insulin because in vivo rates of GNG could not be measured accurately. The reason was that hepatic GNG precursor-specific activities were unknown because of unpredictable dilution of the labeled precursors in the oxaloacetic acid pool, which is shared by GNG and the tricarboxylic acid cycle (18). Recently, several methods have become available that allow accurate noninvasive measurement of postabsorptive rates of GNG (15, 19, 21, 30). In the present study, we have used the 2H2O method, developed and validated by Landau et al. (19, 21), to determine effects of physiologically elevated plasma FFA concentrations on rates of GNG and GL during insulin-induced suppression of EGP.
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METHODS |
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Subjects
Sixteen healthy volunteers (11 males, 5 females) participated in three studies. Two male subjects participated in studies 1 and 2, and all other subjects participated in only one study. The subjects' ages, weights, heights, and body compositions are shown in Table 1. None of the subjects had a family history of diabetes or any other endocrine disorder, and none was taking any medications. Their weights were stable for at least 2 mo, and their diets contained a minimum of 250 g/day of carbohydrate for at least 2 days before the studies. Informed written consent was obtained from all subjects after explanation of the nature, purpose, and potential risks of these studies. The study protocol was approved by the Institutional Review Board of Temple University Hospital.
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Experimental Design
All subjects were admitted to the Temple University Hospital General Clinical Research Center the day before the studies. At 6:00 PM, the subjects ingested a meal of 14 kcal/kg body wt consisting of 53% carbohydrate, 15% protein, and 32% fat. After that, they fasted for the duration of the study but were allowed water ad libitum. At 11:00 PM, a baseline blood sample was obtained. The subjects then drank 2.5 g of 2H2O (99.9% hydrogen 2; Isotec, Miamisburg, OH)/kg body water. They drank the same amount of 2H2O 4 h later at 3:00 AM. Body water was assumed to be 50% of body weight in women and 60% of body weight in men. Additional water ingested during the fast was enriched to 0.5% with 2H2O to prevent dilution of the isotopic steady state. The studies began at 8:00 AM the next day with the subjects reclined in bed. A short polyethylene catheter was inserted in an antecubital vein for infusion of isotopes. Another catheter was placed in a contralateral forearm vein for blood sampling. This arm was wrapped with a heating blanket (~70°C) to arterialize venous blood. The following studies were performed. Study 1 was a 4-h euglycemic-hyperinsulinemic clamp. Plasma FFA levels decreased to very low levels because of insulin-induced inhibition of lipolysis. Study 2 was a 4-h euglycemic-hyperinsulinemic clamp with simultaneous intravenous infusion of lipid plus heparin. Plasma FFA levels rose because heparin-mediated lipolysis from the infused fat exceeded insulin-mediated antilipolysis in adipose tissue. The studies were performed in random order separated by 1-2 mo. Because plasma glucagon levels decreased during study 1, a third study was performed. Study 3 was a combined 4-h euglycemic-hyperinsulinemic-pancreatic clamp.Procedures
Euglycemic-hyperinsulinemic clamping with and without
lipid/heparin.
Regular human insulin (Humulin R; Eli Lilly, Indianapolis, IN) was
infused intravenously at a rate of 7 pmol · kg1 · min
1 for
4 h, and plasma glucose concentrations were clamped at ~5 mmol/l
by a feedback-controlled variable glucose infusion (study 1). Changes in specific activity of [3H]glucose were
avoided by adding [3-3H]glucose to the infusion of
unlabeled glucose. In study 2, euglycemic-hyperinsulinemic clamping was performed as described for study 1. In
addition, Liposyn II (Abbott Laboratories, North Chicago, IL), a 20%
triglyceride emulsion (10% safflower, 10% soybean oil), plus heparin
(0.4 U · kg
1 · min
1) were
infused at a rate of 1.5 ml/min for 4 h. Study 3 (combined euglycemic-hyperinsulinemic-pancreatic clamps) was identical
to study 1 except for the coinfusion of somatostatin (500 µg/h, to block endogenous pancreatic hormone secretion) and glucagon
(0.3 ng · kg
1 · min
1 to
replace basal glucagon secretion). Serial measurements of rates of GNG
and GL and glucose turnover, substrate, and hormone analyses were
obtained before and during the clamps.
Glucose turnover. Glucose turnover was determined with [3-3H]glucose, which was infused intravenously for 6 h, starting with a bolus of 40 µCi followed by a continuous infusion of 0.4 µCi/min. This produced steady-state tracer-specific activities within 120 min. Glucose was isolated from blood for determination of [3-3H]glucose specific activity, as described previously (33). Rates of total body glucose appearance (GRa) and disappearance (GRd) were calculated using Steele's equation for non-steady-state conditions (35). Rates of EGP were obtained by subtracting rates of glucose infused to maintain euglycemia (GIR) from GRa.
GNG.
Rates of GNG were determined with the 2H2O
method of Landau et al. (19-21). In the current
study, we have used the C-5-to-2H2O ratio,
which we have shown to give the same results as those obtained with the
C-5-to-C-2 ratio (5). 2H enrichment of C-5 was
determined by gas chromatography-mass spectrometry (Hewlett-Packard
5973 MSD, HP 5890 GC) as previously described (7).
Enrichment of 2H in plasma water was determined in all
subjects with an isotope ratio-mass spectrometer (PDZ Europa, London,
UK) by use of an ABCA-G module and a standard curve with known
enrichments ranging from 0.25 to 1.0%. 2H2O
enrichment was stable throughout the studies (see Fig. 2). To correct
for the dilution of the 2H on C-5 of glucose, which
occurred as a result of the infusion of unlabeled glucose during the
clamp, the C-5-to-2H2O ratio was multiplied by
GRa, i.e., the sum of exogenous and endogenous
glucose entering the glucose space (10, 13)
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Body composition. Body composition was determined by bioelectrical impedance analysis (24).
Substrate and hormone analyses. Plasma glucose was measured with a glucose analyzer (YSI, Yellow Springs, OH). Insulin was determined by RIA using an antiserum with minimal (0.2%) cross-reactivity with proinsulin (Linco, St. Charles, MO). Glucagon was determined by RIA with a kit from Linco. Cortisol was measured with a kit (Diagnostic Products, Arlington Heights, IL). Plasma FFA concentrations were determined with a kit (Wako Pure Chemicals, Richmond, VA). Plasma glycerol, lactate, alanine, glutamine, and glutamate were determined enzymatically.
Statistical Analysis
All data are expressed as means ± SE. Statistical analysis was performed using the SAS program (SAS Institute, Cary, NC). ANOVA with repeated measures was used to determine the differences in flux rates, substrates, or hormones across time points. Pairwise comparison for each time point was then performed if the overall comparison was statistically significant. ![]() |
RESULTS |
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Glucose, Insulin, and FFA
Basal glucose concentrations were 5.3 ± 0.3 and 5.1 ± 0.1 mmol/l in the insulin (study 1) and the insulin plus lipid (study 2) groups, respectively. Mean clamp glucose concentrations were 5.1 ± 0.1 and 5.4 ± 0.1 mmol/l, respectively, in the two groups (Fig. 1).
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Basal insulin levels were 38 ± 7 and 44 ± 9 pmol/l in the insulin and insulin plus lipid groups, respectively. Mean insulin levels during the clamps were 436 ± 23 and 432 ± 26 pmol/l, respectively.
Plasma FFA concentrations decreased from 571 ± 58 (at 0 min) to 30 ± 6 (at 240 min, P < 0.001) µmol/l in the insulin group. In the insulin plus lipid group, plasma FFA rose from 499 ± 62 (at 0 min) to 1,247 ± 177 (at 240 min, P < 0.001) µmol/l.
C-5 and 2H2O enrichment, C-5-to-2H2O ratio, and [3-3H]glucose Specific Activity
The C-5 atom percent excess (APE) and the C-5-to-2H2O ratio both declined during the clamps as a result of the glucose infusions, but there were no significant differences between the insulin and the insulin plus lipid groups (Fig. 2).
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2H2O APEs were the same in both groups and did not change during the clamps.
[3-3H]glucose specific activity was stable throughout the studies and was not different when the two groups were compared.
GRa, GRd, and GIR
Effects of insulin and insulin plus lipid on GRa, GRd, and GIR are shown in Table 2. Lipid inhibited insulin-stimulated GRd and GIR by 20 and 40%, respectively, at 240 min.
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EGP, GNG, and GL
EGP decreased from 15.7 ± 1.4 (at 0 min) to 2.0 ± 2.5 (at 240 min, P < 0.001) µmol · kg
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GNG decreased from 8.2 ± 0.6 (at 0 min) to 3.7 ± 1.4 (P < 0.05 at 240 min)
µmol · kg1 · min
1 in the
insulin group. In the insulin plus lipid group, the decrease in GNG
(from 7.1 ± 0.8 to 4.6 ± 1.0 µmol · kg
1 · min
1) was
not statistically significant. The difference between the two groups
also was not statistically significant.
GL decreased continuously (from 7.4 ± 1.2 at 0 min to 1.7 ± 1.6 at 240 min, P < 0.01) in the insulin group. In
the insulin plus lipid group, GL initially (0-120 min) decreased
in parallel with the insulin alone group (from 9.1 ± 0.9 to
0.7 ± 1.3 µmol · kg
1 · min
1,
P < 002). However, after 120 min, GL rose so that at
240 min GL was significantly higher in the lipid-infused group
(6.1 ± 1.6 vs.
1.7 ± 1.6 µmol · kg
1 · min
1,
P < 0.01).
GNG Precursors, Glucagon, and Cortisol
GNG precursor concentrations (the sum of plasma alanine, glutamine, glutamate, lactate, and glycerol concentrations) did not change in either group and were not significantly different in the two groups at any time (Fig. 4). Individual precursor levels are shown in Table 3. In the insulin plus lipid study, glycerol was higher than in the insulin alone study (probably because of heparin-induced lipolysis), whereas alanine and glutamic acid concentrations were lower.
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Plasma glucagon concentrations decreased in the insulin group from 52 ± 3 at 0 min to 31 ± 3 pg/ml at 240 min (P < 0.01). Glucagon concentrations did not change in the insulin plus lipid group [56 ± 3 vs. 51 ± 5 pg/ml, not significant (NS)]. As a result, glucagon concentrations were significantly higher in the insulin plus lipid compared with the insulin group during the last 2 h of the studies.
Cortisol concentrations decreased to a similar extent in the insulin group (from 351 ± 101 to 216 ± 60 nmol/l, P < 0.05) and in the insulin plus lipid group (from 310 ± 87 to 186 ± 53 nmol/l, P < 0.05). The two groups were not different from each other at any time.
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DISCUSSION |
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The results of this study confirmed previous reports showing that
physiological increases in plasma FFA concentrations partially inhibited the insulin suppression of EGP (1, 4, 11, 12, 29, 32,
34). When FFA levels in the current study decreased to <100
µM under the influence of postprandial-like insulin concentrations (~450 pM), EGP fell from 15.7 ± 1.4 to 2.0 ± 2.5 µmol · kg1 · min
1 in
4 h. In contrast, when FFA levels rose (to ~1,200 µM), EGP decreased ~60% less (from 15.8 ± 0.7 to 10.6 ± 1.4 µmol · kg
1 · min
1).
Methodological Considerations
To determine whether the difference in EGP suppression between the two groups was the result of inhibition of insulin action on GNG or GL or a combination of both, we measured GNG with the 2H2O method of Landau et al. (19-21). This method determines the part of GNG that contributes to GRa in the circulation. Under postabsorptive (low-insulin) conditions, when glycogen synthesis is negligible (19, 28, 37), this technique provides reliable estimates of GNG, i.e., of glucose derived from all nonglucose precursors. Under hyperinsulinemic conditions, as in our study, two problems arise. 1) The [2H]glucose derived from GNG that enters the circulation is diluted by nonlabeled glucose infused to maintain euglycemia. This dilution effect can be corrected by multiplying the C-5-to-2H2O ratio by GRa (i.e., the sum of exogenous and endogenous glucose entering the glucose space; see Refs. 10 and 13). 2) Hyperinsulinemia stimulates glycogen synthesis and thus the flux of GNG-derived glucose into glycogen. To the extent that this glucose remains in glycogen, i.e., does not return to the circulation, GNG will be underestimated. Hence, under hyperinsulinemic conditions, the 2H2O method provides a minimal estimate of all GNG-derived glucose but an accurate account of the GNG-derived glucose contributing to GRa either directly or via glycogen. GL is not measured with this technique but is calculated as the difference between EGP and GNG. Consequently, it represents GL-derived glucose entering the blood plus the amount of GNG-derived glucose remaining in glycogen.Effect of Insulin
In the present study, GNG declined from 8.2 to 3.7 µmol · kgGiven that a reduction in GNG could account for only a small part, it
follows that most of the insulin-induced suppression of EGP had to be
the result of suppression of GL. Indeed, GL decreased from 7.4 to 1.7
µmol · kg
1 · min
1 in
our study, from 4.5 to
0.9 µmol · kg fat-free
mass
1 · min
1 in the study by
Gastaldelli et al. (13), and from 5.6 to 2.2 µmol · kg
1 · min
1 in the
study by Edgerton et al. (10). Hence the currently
available data indicate that insulin suppresses EGP primarily by
suppressing GL.
Effect of Insulin Plus Lipid
Raising plasma FFA did not change GNG beyond the changes seen with insulin alone. This was somewhat surprising since FFA has been shown to stimulate GNG in animal experiments (14, 16, 17, 39) and also in human subjects (3, 7). The human studies, however, were performed under basal insulin conditions and therefore were not comparable to the present study, where insulin levels were elevated to approximately eightfold over basal levels.During the initial 2 h, FFA also did not seem to affect insulin-mediated suppression of GL, i.e., GL decreased rapidly and at comparable rates during both insulin and insulin plus lipid infusions. After 2 h, however, GL continued to decrease in the insulin group, whereas GL rose in the insulin plus lipid group so that, after 3 and 4 h, GL was significantly higher in the insulin plus lipid than the insulin group.
How Did FFA Inhibit Insulin Suppression of GL?
Insulin infusions in the periphery decrease levels of glucagon (8, 10, 13), a hormone that has been established as a potent physiological regulator of GL (22, 25, 27). In study 1, glucagon levels decreased from 52 ± 3 to 31 ± 3 pg/ml during insulin infusion, whereas no change in plasma glucagon concentration occurred during insulin plus lipid infusions (56 ± 3 vs. 51 ± 5 pg/ml, NS). This suggested the possibility that the complete inhibition of GL during insulin infusion may have reflected the combined suppressive effects of increased insulin and decreased glucagon levels, whereas the absence of a significant inhibition of GL during insulin plus lipid infusion (at 240 min) may have been the result of continued GL stimulation by glucagon. Therefore, it was necessary to perform a control experiment (study 3) in which glucagon was prevented from decreasing. The results showed similar inhibition of GL in response to hyperinsulinemia regardless of whether glucagon levels decreased (study 1) or remained unchanged (study 3) (Fig. 5). Thus they demonstrated that the insulin-induced fall in GL observed in study 1 was unrelated to the decrease in plasma glucagon and supported data by others showing that hyperinsulinemia alone is sufficient to completely suppress EGP (and thus GL; see Ref. 36). On the other hand, the delay, by at least 2 h, in onset of FFA-induced inhibition of insulin action on GL is very similar to the delay in onset of FFA-induced inhibition of insulin-stimulated glucose uptake in skeletal muscle (reviewed in Ref. 2). Thus it seems likely that FFA caused hepatic insulin resistance by interfering with the inhibitory action of insulin on GL, which has been reported to result primarily from shunting of GL-derived glucose into glycogen (28).
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In summary, we have confirmed studies by others showing that, in healthy, nonobese volunteers, insulin suppresses EGP primarily by inhibiting GL. We have expanded these findings by showing that elevated plasma FFA levels attenuate insulin suppression of EGP by interfering with insulin suppression of GL.
These observations may have physiological and pathophysiological significance. In healthy subjects, FFA-mediated attenuation of insulin-induced EGP suppression may prevent hypoglycemia after a protein- and fat-rich meal when insulin levels are elevated more than glucose levels. In diabetic patients, partial unresponsiveness of EGP to hyperinsulinemia is a major problem contributing to hyperglycemia (9). These patients commonly have elevated plasma FFA levels that may contribute to this problem by inhibiting insulin-mediated suppression of GL.
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ACKNOWLEDGEMENTS |
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We thank the nurses of the General Clinical Research Center for help with the studies and for excellent patient care, and Constance Harris Crews for typing the manuscript.
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FOOTNOTES |
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This work was supported by National Institutes of Health Grants R01-AG-07988 (to G. Boden) and RR-349.
Address for reprint requests and other correspondence: G. Boden, Temple Univ. Hospital, 3401 North Broad St., Philadelphia, PA 19140 (E-mail: bodengh{at}tuhs.temple.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. Section 1734 solely to indicate this fact.
First published March 5, 2002;10.1152/ajpendo.00429.2001
Received 24 September 2001; accepted in final form 1 March 2002.
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