Effects of oleic acid infusion on plasma free fatty acids and blood ketone bodies in the fasting rat

High oleic peanuts improve parameters leading to fatty liver development and change the microbiota in mice intestine

Background

Oleic-acid consumption can possibly prevent or delay metabolic diseases. In Israel, a Virginia-type peanut cultivar with a high content of oleic acid has been developed.

Objective

This study examined the effect of consuming high oleic peanuts (D7) on the development of fatty liver compared to the standard HN strain.

Design

The two peanut cultivars were added to normal diet (ND) and high-fat (HF) mouse diet. Male C57BL/6 mice were fed for 8 and 10 weeks on a 4% D7, 4% HN, or control diet. At the end of the experiments, blood and tissues were collected. Triglyceride, lipid levels, histology, and protein expression were examined. The diets’ effects on intestinal microbiota were also evaluated.

Results

Both D7 and HFD7 led to a reduction in plasma triglycerides. Lipids, triglycerides, and free fatty acids in the liver were low in diets containing D7. Additionally, CD36 expression decreased in the D7 group. Consumption of D7 led to higher Prevotella levels, and consumption of ND that contained HN or D7 led to a lower Firmicutes/Bacteroidetes ratio.

Conclusion

These findings suggest that consumption of peanuts high in oleic acid (D7) may have the potential to delay primary fatty liver symptoms.

Fibroblast growth factor 21 regulates lipolysis in white adipose tissue but is not required for ketogenesis and triglyceride clearance in liver

Fibroblast growth factors (Fgfs) are polypeptide growth factors with diverse functions. Fgf21, a unique member of the Fgf family, is expected to function as a metabolic regulator in an endocrine manner. Hepatic Fgf21 expression was increased by fasting. The phenotypes of hepatic Fgf21 transgenic or knockdown mice and high-fat, low-carbohydrate ketogenic diet-fed mice suggests that Fgf21 stimulates lipolysis in the white adipose tissue during normal feeding and is required for ketogenesis and triglyceride clearance in the liver during fasting. However, the physiological roles of Fgf21 remain unclear. To elucidate the physiological roles of Fgf21, we generated Fgf21 knockout (KO) mice by targeted disruption. Fgf21 KO mice were viable, fertile, and seemingly normal. Food intake, oxygen consumption, and energy expenditure were also essentially unchanged in Fgf21 KO mice. However, hypertrophy of adipocytes, decreased lipolysis in adipocytes, and decreased blood nonesterified fatty acid levels were observed when Fgf21 KO mice were fed normally. In contrast, increased lipolysis in adipocytes and increased blood nonesterified fatty acid levels were observed in Fgf21 KO mice by fasting for 24 h, indicating that Fgf21 stimulates lipolysis in the white adipose tissue during feeding but inhibits it during fasting. In contrast, unexpectedly, hepatic triglyceride levels were essentially unchanged in Fgf21 KO mice. In addition, ketogenesis in Fgf21 KO mice was not impaired by fasting for 24 h. The present results indicate that Fgf21 regulates lipolysis in adipocytes in response to the metabolic state but is not required for ketogenesis and triglyceride clearance in the liver.

Endocrine regulation of the fasting response by PPARalpha-mediated induction of fibroblast growth factor 21

Peroxisome proliferator-activated receptor alpha (PPARalpha) regulates the utilization of fat as an energy source during starvation and is the molecular target for the fibrate dyslipidemia drugs. Here, we identify the endocrine hormone fibroblast growth factor 21 (FGF21) as a mediator of the pleiotropic actions of PPARalpha. FGF21 is induced directly by PPARalpha in liver in response to fasting and PPARalpha agonists. FGF21 in turn stimulates lipolysis in white adipose tissue and ketogenesis in liver. FGF21 also reduces physical activity and promotes torpor, a short-term hibernation-like state of regulated hypothermia that conserves energy. These findings demonstrate an unexpected role for the PPARalpha-FGF21 endocrine signaling pathway in regulating diverse metabolic and behavioral aspects of the adaptive response to starvation.

Effect of physiological concentrations of insulin and glucagon on the relationship between nonesterified fatty acids availability and ketone body production in humans

To determine the effect of insulin and glucagon on the transformation of nonesterified fatty acids (NEFA) into ketone bodies (KB), we measured simultaneously in normal subjects NEFA and KB kinetics at different NEFA levels in the presence of basal (control test) or increasing insulin concentrations with glucagopenia (somatostatin + insulin infusion, insulin test) and without glucagopenia (somatostatin + insulin + glucagon infusion, glucagon test). NEFA levels were controlled during these tests by an intravenous (IV) infusion of a triglyceride emulsion. During the control test, a moderate increase of NEFA (464 +/- 30 to 715 +/- 56 mumol/L) increased the percentage of NEFA converted into KB (13.3% +/- 1.4% to 26.4% +/- 2.1%, P less than .05), and there was a linear relationship between this percentage and NEFA levels (r = .788, P less than .01). During the insulin and glucagon tests, the progressive increase in NEFA induced by the triglyceride emulsion infusion was associated, despite the increase of insulinemia, with an increase in KB production rate (P less than .05) and in the proportion of NEFA used for ketogenesis in the presence (8.1% +/- 1.2% to 14.2% +/- 6.3%, P less than .05) and absence (15.7% +/- 2.8% to 25.2% +/- 3.99%, P less than 0.05) of glucagopenia. In both tests, this percentage was always linearly related with NEFA levels (P less than .05) and the slopes of these relationships were comparable to that observed in the control test. However, the fraction of NEFA used for ketogenesis was always higher (P less than .05) during glucagon substitution than in its absence.(ABSTRACT TRUNCATED AT 250 WORDS)

Metabolic response to short term starvation in non-pregnant and late pregnant cafeteria-obese rats

We have determined the blood metabolite responses to a 24-h starvation period of cafeteria obese rats, in both non-pregnant and late pregnant states. In the fed condition the concentrations of glucose, lactate, pyruvate, glycerol and urea do not differ when compared in control and obese rats, but acetoacetate and 3-hydroxybutyrate levels are higher in the obese group. The overall response of the cafeteria-obese rats to starving seems characterized by decreased rates of glucose and amino-acids utilization, substituted by a more intense utilization of lipid fuels, with excess ketone bodies production and increased utilization of the mobilized glycerol. What we observed in the obese pregnant response to starvation can be summarized as the additional or superimposed effects of excess fat reserves. In the obese pregnant starved rats a less severe hypoglycaemia, lower levels of glycerol (as a consequence of increased utilization), reduced urea levels, and increased acetoacetate and 3-hydroxybutyrate levels were observed. It can be assumed that the pregnant obese rat response to starvation is related to the size of the fat deposits: the more obese, the more hyperketonaemia and less hypoglycaemia, and even diminished rates of amino-acid utilization, as indicated by a lower levels, when compared to the lean pregnant.

Evaluation of free fatty acid kinetics during TPN feeding of healthy rats

Free fatty acid (FFA) kinetics were evaluated in TPN-fed healthy rats using a single fatty acid tracer. Rats were divided into three groups according to the nonprotein energetic substrate infused: glucose (A), monoacetoacetin-glucose (B), and lipid emulsion-glucose (C). Fat kinetics were measured by continuous infusion of [1-14C]palmitate. Total FFA and individual FFA concentrations were measured and turnover and oxidation were determined for the total pool of FFA and for palmitate. Groups A and B were similar in all parameters. Group C had increased total and individual FFA concentrations. Group C appeared to have decreased total plasma FFA turnover and unchanged oxidation compared to groups A and B. Palmitate appeared to have a 400% increase in oxidation and a 50% increase in turnover for rats in Group C when compared to Groups A and B. It is concluded that a single tracer does not accurately reflect plasma FFA during TPN using lipid emulsion.

A comparison of the uptake of 3-hydroxy-3-methyl-glutaric acid in newborn and adult rat kidney

The developmental aspects of the renal uptake of 3-OH-3-CH3-glutaric acid (HMG) was examined using isolated renal tubules prepared from both newborn and adult rats and isolated renal brush border membranes vesicles from adult rats. The accumulation of 70 microM HMG by both newborn and adult tubules reached a steady state and achieved a distribution ratio (DR) of 4.9 and 6.5, respectively; decreased DR's at higher substrate concentrations suggest concentration-dependent uptake. Lineweaver-Burk analysis of the 5 min calculated velocities of HMG uptake by newborn and adult tubules indicate a single transport system with the same apparent Km of 0.2 mM in both age groups. The Vmax in adult rats was twofold greater than in newborn (0.95 versus 0.44 mM/1/5 min). The carrier system for HMG is assumed to be distinct from those of amino acids and sugars because tubule uptake of HMG is not affected by the presence of alpha-NH2-isobutyric acid and alpha-methyl-D-glucoside. Sodium maleate and acetoacetate significantly decreased HMG uptake in tubules of both age groups. HMG uptake by isolated renal brush border membrane vesicles from adult rats suggests that uptake is both carrier-mediated and Na+-dependent. These observations are consistent with renal tubular HMG uptake by an energy-dependent, carrier-mediated system.

Studies on metabolic alterations after a mixed meal and during a 39-hour fast in thyrotoxicosis

In order to determine the endocrine and metabolic state of thyrotoxicosis we measured blood glucose and plasma insulin response to ingestion of a mixed meal in 19 euthyroid and 9 hyperthyroid subjects. Moreover concentrations of glucose, free fatty acids (FFA), glycerol, acetoacetate (AcAc) beta-hydroxybutyrate (beta-OHB), insulin and human growth hormone (hGH) were determined in the blood of both healthy and hyperthyroid patients after an overnight and a 39-h fast. In another group of thyrotoxics the overnight fasting respiratory quotient (RQ) was measured. After a mixed meal blood glucose and plasma insulin changes of FFA, AcAc and beta-OHB was significantly higher in thyrotoxics, whereas hGH increase did not appear significantly greater in these subjects. There was no statistical difference between the respiratory quotient mean values found in hyperthyroid and in control subjects. In conclusion, these data indicate that in thyrotoxicosis absolute insulin response to a mixed meal is normal and that food deprivation considerably increase lipid mobilization from adipose tissue and causes an exaggerated starvation ketosis. The RQ mean valoue suggests that in the hyperthyroid state lipid-derived fuel as well as carbohydrate-derived fuel contributes to the increased oxygen consumption.

Effect of oleic acid on insulin secretion by the isolated perfused rat pancreas

The isolated perfused rat pancreas was utilized to investigate the effect of oleic acid on insulin secretion. In the absence of glucose, a continuous infusion of oleic acid (1500 micromol/l) induced a biphasic insulin release. This effect was reduced at low extracellular calcium concentration. In the presence of oleic acid 1500 micromol/l, the insulin response to 10 mmol/l arginine occurred earlier, the total amount of insulin released in response to the amino acid being unchanged. Such an effect was not obtained when oleic acid in the medium was 750 micromol/l, but it was observed in the presence of oleic acid 1500 micromol/l when the concentration of albumin in the perfusate was increased from 2 g/100 ml to 4 g/100 ml. The insulin response to a continuous infusion of glucose (4.4 mmol/l and 16.7 mmol/l) was potentiated by the presence of oleic acid 1500 micromol/l in the perfusate. No modification of the biphasic pattern of insulin response to glucose 16.7 mmol/l was observed. These results demonstrate that high concentrations of oleic acid stimulate insulin release from the isolated perfused rat pancreas and modulate the insulin response to arginine or glucose.

Long and medium chain triglycerides increase plasma concentrations of ketone bodies in suckling rats

The potential of medium chain triglyceride (MCT) and long chain triglyceride (LCT) as sources of plasma ketones was investigated in suckling rats. Initially high concentrations of plasma ketones in 6-, 10, and 17-day-old rats increased 2- to 3-fold after acute feeding of MCT. This feeding had the same effect in fed or fasted adult rats. Corn oil (as a source of LCT) induced a large increase in the plasma ketone concentration of suckling rats and a relatively small but significant increase in fasted adult rats. The LCT treatment did not affect plasma ketone levels in fed adult rats. The results show clearly that feeding either LCT or MCT will enhance hyperketonemia in suckling rats. In the livers of all animals, regardless of age, the capacity for incorporation of [1(-14C)]octanoate into CO2 and acetoacetate far exceeded that for [1(-14C)]palmitate. The hyperketonemic action of LCT in suckling rats was accompanied by an increased activity of carnitine palmityltransferase and increased level of carnitine.