Effect of hyperglycemia-hyperinsulinemia on whole body and
regional fatty acid metabolism
Labros S.
Sidossis,
Bettina
Mittendorfer,
David
Chinkes,
Eric
Walser, and
Robert R.
Wolfe
Metabolism Unit, Shriners Burns Institute, and the Departments of
Surgery, Anesthesiology, and Internal Medicine, The University of
Texas Medical Branch, Galveston, Texas 77550
 |
ABSTRACT |
The effects of combined
hyperglycemia-hyperinsulinemia on whole body, splanchnic, and leg fatty
acid metabolism were determined in five volunteers. Catheters were
placed in a femoral artery and vein and a hepatic vein.
U-13C-labeled fatty acids were
infused, once in the basal state and, on a different occasion, during
infusion of dextrose (clamp; arterial glucose 8.8 ± 0.5 mmol/l).
Lipids and heparin were infused together with the dextrose to maintain
plasma fatty acid concentrations at basal levels. Fatty acid
availability in plasma and fatty acid uptake across the splanchnic
region and the leg were similar during the basal and clamp experiments.
Dextrose infusion decreased fatty acid oxidation by 51.8% (whole
body), 47.4% (splanchnic), and 64.3% (leg). Similarly, the percent
fatty acid uptake oxidized decreased at the whole body level (53 to
29%), across the splanchnic region (30 to 13%), and in the leg (48 to
22%) during the clamp. We conclude that, in healthy men, combined
hyperglycemia-hyperinsulinemia inhibits fatty acid oxidation to a
similar extent at the whole body level, across the leg, and across the
splanchnic region, even when fatty acid availability is constant.
liver; blood flow; hepatic vein; diabetes; obesity
 |
INTRODUCTION |
WE HAVE RECENTLY SHOWN in human volunteers that
intracellular glucose availability directly regulates fatty acid
oxidation in the setting of constant free fatty acid (FFA) availability (25). This notion represents the exact opposite of the concept of fatty
acid-mediated regulation of glucose oxidation originally proposed by
Randle et al. (15), namely, that fatty acid availability and oxidation
control the rate of glucose disposal. In subsequent papers, we
presented evidence suggesting that glucose elicits its effect on fat
oxidation by controlling the rate of fatty acid entry into the
mitochondria (23, 24). According to those findings (23, 24), an
increase in glycolytic flux inhibits long-chain fatty acid entry into
the mitochondria, possibly via inhibition of carnitine
palmitoyltransferase I (CPT I).
The traditional "glucose-fatty acid cycle" hypothesis was
developed from studies performed in rat diaphragm and heart muscle (16). Since its introduction, the operation of the glucose-fatty acid
cycle has been extensively examined in resting human volunteers, with
conflicting results (see Refs. 1, 2, 7, 9, 26, 27, 29). It may be that
the difficulty in confirming the findings of Randle and co-workers (15,
16) at the whole body level at rest is that only specific tissues
respond as predicted by the in vitro studies, and that the contribution
of those tissues does not account for a sufficient percentage of
resting substrate metabolism to be detected at the whole body
level. In this regard, although skeletal muscle comprises a large
percentage of the lean body mass, at rest it is less metabolically
active than the splanchnic region. It is thus possible that whole
body responses that have been previously observed predominantly
reflected the splanchnic region metabolism, and that different
responses in muscle tissue were obscured.
In our previous studies (24, 25), the effect of glycolytic flux on
fatty acid oxidation was determined at the whole body level. This
precluded drawing any conclusions as to the nature of glucose-fatty
acid interaction in specific tissues, because whole body measurements
reflect the sum of kinetics and oxidation of the various regions of the
body. Therefore, in the current study we examined the effect of
dextrose infusion, causing moderate hyperglycemia (~8 mM) and
hyperinsulinemia (35.8 ± 11.4 µU/ml) on fatty acid kinetics and
oxidation simultaneously at the whole body level, across the
splanchnic region, and across the leg in five healthy volunteers.
Plasma FFA concentration was maintained constant via exogenous infusion
of lipids and heparin during dextrose infusion, whereas insulin
concentration was allowed to change in response to dextrose infusion.
With this approach we created an experimental model in human volunteers
with a similar metabolic profile to insulin-resistant states with
respect to blood glucose, insulin, and FFA concentrations. Our findings
are also pertinent to the common circumstance of intravenous glucose
infusions for nutritional purposes in hospitalized patients.
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METHODS |
Volunteers
Five male volunteers (age 29 ± 2 yr, weight 76 ± 5 kg, height
177 ± 5 cm) participated in this study. All volunteers were healthy, as indicated by comprehensive history, physical examination, and standard blood and urine tests, and had maintained stable weights
for
3 mo before the studies. The Institutional Review Board and the
General Clinical Research Center (GCRC) of the University of Texas
Medical Branch at Galveston approved the experiments. Informed consent
was obtained for all procedures.
Materials
U-13C-labeled fatty acids, 86.2%
enriched, were obtained from Cambridge Isotope Laboratories (Andover,
MA). The composition of the fatty acid mixture was palmitic acid (16:0)
51.7%, palmitoleic acid (16:1) 9.3%, stearic acid (18:0) 5.5%, oleic
acid (18:1) 17.9%, linoleic acid (18:2) 14.1%, and linolenic acid
(18:3) 1.5%. Human albumin 5% was purchased from Baxter Healthcare
(Glendale, CA). The lipid emulsion (Intralipid, 20%), containing
linoleic (50%), oleic (26%), palmitic (10%), linolenic (9%), and
stearic (3.5%) acids, was obtained from Kabi (Clayton, NC). Heparin
came from Elkins Sinn (Cherry Hill, NJ), and indocyanine green came from Ceton Dickenson Microbiology Systems (Cocksville, MD).
Experimental Design
Volunteers were studied in the basal state (overnight fast) and, on a
different occasion, during 15 h of hyperglycemia-hyperinsulinemia. The
order of the studies was randomized. The volunteers were admitted to
the GCRC at the University of Texas Medical Branch at Galveston and
received a light meal at 5 PM. The meal contained 30% of energy as
fat, 20% as protein, and 50% as carbohydrate. At 9 PM of the same
day, catheters were placed percutaneously into an antecubital vein for
infusion and into a contralateral dorsal hand vein for sampling. The
catheters were kept patent by infusion of 0.9% NaCl. After the
volunteers had rested for 30 min, background blood and breath samples
were collected, and one of the following two randomly assigned
experimental protocols was performed.
Protocol 1: basal state.
Infusion of the U-13C-labeled
fatty acid mix (no prime, constant infusion = 0.035 µmol · kg
1 · min
1)
bound to human albumin was started through the arm vein and maintained
until the end of the study. The bicarbonate pool was primed using
NaH13CO3
(25 µmol/kg). At 7 AM the following morning, the volunteers were
transferred to the Angiography and Interventional Radiology Center of
the University of Texas Medical Branch, in the same building as the
GCRC, where femoral artery, hepatic vein, and femoral vein catheters
were inserted, as described in Procedures. Thirty to sixty
minutes after catheter placement, the volunteers were transferred back
to the GCRC for completion of the study.
The U-13C-labeled fatty acid
infusion continued uninterrupted during catheter placement by use of a
battery-operated pump and for two more hours after volunteers returned
to the GCRC. Blood samples were drawn from the femoral artery, femoral
vein, and hepatic vein at 100, 110, and 120 min after volunteers
returned to the GCRC. At the same time points, breath samples were
collected for determination of breath
CO2 carbon enrichment.
Whole body oxygen consumption
(
O2) and carbon dioxide
production (
CO2) were
measured over 30 min during the last hour of the study.
Splanchnic and leg blood flow were determined using a constant infusion
of indocyanine green, as described in Procedures. After
completion of the study all catheters were removed, and the volunteers
remained in the hospital for several hours for observation.
Protocol 2: glucose infusion (clamp).
Protocol 2 was the same as
protocol 1, except that a continuous
infusion of 15% dextrose was started at the same time as the labeled
fatty acid infusion (i.e., 9 PM) and maintained until the end of the
study. Dextrose was infused at a rate designed to increase blood
glucose concentration to ~8 mmol/l. Blood glucose levels were
measured every 30 min, and dextrose infusion was appropriately adjusted
to maintain blood glucose concentration at ~8 mmol/l. Blood potassium
concentration was measured every 2 h, and a variable infusion of
potassium chloride was given to maintain a constant plasma potassium
concentration. Lipids (0.7 ml · kg
1 · h
1)
were infused together with heparin (bolus of 7.0 U/kg; continuous infusion of 7.0 U · kg
1 · h
1)
to prevent the expected insulin-induced decline in plasma FFA concentration.
Procedures
Catheter placement.
In the morning of the study, volunteers were brought to a vascular
radiology suite, where the right groin was prepared and draped in a
sterile fashion. A lead glove was placed over the genitalia before the
procedure. After patient preparation, the right common femoral vein was
punctured and a 6-Fr sheath was placed. Through this sheath, a straight
5-Fr catheter with several side holes near its tip was manipulated into
the right or middle hepatic vein. This catheterization was performed
using a deflecting-tip 0.035' guidewire within the straight
catheter. After the catheter had been positioned into the hepatic vein,
a digital venogram was performed to verify placement, and both the
sheath and catheter were infused with heparinized saline to maintain
patency. The position of the catheter was confirmed again by a plain
view abdominal X ray immediately after the end of the study. A short,
straight 4-Fr catheter was then placed retrograde into the right common femoral artery, and it was also connected to a pressurized flush setup.
After both catheters and the sheath were sutured in place, a sterile
transparent dressing was used to cover the vascular entry sites.
Blood flow.
Blood flow was determined using a constant infusion of indocyanine
green dissolved in 0.9% saline. The dye was infused through the
femoral artery catheter at the rate of 0.5 mg/min for 55 min during the
last hour of the study, and blood samples were taken at 40, 45, 50, and
55 min simultaneously from the hepatic vein, the femoral vein, and an
antecubital vein. The concentrations of the dye in the infusate and in
serum samples were determined using a spectrophotometer set at 805 nm.
Splanchnic plasma flow (SPF) was calculated via the formula SPF = I/(PV
HV), where I is the infusion rate of the dye, PV is the
concentration of dye in an antecubital vein, and HV is the
concentration of dye in the hepatic vein. Splanchnic blood flow (SBF)
was calculated via the formula SBF = SPF/(1
Hct), where Hct is
the hematocrit. Leg plasma flow (LPF) was calculated via the formula
LPF = I/(FV
PV), where I is the infusion rate of the dye, PV is
the concentration of dye in an antecubital vein, and FV is the
concentration of dye in the femoral vein of the leg into which the dye
is infused. Leg blood flow (LBF) was calculated via the formula LBF = LPF/(1
Hct).
Determination of acetate correction factor.
On a different occasion, a 15-h primed (45 µmol/kg), continuous
infusion (1.5 µmol · kg
1 · min
1)
of [U-13C]acetate was
performed in the postabsorptive state to determine the "acetate
correction factor," i.e., the acetate-carbon recovery rate, for use
in the calculation of fatty acid oxidation rate (21). Unlike the
traditional "bicarbonate correction factor," the acetate
correction factor fully accounts for label fixation occurring at any
point between the entrance of labeled acetyl-CoA into the tricarboxylic
acid cycle and the appearance of labeled CO2 in breath (21, 22). It was not
necessary to determine acetate carbon recovery across the splanchnic
region and the leg in this study, because we have recently shown that
acetate recovery across these sites is similar to whole body acetate
recovery (13).
Assays
Breath.
Ten milliliters of expired air were injected into evacuated tubes for
determination of the
13CO2-to-12CO2
ratio. Briefly, CO2 was isolated
from the breath samples before analysis by isotope ratio mass
spectrometry (IRMS; SIRA VG Isotech, Cheshire, UK) by passage through a
water trap followed by condensation in a liquid nitrogen trap to allow
other gases to be evacuated. The
13CO2-to-12CO2
ratio was then determined by IRMS. Results are presented as percent
enrichment, i.e.,
13CO2-to-12CO2
ratio times 100.
Blood.
BLOOD CO2 ANALYSIS.
All blood samples for CO2 analysis
were collected into prechilled tubes containing sodium heparin. Blood
CO2 concentration was measured
immediately using a 965 Ciba Corning
CO2 Analyzer, and the remaining
blood samples were kept frozen until further analysis. For the
determination of blood CO2
enrichment, 5-10 ml of hyperphosphoric acid were added to 1 ml
blood in a sealed tube to release the
CO2. The
13C-to-12C
ratio in the headspace was then determined by IRMS. Results are
presented as percent enrichment, i.e.,
13C-to-12C
ratio times 100.
PLASMA FFA ENRICHMENT AND SUBSTRATE CONCENTRATIONS.
Blood samples (6 ml) for determination of substrate concentration and
enrichment were collected into prechilled tubes containing 120 µl of
0.2 M EGTA to prevent in vitro lipolysis, and plasma was immediately
separated by centrifugation and frozen until further processing. For
determination of plasma fatty acid enrichment, the fatty acids were
extracted from plasma, isolated by thin-layer chromatography, and
combusted (Elemental Analyzer, Carlo Erba 1500), and the
13C-to-12C
ratio was determined by IRMS. Individual and total plasma fatty acid
concentrations were determined by gas chromatography (GC; Hewlett-Packard 5890), with heptadecanoic acid as internal standard. Plasma
-hydroxybutyrate concentration was determined
enzymatically (Sigma Diagnostics, St. Louis, MO). Plasma glucose
concentration was measured on a 2300 STAT analyzer (Yellow Springs
Instruments, Yellow Springs, OH). Plasma insulin concentration was
determined using a radioimmunoassay method (INCSTAR, Stillwater, MN).
Calculations
The rate of appearance of fatty acids in plasma
(Ra) was determined by dividing
the fatty acid tracer infusion rate (I) by the arterial fatty acid
carbon enrichment
(EA)
The fatty acid kinetic parameters for the splanchnic region
were calculated using femoral artery and hepatic venous measurements and splanchnic blood flow, whereas the kinetic parameters for the leg
were determined using femoral artery and femoral venous measurements
and leg blood flow. All values calculated for the leg represent
kinetics and oxidation across one leg only. The net rate of FFA uptake
or release across the splanchnic region (NBspl) and the leg
(NBleg) was determined by
multiplying the arteriovenous FFA concentration difference times the
plasma flow, that is
where
CA, CHV, and CFV are arterial, hepatic venous, and femoral venous
concentrations of FFA, respectively, and HPF and LPF are hepatic and
leg plasma flow, respectively.
The percentage of FFA taken up by either the splanchnic region
(%FFAox spl) or leg
(%FFAox leg) that is
released as CO2 was calculated by
dividing the arteriovenous labeled
CO2 concentration difference by
the arteriovenous FFA tracer concentration difference
where EA CO2,
EHV CO2, and
EFV CO2 are the enrichments
of CO2 in the artery, hepatic
vein, and femoral vein, respectively, CA CO2,
CHV CO2, and
CFV CO2 are the
concentrations of CO2 in the
artery, hepatic vein, and femoral vein, respectively, and EA, EHV, and
EFV are the enrichments of FFA in the artery, hepatic vein, and femoral
vein, respectively.
The fractional extraction of labeled FFA by the splanchnic region
(%FFAex spl) and the leg
(%FFAex leg) was
determined by dividing the uptake of label by the arterial
concentration of label
The absolute rate of uptake of FFA by the splanchnic region
(FFA Rd spl) and leg
(FFA Rd leg) was
determined by multiplying the fractional extraction of labeled FFA by
the arterial (unlabeled) plasma FFA concentration times the plasma flow
Plasma fatty acid oxidation across the splanchnic region
(FFAox spl) and the leg
(FFAox leg) was
subsequently calculated by multiplying the absolute rate of FFA uptake
across each region by the percentage of FFA uptake that is released as
CO2. This value was then divided
by the acetate correction factor (ar) obtained using labeled acetate
infusion.
The percentage of FFA taken up by either the splanchnic region
(%FFAket spl) or leg
(%FFAket leg) that is
released as ketones was calculated by dividing the release of ketones
by the uptake of FFA
where
CKA, CKHV, and CKFV are the ketone concentrations in the artery,
hepatic vein, and femoral vein, respectively.
The percentage of Ra FFA which is
taken up by the splanchnic region
(%RaFFAspl)
and by the leg
(%RaFFAleg)
is calculated by dividing the absolute uptake of FFA by
Ra FFA.
Statistical Analysis
Results are reported as means ± SE. The effects of the glucose
infusion on the various parameters were evaluated using a two-tailed paired Student's t-test. Significance
was set at the 0.05 level.
 |
RESULTS |
Systemic and Regional Substrate Concentrations
Plasma glucose concentrations were significantly higher during the
clamp compared with the basal state (Fig.
1A).
To achieve the desired plasma glucose levels in the clamp experiments,
dextrose was infused at an average rate of 608 ± 49 mg/min. In
response to dextrose infusion, insulin concentration increased from 5.5 ± 1.1 in the basal to 35.8 ± 11.4 µU/ml during the clamp
(P < 0.05).

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Fig. 1.
Plasma glucose (A), free fatty acids
(FFA, B), and -hydroxybutyrate
( -OH butyrate, C) concentrations
in the artery, hepatic vein, and femoral vein in basal state (open
bars) and during hyperglycemia (hatched bars). Values are means ± SE for 5 volunteers. * P < 0.05.
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We were able to maintain arterial plasma FFA concentration similar in
the basal and clamp experiments via infusion of lipids and heparin
(Fig. 1B). This was important,
because if we had allowed fatty acid availability to the splanchnic
region and leg to vary between the two trials, we would not have been
able to differentiate the direct effects of
hyperglycemia-hyperinsulinemia from the effect of decreasing fatty acid
availability on regional fatty acid kinetics and oxidation.
The concentration of
-hydroxybutyrate (
-OHB) was significantly
higher in the hepatic vein than in the artery and the femoral vein in
the basal experiments (Fig. 1C).
During hyperglycemia,
-OHB concentration decreased to levels not
different from zero (Fig. 1C).
Whole Body and Regional Fatty Acid Kinetics and Oxidation
Plasma fatty acid carbon enrichment was constant during the last 20 min
of labeled fatty acid infusion (Table 1).
These values were used in the calculation of fatty acid kinetics and
oxidation.
The rates of appearance of fatty acids in plasma coming from endogenous
(basal state) or endogenous plus exogenous (clamp) sources were 4.8 ± 0.6 and 4.4 ± 0.6 µmol · kg
1 · min
1,
respectively. Net uptake of fatty acids across the splanchnic region
was similar in the basal state and the clamp experiments (Fig.
2). We did not observe significant net
fatty acid uptake or release across the leg in either state (i.e.,
basal vs. clamp).

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Fig. 2.
Net fatty acid uptake (positive value) or release (negative value)
across splanchnic region and leg in basal state (open bars) and during
hyperglycemia (hatched bars). Values are means ± SE for 5 volunteers.
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Fatty acid extraction was similar across the splanchnic region and the
leg both in the basal state and during the clamp (Fig. 3). In the basal state, the splanchnic
region and the leg accounted for 28.7 ± 2.7 and 12.5 ± 2.4% of
total FFA disappearance, respectively, whereas during
hyperglycemia-hyperinsulinemia, the splanchnic region and the leg
accounted for 36.6 ± 16.9 and 10.3 ± 3.5% of total FFA
disappearance (Fig. 4).

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Fig. 3.
FFA extraction (%) across splanchnic region and leg in basal state
(open bars) and during hyperglycemia (hatched bars). Values are means ± SE for 5 volunteers.
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Fig. 4.
Percent contribution of splanchnic region and leg to fatty acid
disappearance in basal state (open bars) and during hyperglycemia
(hatched bars). Values are means ± SE for 5 volunteers.
Rd, rate of uptake.
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Plasma CO2 carbon enrichment was
constant over the last 20 min of labeled fatty acid infusion (Table
2). These values were used to calculate
fatty acid oxidation. The decrease in enrichment during the clamp
experiments compared with the basal reflects a decrease in labeled
fatty acid oxidation and/or increased unlabeled substrate
oxidation (e.g., glucose).
In the basal state, splanchnic region and leg fatty acid oxidation
accounted for 15 ± 2 and 11 ± 1.5% of whole body fatty acid
oxidation, respectively (Fig. 5).
Approximately 50% of the fatty acids taken up by the leg were oxidized
to CO2 under these conditions, a
figure similar to that calculated for the whole body level (Fig.
6). In contrast, only 30% of the fatty
acids taken up by the splanchnic region were oxidized to
CO2 (Fig. 6), with an additional
20% of the fatty acids appearing as ketones in the hepatic vein,
bringing the total percentage of fatty acids taken up by the splanchnic
region that were oxidized to levels similar to those observed across
the leg and the whole body.

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Fig. 5.
Percent contribution of splanchnic and leg fatty acid oxidation to
whole body fatty acid oxidation in basal state (open bars) and during
hyperglycemia (hatched bars). Values are means ± SE for 5 volunteers.
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Fig. 6.
Percentage of fatty acid uptake that was oxidized to
CO2 across splanchnic region and
leg in basal state (open bars) and during hyperglycemia (hatched bars).
Values are means ± SE for 5 volunteers.
* P < 0.05.
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Compared with the basal state, hyperglycemia-hyperinsulinemia
significantly impaired whole body and regional fatty acid oxidation (Table 3), whereas it did not affect the
relative contribution of the various regions on total fatty acid
oxidation (17 ± 3 and 8 ± 1% across the splanchnic region and the
leg, respectively; Fig. 5). The decrease in whole body and regional
fatty acid oxidation was independent of FFA availability, as the
availability of fatty acids at the whole body level and across the
tissues was similar in the basal and clamp experiments (Figs.
1B and 2).
Hyperglycemia-hyperinsulinemia similarly decreased the percentage of
fatty acids taken up that were oxidized to
CO2 by ~50% at the whole body
level, across the splanchnic region, and across the leg (Fig. 6).
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Table 3.
Plasma fatty acid oxidation at whole body level, across splanchnic
region, and across leg in basal state and during hyperglycemia
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Splanchnic and Leg Blood Flow
Splanchnic blood flow increased significantly during the clamp from
1,121 ± 63 ml/min at basal to 1,231 ± 65 ml/min in the clamp
(P < 0.05). Leg blood flow was 488 ± 20 ml/min in the basal and 443 ± 41 ml/min during the clamp (not significant).
Effect of Exogenous Glucose on Blood and Breath
CO2 Carbon Enrichment
Infusion of unlabeled "cold" glucose to increase blood glucose
concentration during the clamp experiments is expected to increase breath and blood CO2 carbon
enrichment (18, 28). To account for the "unlabeled" glucose
contribution to CO2 carbon
enrichment, it is usually necessary to repeat the clamp experiments
without tracer infusion, measure breath
CO2 carbon enrichment, and use this number as the background enrichment for calculation of fatty acid
oxidation during the tracer infusion experiments (24). Because of the
invasiveness of the experimental design in the present studies, we
decided instead to infuse the fatty acid tracer at a high rate to
increase the breath and blood CO2
carbon enrichment enough so that the contribution of naturally
occurring 13C in glucose would
become negligible. Thus, whereas the average breath
CO2 carbon enrichments in the
present study were
1.4e
03 ± 1.0e
04,
infused glucose is expected to contribute no more than
5e
05 to
7.0e
05 to
CO2 carbon enrichment (24).
Furthermore, any effect of the infused glucose on
13C enrichment would have caused
us to underestimate the extent to which the fatty acid oxidation was
suppressed by glucose infusion.
 |
DISCUSSION |
We had hypothesized that the difficulty in confirming the findings of
Randle and co-workers (15, 16) at the whole body level at rest may be
because only specific tissues respond as predicted by the in vitro
studies. It is thus possible that the contribution of the tissues that
respond, as suggested by Randle and co-workers, does not account for a
sufficient percentage of resting substrate metabolism to be detected at
the whole body level. The findings of the present study, that
hyperglycemia-hyperinsulinemia affects regional (i.e., muscle and
splanchnic) fatty acid oxidation similarly, may be indicative of the
fact that glucose-fatty acid interactions are not regulated as would be
predicted by the Randle hypothesis in resting postabsorptive individuals.
Despite the significant decrease in fatty acid oxidation across both
the leg and the splanchnic region (Table 3), fatty acid uptake was not
affected in either leg or splanchnic region during hyperglycemia-hyperinsulinemia (Fig. 2), suggesting increased channeling of fatty acids toward an alternative pathway, e.g., reesterification into triacylglycerols (TG). It is possible that, in
the postabsorptive state, glycerol 3-phosphate availability is rate
limiting for reesterification into TG and that the increased glucose
uptake during hyperglycemia increases its availability to serve as a
backbone for TG synthesis. In fact, the possibility cannot be excluded
that, during hyperglycemia-hyperinsulinemia, fatty acid oxidation
decreased because of preferential channeling of fatty acids toward TG
instead of oxidation.
The rate of fatty acid oxidation across the splanchnic region and the
leg did not correlate with fatty acid uptake (Fig.
7), suggesting that fatty acid oxidation is
not a function of uptake, at least with FFA concentration ~0.5
mmol/l. This observation is in accord with the finding of the present
study that glucose availability determines the rate of fatty acid
oxidation. If this is true, then it should not be expected that fatty
acid uptake influences the rate at which fatty acids are oxidized.

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Fig. 7.
Fatty acid oxidation as a function of uptake across splanchnic region
(A; r = 0.2) and leg (B;
r = 0.3). Individual values for 5 volunteers in basal state ( ) and during hyperglycemia ( ) are
plotted.
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The percentage of fatty acid uptake that was oxidized at the whole body
level, across the splanchnic region, and across the leg decreased
similarly in response to hyperglycemia-hyperinsulinemia (Fig. 6). The
fact that the magnitude of the decrease in fatty acid oxidation in the
present study (~50%) is similar to the decrease observed after 5 h
of hyperinsulinemia-hyperglycemia induced via exogenous infusion of
insulin and glucose (24) suggests that there is a limit to the effect
that glucose may have on fatty acid oxidation. In other words, when
fatty acid availability is maintained constant, fatty acid oxidation
persists at a significant rate even when glucose uptake and oxidation
are maximally stimulated. Thus, whereas we envision glucose
availability as the predominant regulator of substrate oxidation,
variations in FFA availability have some effect. This is because, if we
had allowed fatty acid concentration to decrease in the present study,
then there would probably have been a further decrease in fatty acid
oxidation. Therefore, even in the setting of
hyperglycemia-hyperinsulinemia, changes in fatty acid concentration
also exert a modest effect on the rate of fatty acid oxidation. This is
consistent with the notion of glucose acting via suppression of
CPT I activity, because at even a suppressed level of activity, one
would expect a residual effect of fatty acid concentration on the
rate of acylcarnitine formation and entry into the mitochondria.
The mechanism by which accelerated glucose metabolism may directly
inhibit fatty acid oxidation in humans is not yet entirely clear. We
have previously shown that hyperglycemia-hyperinsulinemia inhibits
long-chain but not medium-chain fatty acid oxidation and decreased
muscle long-chain acylcarnitine concentration in resting healthy
volunteers, even in the setting of constant plasma fatty acid
availability (24). Those data suggest that
hyperglycemia-hyperinsulinemia inhibits fatty acid oxidation by
limiting long-chain fatty acid entry into the mitochondria (24).
In the present study, we infused only glucose and allowed the
concentration of insulin (as well as that of other hormones and
mediators) to change spontaneously. Indeed, infusion of glucose to
induce hyperglycemia in the clamp experiments is expected to result in
changes in the secretion of various hormones, including insulin. It is
well established that increased glucose and insulin concentration in
plasma inhibits peripheral lipolysis and fatty acid release, thereby
decreasing FFA concentration in plasma (3-5, 8, 14, 20). A
significant decrease of plasma FFA is expected to decrease fatty acid
oxidation. To prevent the insulin-induced decline in fatty acid
availability, fatty acid concentration was maintained similar in the
basal and clamp experiments via infusion of lipids and heparin. This
was important, because if we had allowed fatty acid availability to
vary between the two trials, we would not have been able to
differentiate the direct effects of
hyperglycemia-hyperinsulinemia from the effect of decreasing fatty acid
availability on regional fatty acid kinetics and oxidation.
Even though the insulin effect on fatty acid availability was
controlled, a possible other direct effect of insulin on fatty acid
oxidation cannot be excluded by the present study, as insulin concentration was allowed to change freely in response to dextrose infusion. Insulin stimulates pyruvate dehydrogenase activity, which
results in increased acetyl-CoA formation. An increase in acetyl-CoA-to-CoA ratio may directly decrease
-oxidation via feedback inhibition of 3-ketoacyl-CoA thiolase (19). Furthermore, it
has been proposed that insulin activates acetyl-CoA carboxylase (11),
which is the enzyme that catalyzes malonyl-CoA formation. Malonyl-CoA,
in turn, may decrease fatty acid oxidation by decreasing CPT I activity
and therefore inhibiting fatty acid entry into the mitochondria (10,
12). However, glucose needs to be present for insulin to decrease fatty
acid oxidation, because insulin alone cannot alter malonyl-CoA
concentration (6). On the other hand, glucose alone may also not be
able to affect fatty acid oxidation, at least in the insulin-sensitive
tissues, because of limited entry into the cells. In any case, in
physiological circumstances the concentrations of insulin and glucose
change simultaneously. Therefore, from the present experimental design, it is not possible to specifically assign responsibility to
hyperglycemia, per se, for the observed changes, as opposed to changes
caused as a consequence of secondary alterations in the concentration of other hormones or mediators (e.g., insulin).
On the basis of findings from our previous experiments at the whole
body level (23, 24), we have advocated the view that intracellular
glucose availability and glycolytic flux directly regulate fatty acid
oxidation via control of fatty acid entry into the mitochondria.
Our present findings of glucose-induced inhibition of fatty acid
oxidation across the splanchnic region and the leg support our view
that, under the present experimental conditions, glucose is the primary
regulator of glucose-fatty acid interactions in most tissues of the
body. Similar findings have been obtained across the rat heart (17).
In summary, the results of the present study indicate that an increase
in glucose availability, in combination with changes in other hormones
and/or mediators (e.g., insulin), inhibits fatty acid oxidation
similarly across the leg and the splanchnic region in the setting of
constant fatty acid availability. The decrease in fat oxidation
observed across these tissues is similar to the decrease observed at
the whole body level, suggesting a uniform effect of glucose
and/or insulin on fatty acid oxidation across most tissues of
the body.
 |
ACKNOWLEDGEMENTS |
We appreciate the help of the nursing staff of the General Clinical
Research Center (GCRC) in the performance of the experiments. We also
thank Drs. Y. Zheng and X.-J. Zhang, Y.-X. Lin, Zhanpin Wu, and G. Jones for excellent technical assistance.
 |
FOOTNOTES |
This work was supported by National Institutes of Health (NIH) Grants
DK-51969 (L. S. Sidossis), DK-34817 (R. R. Wolfe), and DK-46017 (R. R. Wolfe); American Heart Association Texas Affiliate Grant 96G-1618
(L. S. Sidossis); NIH National Center for Research Resources GCRC Grant
MO1 00073; Shriners Hospital Grant 15849 (R. R. Wolfe); and a
Fellowship from the European Society of Parenteral and Enteral
Nutrition (L. S. Sidossis).
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.
Address for reprint requests: L. S. Sidossis, Metabolism Unit, The
Univ. of Texas Medical Branch, Shriners Burns Institute, 815 Market
Str., Galveston, TX 77550.
Received 25 June 1998; accepted in final form 4 November 1998.
 |
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