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Department of Integrative Biology, University of California, Berkeley, California 94720
To
evaluate the hypothesis that precursor supply limits gluconeogenesis
(GNG) during exercise, we examined training-induced changes in glucose
kinetics [rates of appearance (Ra) and disappearance (Rd)], oxidation (Rox), and recycling
(Rr) with an exogenous lactate infusion to 3.5-4.0 mM
during rest and to pretraining 65% peak O2 consumption
(
O2 peak) levels during exercise.
Control and clamped trials (LC) were performed at rest pre-
(PRR, PRR-LC) and posttraining
(POR, POR-LC) and during exercise pre-
(PREX) and posttraining at absolute
(POAB, POAB-LC) and
relative (PORL, PORL-LC) intensities. Glucose Rr
was not different in any rest or exercise condition. Glucose
Ra did not differ as a result of LC. Glucose
Rox was significantly decreased with LC at POR
(0.38 ± 0.03 vs. 0.56 ± 0.04 mg · kg
1 · min1)
and POAB (3.82 ± 0.51 vs. 5.0 ± 0.62 mg · kg1 · min1).
Percent glucose Rd oxidized decreased with all LC except
PORL-LC (PRR, 32%;
PRR-LC, 22%; POR, 27%; POR-LC,
20%; POAB, 95%;
POAB-LC, 77%), which resulted in a significant
increase in oxidation from alternative carbohydrate (CHO) sources at
rest and POAB. We conclude that 1)
increased arterial [lactate] did not increase glucose Rr
measured during rest or exercise after training, 2) glucose disposal or production did not change with increased precursor supply,
and 3) infusion of exogenous CHO in the form of lactate resulted in the decrease of glucose Rox.
lactate; glucose kinetics; glucose recycling; training
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