Placental transfer of lactate,glucose and 2-deoxyglucose in control and diabetic Wistar rats

Placental transfer of lactate, glucose and 2-deoxyglucose was examined employing the in situ perfused placenta. Control and streptozotocin induced diabetic Wistar rats were infused with [U-14C]-glucose and [3H]-2-deoxyglucose (2DG). The fetal side of the placenta was perfused with a cell free medium and glucose uptake was calculated in the adjacent fetuses. Despite the 5-fold higher maternal plasma glucose concentration in the diabetic dams the calculated fetal glucose metabolic index was not significantly different between the 2 groups. Placental blood flow was reduced in the diabetic animals compared with controls but reduction of transfer of [U-14C]-glucose and [3H]-2-deoxyglucose and endogenously derived [14C]-Lactate to the fetal compartment, could not be accounted for by reduced placental blood flow alone. There was no significant net production or uptake of lactate into the perfusion medium that had perfused the fetal side of the placenta in either group. The plasma lactate levels in the fetuses adjacent to the perfused placenta were found to be higher than in the maternal plasma and significantly higher in the fetuses of the diabetic group compared with control group. In this model the in-situ perfused placenta does not secrete significant quantities of lactate into the fetal compartment in either the control or diabetic group.     

Thyrotropin-releasing hormone metabolism and extraction by the perfused guinea pig placenta

This report describes the extraction of synthetic TRH and its metabolic conversion in the perfused guinea pig placenta. These studies were performed to obtain an estimate of fractional fetal TRH losses through the placenta and to determine if some of these losses are due to TRH metabolism. The in situ guinea pig placenta was perfused through an umbilical artery for 90 min, and placental effluent fractions were collected at timed intervals from the umbilical vein. Experiments were performed in which the perfusion buffer contained 0.01, 1, and 10 micrograms/ml or no synthetic TRH. Synthetic TRH was always perfused in the presence of 3H2O. In experiments in which TRH was perfused, the perfusion reservoir contents and placental effluent fractions were counted for 3H, and TRH and deamido-TRH were determined by RIA. Similarly, cyclo(His-Pro) was measured when 10 micrograms/ml TRH were perfused. When no TRH was perfused, the perfusion reservoir and placental effluent contents were processed to determine their content of TRH immunoreactivity. When synthetic TRH was perfused, steady state TRH concentrations were achieved in placental effluent fractions by 20-30 min. The single pass extraction of TRH by the placenta was 11.4 +/- 2.6% (mean +/- SE) compared to 56.9 +/- 7.0% for 3H2O (P less than 0.001). No significant difference was detected regardless of whether 10, 1, or 0.01 micrograms/ml TRH were perfused. A portion of the TRH that perfused the placenta was converted to deamido-TRH at all concentrations of perfused TRH. No conversion of TRH to cyclo(His-Pro) was noted when the highest concentration (10 micrograms/ml) of TRH was perfused. The conversion of TRH to TRH-OH was 4.2 +/- 0.7% in a single pass. When the perfusion buffer was devoid of synthetic TRH, a small but significant increase in the content of TRH immunoreactivity was noted in the placental effluent compared to that in the perfusion reservoir. This was not large enough to affect calculations of the placental extraction of TRH. These studies, in addition to demonstrating that the placenta contains TRH deamidase activity, suggest that losses of fetal TRH through the placenta are not large. They do not support the current impression, based on the fetal TSH response to maternal TSH administration, that the placenta is freely permeable to TRH.     

Relative effects of pregnancy and corticosterone administration on skeletal muscle metabolism in the rat

The effects of pregnancy and corticosterone treatment on skeletal muscle metabolism were compared using a noncyclically perfused rat hindlimb preparation. Animal groups studied included 3-week-pregnant animals, rats injected with corticosterone (7.5 mg/100 g BW . day) for 3 days, and age-matched control rats. All were fasted 24 h before perfusion. In baseline perfusions devoid of insulin, no differences were observed among the groups with respect to muscle glucose uptake and the release of lactate, pyruvate, and glycerol. Baseline alanine and phenylalanine release were significantly increased in corticosterone-treated rats compared to values observed in control and pregnant animals. In perfusions with 100 or 500 microU/ml insulin, glucose uptake was increased 5-fold above baseline uptake in the control group. At 100 microU/ml insulin concentrations, glucose uptake in pregnant and corticosterone-treated rats achieved only 50% of the increase seen in control experiments. With 500 microU/ml insulin, glucose uptake was decreased 20% in pregnant animals and 40% in rats receiving corticosterone relative to control values. Alanine release was significantly reduced below baseline after the administration of 500 microU/ml insulin in control rats. In these rats, phenylalanine release, an index of net protein degradation, also was reduced with both 100 and 500 microU/ml insulin. Similar insulin concentrations did not suppress the efflux of either amino acid below baseline in pregnant or corticosterone-treated groups. Corticosterone administration to nonpregnant rats appears to duplicate changes in skeletal muscle metabolism that occur during late rat pregnancy. Insulin resistance in both states is manifested by a decrease in insulin-stimulated glucose uptake and an inability of insulin to suppress net muscle proteolysis. Since plasma free glucocorticoid concentrations are increased in late human as well as rat gestation, these steroids may have an important role in the development of insulin resistance at skeletal muscle sites in this state.     

Effect of insulin on glucose uptake by the maternal hindlimb and uterus, and by the fetus in conscious pregnant sheep

Previous studies have demonstrated the presence of insulin receptors on the maternal surface of the placenta in several species and the specific binding of insulin to the placenta in sheep. However, both in-vitro and in-vivo studies have produced conflicting evidence concerning the effect of insulin on placental glucose uptake. To clarify this problem, we measured maternal hindlimb, uterine and fetal glucose and oxygen extractions and glucose/oxygen quotients in chronically catheterized, non-stressed, late-gestation pregnant sheep over 1 h at a constant concentration of arterial plasma glucose, and again during the next 2 h at the same glucose level but at a higher insulin concentration using glucose 'clamp' methodology. Insulin produced a 4.9-fold increase in glucose extraction and a 3.5-fold increase in glucose/oxygen quotient across the hindlimb; in contrast, insulin did not significantly affect uterine or fetal glucose extraction or glucose/oxygen quotient. We conclude that in contrast to other tissues of the pregnant ewe, placental glucose uptake and transfer are insensitive to variations in maternal insulin concentration.     

Human Placental Biotin Transport: Normal Characteristics and Effect of Ethanol

Biotin, a vitamin essential for many metabolic reactions, is supplied to the fetus exclusively from the mother. Deficiency of biotin in pregnancy leads to impaired fetal growth and development. Alcohol taken in pregnancy likewise may cause fetal growth abnormalities. Normal biotin transport via the placenta and the effects of ethanol on this transport apparently have not been studied. Our aims were to characterize these phenomena for the normal human-term placenta. Using maternal-facing placental membrane vesicles, biotin uptake was sodium- and temperature-dependent, saturable, and inhibited by structural analogs of biotin (desthiobiotin, biocytin, and biotin methyl ester), as well as by 4 and 10 hr exposure to 3 g/liter ethanol. Using the isolated perfused single cotyledon method to measure placental transport of biotin at a perfusion concentration of 1 nM, the overall rate of biotin transport was found to be only 30% that of antipyrine, a freely diffusible marker. Clearance of biotin was ～2 ml/hr. g placenta, which was equal to the clearance of passively transferred l -glucose; biotin clearance was similar in both maternal to fetal and fetal to maternal directions. Overall transfer of biotin from maternal to fetal compartments was not inhibited by 500-fold greater concentrations of the three analogs, did not proceed against a biotin concentration gradient, and was not inhibited by 90–240 min exposure to an initial concentration of 4 g/liter ethanol. Concentration of biotin in the fetal compartment at the end of the study was not higher than on the maternal side (after maternal to fetal infusion), but placental concentration was 2- to 3-fold greater. No significant metabolism of biotin was detected. Exposing human placental cultured trophoblast on day 3 to 24 hr of ethanol (2 g/liter) had no effect on the net uptake of biotin by these cells. These studies provide evidence that maternal-facing placental membranes take up biotin by a mediated, carrier-dependent process that is inhibited by ethanol; however, based on the perfusion studies, we conclude that the overall (maternal-fetal) rate-limiting transfer of biotin by the human placenta is most consistent with a passive process, which is not inhibited by short-term exposure to ethanol.     

Human Placental Transfer of Zinc: Normal Characteristics and Role of Ethanol

The fetal alcohol syndrome is primarily an impairment of growth and development. Zinc deficiency also causes abnormal fetal growth. Moreover, alcohol has been shown in some rodent studies to impair placental transport of zinc. The purpose of this investigation was to define better normal human placental zinc transport and the effects of alcohol on this process. To do this we employed the isolated perfused single cotyledon human term placental model, as well as the cultured human cytotrophoblast. In the perfused placental studies, it was shown that zinc is transferred by the placenta very slowly, about 6% of the rate of transport of antipyrine, a freely diffusible marker. The transfer is comparable in both directions, maternal to fetal and the reverse. Zinc does not cross the placenta against a zinc concentration gradient, in either direction. Rather there is good evidence of significant uptake (storage) of the zinc by the placenta on the recirculating compartment side of gradient studies. Moreover, when the perfusion fluid was low (0.2 g/100 ml) in albumin, about twice as much zinc accumulated in the perfused cotyledon and there was less zinc in the maternal compartment, as compared to perfusion with ten-fold higher (2.0 g/100 ml) albumin concentrations. Thus, ligand binding in the perfusate importantly influences placental zinc uptake. Interestingly, however, the increased placental binding of zinc did not translate into greater transfer of zinc to the fetal compartment. Thus, normal zinc transfer is slow, equal bidirectionally, and dependent on ligand binding in perfusate and placenta.(ABSTRACT TRUNCATED AT 250 WORDS)     

Bidirectional placental transfer (‘leak’) ofl-glucose in control and diabetic rats

The placental transfer ofd- andl-glucose was investigated in anaesthetised non-diabetic and streptozotocin-induced diabetic rats. Maternal to fetal transfer was determined by perfusing the fetal side of one placenta in situ whilst infusing a mixture ofd-[3-³H]glucose andl-[1-¹⁴C]glucose into the maternal circulation. Backtransfer from the fetal to maternal circulation was assessed by determining the uptake of the radiolabelled glucoses from the perfusion fluid during a single passage through the placenta on the fetal side. Maternal diabetes resulted in a reduced utero-placental blood flow but an increased bidirectional transfer ofd-glucose. Non-specific maternal to fetal placental transfer ofl-glucose was greater in diabetic rats than in controls, and the loss ofl-glucose during placental perfusion of the fetal side was, again, greater in diabetic than in control rats. This increased bidirectional leak of glucose possibly reflects a functionally compromised placenta, caused by its formation in a diabetic milieu, and may explain the greater fetal-maternal glucose ratios found in diabetic rats relative to controls.     

Fructose-2,6-bisphosphate, a potent stimulator of phosphofructokinase, is increased by high exogenous glucose perfusion

BACKGROUND: We have previously demonstrated that perfusion of isolated hearts with high concentrations of glucose results in increased glycolysis during ischemia, diminished ischemic injury, and improved functional recovery with reperfusion. OBJECTIVE: To evaluate a possible mechanism by which glucose conferred this protection. We examined the hypothesis that increased exogenous glucose concentrations results in increased concentrations of fructose-2,6-bisphosphate, a potent activator of phosphofructokinase-1, and thus increases glycolysis. METHODS: Perfused rabbit hearts were subjected to 60 min of low-flow ischemia. Control hearts were perfused with buffer containing 0.4 mmol/l palmitate, 5 mmol/l glucose, and 70 mU/l insulin, and treated hearts were perfused with buffer containing 0.4 mmol/l palmitate, 15 mmol/l glucose and 210 mU/l insulin. RESULTS: Ischemic contracture was attenuated by perfusion of high concentrations of glucose (high glucose) (P < 0.05 compared with control). Glucose uptake and lactate production were greater in hearts perfused with high glucose, as was the ATP concentration at the end of ischemia (P < 0.05 compared with controls). Exogenous glucose uptake and lactate production correlated well with fructose-2,6-bisphosphate content (P = 0.007). CONCLUSIONS: Enhancement of glycolysis in hearts perfused with high glucose may be the result of stimulation of phosphofructokinase-1 by fructose-2,6-bisphosphate. Accordingly, this may serve as an important mechanism by which cardioprotection may be achieved.     

Effect of ciglitazone on glucose uptake and insulin sensitivity in skeletal muscle of the obese (ob/ob) mouse: distinct insulin and glucocorticoid effects

The oral hypoglycemic agent, ciglitazone, (5-[4-(1-methylcyclohexylmethoxy)benzyl]-thiazolidine-2,4-dione), was fed for nine days to genetically obese (ob/ob) mice aged 5 to 6 weeks. This treatment resulted in a lowering of plasma glucose and circulating insulin levels, but did not cause a fall in plasma corticosterone levels. Basal 2-deoxy-D-glucose uptake by the perfused hindquarters of ob/ob mice was unchanged by ciglitazone feeding. In the presence of 0.1 mU/mL insulin in the perfusion medium, there was a significant increase in the uptake rate of 2-deoxy-D-glucose by the skeletal muscle of ciglitazone-treated ob/ob mice, while there was no insulin effect in untreated ob/ob mice. Insulin at a concentration of 1 mU/mL caused a further stimulation of 2-deoxy-D-glucose transport. However, this response was significantly lower than the maximal stimulation in lean mice. Ciglitazone feeding did not have any effect on [5-3H]-glucose metabolism by the perfused muscle which remained subnormal, suggesting that the posttransport metabolism of glucose was limited by substrate availability. In the perfused mouse liver, net [14C]-glucose production from [14C]-lactate was unchanged by ciglitazone treatment while gluconeogenesis from [14C]-alanine was reduced. These findings show that ciglitazone produces its hypoglycemic effect by improving the insulin sensitivity in skeletal muscle, as others have reported in the adipose tissue. The presence of elevated plasma levels of corticosterone and lower levels of insulin in ciglitazone-treated ob/ob mice suggests that the adrenal glucocorticoids are responsible for the basal defects in glucose transport and the hyperinsulinemia is responsible for the insulin insensitivity.     

Delayed response of insulin-stimulated fluorine-18 deoxyglucose uptake in glucose transporter-4-null mice hearts

OBJECTIVES: We sought to evaluate the time course of insulin-stimulated myocardial glucose uptake (MGU) in mice that had undergone ablation of glucose transporter-4 (GLUT4). BACKGROUND: The relative importance of GLUT4, the most abundant insulin-responsive glucose transporter, to modulate myocardial glucose metabolism is not well defined. METHODS: Myocardial glucose uptake was assessed at various time points after glucose (1 mg/g) and insulin (8 mU/g) injection in GLUT4-null (G4N) (n = 48) and wild-type (WT) (n = 48) mice with (18)F-2-deoxy-2-fluoro-d-glucose (FDG) using in vivo positron emission tomography (PET), in vitro gamma-counter biodistribution, and isolated, perfused hearts. RESULTS: Baseline assessment with PET imaging showed comparable MGU in G4N (0.66 +/- 0.12) and WT (0.67 +/- 0.11, p = 0.70) mice. Early after insulin injection, WT mice demonstrated a 3.5-fold increase in MGU (2.45 +/- 0.45, p = 0.03), whereas G4N mice presented no increase (1.11 +/- 0.24, p = 0.28). At 60 min, MGU was comparable in G4N (3.19 +/- 0.60) and WT (2.66 +/- 0.47, p = 0.28) mice. In vitro gamma-counter biodistribution evaluation confirmed in G4N mice a lack of MGU increase early after insulin, but a slow response over 120 min. The isolated, perfused hearts of G4N mice during short-term (15 min) insulin stimulation displayed no increase in MGU (0.08 +/- 0.01 ml/g/min), whereas WT mice presented a threefold increase (0.22 +/- 0.01 ml/g/min, p < 0.01). With long-term (60 min) insulin stimulation, similar MGU was found in G4N (0.31 +/- 0.02 ml/g/min) and WT (0.33 +/- 0.04 ml/g per min, p = 0.04) mice. CONCLUSIONS: The G4N mice displayed an increase of MGU in response to insulin similar to that of controls, but with a markedly delayed time response. Our findings underscore the important role of GLUT4 in the rapid adaptive response of myocardial glucose metabolism.     

Ischemia-stimulated glucose uptake does not require catecholamines in rat heart

The authors tested the hypothesis that ischemia stimulates glucose uptake in rat heart independent of the insulin signaling pathway and independent of endogenous catecholamines. Isolated working rat hearts were perfused with Krebs-Henseleit buffer containing [2-3H]glucose (5 mmol/l, 0.05 muCi/ml) and Na-oleate (0.4 mmol/l) with or without the phosphatidylinositol 3-kinase inhibitor wortmannin (3 mumol/l). Insulin (1 mU/ml) was added to the perfusate in the middle of the experiments or the hearts were subjected to 30 min of low-flow ischemia (75% reduction in coronary flow) followed by 15 min of reperfusion. In a separate group, hearts were subjected to ischemia and reperfusion in the presence of propranolol (10 mumol/l) plus phentolamine (10 mumol/l). Cardiac power was stable but decreased (-75%) during ischemia. Both insulin and ischemia increased glucose uptake (P < 0.01). Glucose uptake returned to pre-ischemic values during reperfusion. Wortmannin completely inhibited insulin-stimulated glucose uptake and glycogen synthesis, but did not affect the ischemia-stimulated glucose uptake or glycogen resynthesis during reperfusion. Full adrenergic blockade did not abolish the ischemia-stimulated glucose uptake. The authors conclude that: (1) insulin and ischemia increase glucose uptake through different mechanisms; (2) ischemia-stimulated glucose uptake is not catecholamine mediated: and (3) glycogen resynthesis during reperfusion is independent of PI3-K.     

Placental transfer and uptake of 2-deoxyglucose in control and diabetic rats.

Placental glucose transfer and sequestration were investigated in anesthetized control and streptozotocin-diabetic rats by perfusing the fetal side of one placenta in situ while infusing a mixture of [3H]D-glucose (to measure net transfer after metabolism) and [14C]2-deoxyglucose (to estimate tissue sequestration) into the maternal circulation. No difference was found between transfer ratios (perfusate/simultaneous maternal plasma ratio) of [3H]D-glucose (0.35 +/- 0.06, mean +/- SD) and [14C]2-deoxyglucose (0.36 +/- 0.06) in control rats. Ratios were reduced (P < .001) to the same extent in diabetic rats ([3H]D-glucose, 0.13 +/- 0.06; [14C]2-deoxyglucose, 0.15 +/- 0.07). Placental glucose utilization, estimated by the quantity of [14C]2-deoxyglucose-6-phosphate present, was increased from 66 nmol.min-1.g-1 in control to 595 nmol.min-1.g-1 (P < .001) in diabetic rats. Transfer to the perfusion fluid of unlabeled D-glucose was increased (P < .001) in diabetic rats (2.32 mumol/mL) compared with control rats (0.77 mumol/mL) due to elevated (P < .001) maternal plasma glucose levels. Upon phosphorylation, 2-deoxyglucose becomes trapped within the placenta, and therefore these results indicate that all the glucose destined for direct transfer to the fetus is protected from phosphorylation while traversing the placenta, and that diabetes appears to increase placental glucose utilization, but does not induce futile cycling of glucose in an attempt to protect the fetus from an excessive influx of glucose from the mother in the rat.     

Release of large amounts of noradrenaline from the isolated perfused canine pancreas during glucose deprivation

Summary Six fasting male mongrels served as pancreas donors. The pancreas was perfused without recirculation with a synthetic medium. The noradrenaline and adrenaline concentration in the efflux perfusate was determined by a double-isotope derivative technique. 1. The noradrenaline concentration in the efflux perfusate rose considerably (from 0.25 ng/ml to 10.0 ng/ml), when the pancreas was perfused with a glucose deprived perfusing medium. The concentration rose almost linearly with time. After the addition of very small amounts of glucose (2 mg/100 ml) to the perfusing medium there was a considerable decrease in catecholamine concentration and a further decrease with higher glucose concentrations. 2. No change in catecholamine concentration in the efflux perfusate was observed if the pancreas was perfused with a high glucose concentration during the whole experiment. 3. Glucagon release was also high during perfusion with a glucose deprived solution while insulin release was low. These experiments raise the question whether an increased catecholamine release may, at least partially, be responsible for the change in insulin and glucagon secretion during glucose deprivation.     

Effects of gestational diabetes on human placental glucose uptake, transfer, and utilisation

Aims/hypothesis. Gestational diabetes is associated with complications for the offspring before, during and after delivery. Poor maternal glucose control, however, is a weak predictor of these complications. Given its position at the interface of the maternal and fetal circulations, the placenta possibly plays a crucial part in protecting the fetus from adverse effects from the maternal diabetic milieu. We hypothesised that gestational diabetes may result in changes in placental function, particularly with respect to the uptake, transfer, and/or utilisation of glucose. We aimed to examine glucose transport and utilisation in intact human placental lobules from women with gestational diabetes and those from normal pregnancies. Method. Dual perfusion of an isolated placental lobule was done on placentae from diet treated gestational diabetic (n = 7) and normal pregnant patients (n = 9) using maternal glucose concentrations of 4, 8, 16 and 24 mmol/l in random order over a 4-h experiment. Results were expressed in μmol · min^–1· g^–1. Results. d-glucose uptake from the maternal circulation (control 0.492 vs gestational diabetes mellitus 0.248, at 8 mmol/l maternal glucose), d-glucose utilisation by the placenta (0.255 vs 0.129), d-glucose transfer to the fetal circulation (direct 0.979 vs 0.402; net transfer 0.269 vs 0.118) and l-lactate maternal release into both the fetal (0.052 vs 0.042) and maternal (0.255 vs 0.129) circulation were significantly reduced during in vitro perfusion of placentae from patients with gestational diabetic pregnancies. Transfer of ³H-l-glucose also significantly reduced in the diabetic group (8.1 % vs 2.6 %). Conclusion/interpretation. These results suggest that placental transport and metabolism of d-glucose is altered during gestational diabetes. [Diabetologia (2000) 43: 576–582] Received: 21 October 1999 and in revised form: 15 December 1999     

Mechanism of insulin resistance in fructose-fed rats

Previous results from our laboratory demonstrated that chronic administration of fructose to normal rats led to both hyperinsulinemia and in vivo insulin resistance. To localize the major tissue site of insulin resistance in fructose-fed animals, we compared glucose uptake by perfused hindlimb skeletal muscle and liver from rats fed either a 60% fructose diet or laboratory chow. Glucose uptake by perfused muscle from chow and fructose-fed rats was comparable at perfusate insulin levels of 0 μU/ml (15.2 versus 15.5 μl/min/g muscle), 100 μU/ml (18.3 versus 19.8), and >500 μU/ml (35.5 versus 33.4). In contrast, glucose outflow from livers of fructose-fed rats was significantly greater (p < .02) than chow-fed animals perfused in the absence of added insulin (52.1 versus 36.5 μmol/g). Furthermore, the ability of insulin to suppress glucose outflow was less in livers from fructose-fed rats at perfusate insulin levels of 165 μU/ml (13.2 versus 41.4% as well as at insulin concentration >900 μU/ml, (32.5% versus 62.2%). These findings suggest that the insulin resistance resulting from chronic fructose feeding is due to the diminished ability of insulin to suppress hepatic glucose output, and not to a decrease in insulin-stimulated glucose uptake by muscle.     

Insulin-like effect of low-dose leptin on glucose transport in Langendorff rat hearts.

BACKGROUND: In a murine myotube cell line (C 2 C 12 myotubes), leptin at low physiological concentrations (1 ng/ml) has been shown to stimulate glucose transport and glycogen synthesis. The aim of the present study was to test whether an analogous leptin effect on glucose transport is detectable in the heart. METHODS AND RESULTS: We used the isolated Langendorff rat heart preparation with hemodynamic function control. Using polymerase chain reaction (RT-PCR), a 346- and 375-base fragment indicative for the short and long leptin receptor isoform was detected in the rat heart. Glucose transport rates were calculated using equimolar double tracer perfusion with the non-metabolizable glucose analog 3-O-methylglucose (3-O-MG) and the non-transportable tracer mannitol and two-compartimental modeling. 3-O-MG uptake at a perfusate glucose concentration of 11 mM was measured over 15 minutes in control hearts, hearts perfused with insulin (10 mU/ml), leptin (1 ng/ml) or insulin (10 mU/ml) plus leptin (1 ng/ml; n = 8 in each group). The basal 3-O-MG transport rate of 0,7351 +/- 0,051 micro mol/min/g wet weight was increased 4.18 fold with insulin, 2.69 fold with leptin, and 4.2 fold with leptin plus insulin. Simultaneous monitoring of hemodynamic function revealed a minor and transient effect of leptin on left ventricular pressure, which was strongly augmented in coperfusion with insulin. CONCLUSIONS: The data suggest that leptin at low physiological concentrations is able to exert a partial insulin like effect on glucose uptake. We speculate that the effect might be mediated by both leptin receptor isoforms.This leptin effect is additive to the effect of insulin and might therefore contribute to the insulin independent basal glucose supply of the heart. It can not be completely excluded that the observed leptin effect on glucose transport is secondary to altered myocardial function.     

The influence of high maternal plasma glucose levels,and maternal blood flow on the placental transfer of glucose in the guinea pig

Summary The relationship between maternal and fetal plasma glucose concentrations and placental glucose transfer has been studied in the anaesthetised guinea pig. The fetal circulation of the placenta, left in situ, was perfused through the umbilical arteries, after removal of the fetus, with a low molecular weight dextran, containing physiological salts and 100 mg/100 ml glucose. The maternal plasma: fetal perfusate concentration ratio of antipyrine, infused at a constant rate into the maternal circulation, was used to monitor the changes in maternal placental blood flow. — As the maternal plasma glucose was increased from 100 to 450 mg/100 ml the perfusate concentration followed, but at a slower rate. No further increases in perfusate concentration occurred after the maternal plasma level exceeded 450 mg/100 ml which suggests a maximum capacity of the placental membrane to transport glucose, analogous to that observed for the renal tubule and blood brain barrier. — The transfer rates of glucose from the fetal to the maternal circulation were similar to those in the opposite direction, with the same linear relationship to the transplacental gradients. Transfer, in either direction across the placental membrane, was reduced when the maternal placental blood flow was impaired, as indicated by a maternal: fetal antipyrine ratio below 0.6.     

Secretion of beta-endorphin into the maternal circulation by uteroplacental tissues in response to hypoglycaemic stress

The placenta has been shown to contain ACTH and beta-endorphin but the roles of these peptides are unknown. To investigate whether they are released into the maternal circulation from the placenta in response to physiological stimuli the effects of hypoglycaemic stress were investigated. Plasma samples were collected from the femoral artery (FA) and uterovarian (UV) vein of nine pregnant sheep before and during hypoglycaemia induced by intravenous insulin (100U). Plasma concentrations of ovine beta-endorphin (o beta-EP) were measured by radioimmunoassay. Concentrations of o beta-EP rose in both vessels by 60 min after insulin. The peak concentrations of o beta-EP (pmol/l) were 122 +/- 29 (mean +/- SEM, n = 8) in the UV and 96 +/- 24 (n = 9) fmol/ml in the FA 60 min after insulin injection. There was no difference between the concentrations of o beta-EP in the vessels before insulin injection but at 60 and 120 min after insulin the concentrations of o beta-EP were significantly higher in the UV than FA (P less than 0.02, analysis of variance). This indicates that the pregnant uterus or placenta can respond to hypoglycaemia by secreting beta-EP into the maternal circulation. It is therefore possible that placental pro-opiomelanocortin (POMC) peptides may have a role in maternal endocrinology and metabolism.     

Insulin extraction and glucose output by the perfused liver of starved rats

Using the isolated and perfused liver of rats, we investigated the effect of starvation on hepatic glucose output and hepatic insulin extraction. The rats were starved for 72 h. The intestines of fed and starved rats were isolated and perfused, and portal venous effluent (PVE) was collected. The liver of fed and starved rats was perfused with synthetic medium or PVE containing 100 mg/dl glucose and 100 muU/ml insulin. Fractional uptake of insulin and reduction in glucose output by the perfused liver were almost the same in all groups. These results suggest that the removal and action of insulin in the liver were not altered by short-term starvation in rats.     

Removal of insulin by perfused rat liver: Effect of concentration

The kinetics of insulin removal by isolated rat liver were investigated by measuring the rate of disappearance of insulin from the perfusate during recycling perfusion and by comparing the extraction of insulin over a wide range of constant arterial hormone levels during nonrecycling perfusion. In the recycling studies, insulin was removed from the perfusing medium at a uniform rate between 5 and 45 min. The reaction velocity constant, or hepatic clearance, during this period of uniform disappearance averaged 1.8 ml/min and represented 34% of the volume flow through the liver. In the nonrecycling flow-through studies at constant arterial insulin concentration, an initial period of accelerated hepatic uptake of insulin was seen. This period lasted for 3 to 7 min, was seen at every level of arterial insulin concentration, and was followed by a period of constant hepatic insulin removal. The hepatic removal rate during the period of constant uptake increased in a linear fashion until arterial insulin concentration reached 500 μU/ml and attained a maximal value at concentrations over 800 μU/ml. These findings indicate that the time course of hepatic insulin uptake by the perfused rat liver consists of two phases—an initial rapid phase, possibly associated with insulin binding, followed by a sustained rate of insulin removal, which probably represents insulin utilization and degradation. The rate of hepatic insulin removal was found to be proportional to arterial insulin concentration over a range of 20 to 500 μU/ml. Above this concentration, hepatic removal processes became saturated, reaching a maximal value of 183 μU of insulin per gram of liver per minute.