Fast, affordable and eco-friendly enzyme kinetic method for the assay of α-ketoglutaric acid in medical product and sports supplements.

A novel kinetic method was developed for the quantitation of α-ketoglutaric acid (AKG) in cardioplegic solution and athletic supplements. The assay relied on an enzymatic transamination of AKG and d-4-hydroxyphenylglycine to form 4-hydroxybenzoylformic acid and l-glutamic acid using d-phenylglycine aminotransferase. Since 4-hydroxybenzoylformic acid absorbed UV strongly at 334 nm, the initial rate of the reaction was determined by the increasing absorbance at this wavelength without the need for colorimetric probes or coupling reactions, and this information was used for the construction of a standard curve against AKG concentration. The method showed good linearity (r2 = 0.9994) over an AKG concentration range of 20-160 µM. The limits of detection and quantitation were 4.09 and 13.62 µM respectively. It was simple, inexpensive, accurate and precise, as well as repeatable, and was not interfered with by excipients in the samples. Regarding the environmental friendliness, the method was free from the use of organic solvents or hazardous reagents and required no chemical pre-treatment of samples. The proposed method gave assay results tested in real samples in agreement with the HPLC method and commercial assay kits, therefore being suitable for routine analysis of AKG in quality control laboratories.

Dietary alpha-ketoglutarate increases cold tolerance in Drosophila melanogaster and enhances protein pool and antioxidant defense in sex-specific manner.

Alpha-ketoglutarate (AKG) is an important intermediate in Krebs cycle which bridges the metabolism of amino acids and carbohydrates. Its effects as a dietary supplement on cold tolerance were studied in Drosophila melanogaster Canton S. Two-day-old adult flies fed at larval and adult stages with AKG at moderate concentrations (5-10mM) recovered faster from chill coma (0°C for 15min or 3h) than control ones. The beneficial effect of AKG on chill coma recovery was not found at its higher concentrations, which suggests hormetic like action of this keto acid. Time of 50% observed mortality after 2h recovery from continuous cold exposure (-1°C for 3-31h) (LTi50) was higher for flies reared on 10mM AKG compared with control ones, showing that the diet with AKG enhanced insect cold tolerance. In parallel with enhancement of cold tolerance, dietary AKG improved fly locomotor activity. Metabolic effects of AKG differed partly in males and females. In males fed on AKG, there were no differences in total protein and free amino acid levels, but the total antioxidant capacity, catalase activity and low molecular mass thiol content were higher than in control animals. In females, dietary AKG promoted higher total antioxidant capacity and higher levels of proteins, total amino acids, proline and low molecular mass thiols. The levels of lipid peroxides were lower in both fly sexes reared on AKG as compared with control ones. We conclude that both enhancement of antioxidant system capacity and synthesis of amino acids can be important for AKG-promoted cold tolerance in D. melanogaster. The involvement of AKG in metabolic pathways of Drosophila males and females is discussed.

Metabolic phenotyping of an adoptive transfer mouse model of experimental colitis and impact of dietary fish oil intake.

Inflammatory bowel diseases are acute and chronic disabling inflammatory disorders with multiple complex etiologies that are not well-defined. Chronic intestinal inflammation has been linked to an energy-deficient state of gut epithelium with alterations in oxidative metabolism. Plasma-, urine-, stool-, and liver-specific metabonomic analyses are reported in a naïve T cell adoptive transfer (AT) experimental model of colitis, which evaluated the impact of long-chain n-3 polyunsaturated fatty acid (PUFA)-enriched diet. Metabolic profiles of AT animals and their controls under chow diet or fish oil supplementation were compared to describe the (i) consequences of inflammatory processes and (ii) the differential impact of n-3 fatty acids. Inflammation was associated with higher glycoprotein levels (related to acute-phase response) and remodeling of PUFAs. Low triglyceride levels and enhanced PUFA levels in the liver suggest activation of lipolytic pathways that could lead to the observed increase of phospholipids in the liver (including plasmalogens and sphingomyelins). In parallel, the increase in stool excretion of most amino acids may indicate a protein-losing enteropathy. Fecal content of glutamine was lower in AT mice, a feature exacerbated under fish oil intervention that may reflect a functional relationship between intestinal inflammatory status and glutamine metabolism. The decrease in Krebs cycle intermediates in urine (succinate, α-ketoglutarate) also suggests a reduction in the glutaminolytic pathway at a systemic level. Our data indicate that inflammatory status is related to this overall loss of energy homeostasis.

Ornithine-alpha-ketoglutarate (OKG) supplementation is more effective than its component salts in traumatized rats.

Addition of an anabolic stimulus during nutritional support seems to be a reasonable adjunct to augment protein synthesis. Ornithine-alpha-ketoglutarate (OKG) has been used for this purpose in many pathological situations, but the mechanism of action is poorly understood. We have evaluated the relative metabolic efficacy of four isonitrogenous diets with or without the addition of alpha-ketoglutarate (alpha KG) or ornithine (ORN), in a rat trauma (bilateral femur fracture) model. Both control and traumatized rats were starved for 2 d. Then for 4 d, the control rats were pair-fed to the traumatized rats, one of the four isonitrogenous diets: the basal diet was a casein-based liquid diet; the ORN and OKG diets were the basal diet in which 10% of the dietary nitrogen was replaced by ORN- or OKG-nitrogen, respectively; the alpha KG diet contained equivalent amounts of alpha KG as were present in the OKG diet. Body weight gain per gram of nitrogen intake was similar in all four diet groups of both control and traumatized rats. The fraction of nitrogen intake that was retained in the body was significantly higher in OKG-fed traumatized rats (23%) than in the corresponding basal diet-fed rats. Plasma and muscle free amino acid concentrations were comparable in OKG- and ORN-fed rats but not in OKG- and alpha KG-fed rats. Our data suggest that the mechanism of OKG action may be associated with increases in growth hormone and insulin, as well as the production of metabolites of ORN and alpha KG. OKG has better metabolic benefits than its two components given separately in the nutritional support of injured rats.

Effect of L-carnitine on cerebral and hepatic energy metabolites in congenitally hyperammonemic sparse-fur mice and its role during benzoate therapy.

Sparse-fur (spf) mutant mice with X-linked ornithine transcarbamylase deficiency were used to study the effect of L-carnitine on energy metabolites in congenital hyperammonemia. L-Carnitine was used at doses of 2, 4, 8, or 16 mmol/kg body weight (BW), and levels of ammonia, glutamine, glutamate, and some intermediates of energy metabolism were measured in brain and liver of spf/Y mice. Cerebral and hepatic levels of ammonia were decreased with 4 mmol L-carnitine (P < .001), whereas other doses did not seem to have any effect on this metabolite. Cerebral levels of glutamine were decreased following administration of L-carnitine at doses of up to 4 mmol/kg BW, whereas hepatic glutamine levels remained unaltered at all doses of L-carnitine. Both cerebral and hepatic levels of pyruvate, lactate, and alpha-ketoglutarate were decreased at doses of up to 8 mmol L-carnitine/kg BW. L-Carnitine treatment elevated adenosine triphosphate (ATP), free coenzyme A (CoA), and acetyl CoA levels in both brain and liver of spf/Y mice. Cytosolic and mitochondrial redox ratios of spf/Y mice, which were altered by congenital chronic hyperammonemia, were partially corrected by L-carnitine administration. L-Carnitine supplementation to spf/Y mice during sodium benzoate therapy also restored the availability of free CoA and ATP, thus counteracting the adverse effects of higher doses of sodium benzoate. These changes in free CoA and acetyl CoA levels could be due to the deinhibition of pantothenate kinase and stimulation of fatty acid oxidation by L-carnitine.(ABSTRACT TRUNCATED AT 250 WORDS)

The effects of vitamin D on the rat kidney metabolism under conditions of experimental hypercalcemia.

The effects of vitamin D3 on rat kideney metabolism under conditions of experimental hypercalcemia. Acta Physiol. Pol., 1978, 29 (2) 153--159. The effect of vitamin D3 on renal gluconeogenesis processes was studied in the rat. The performed estimations of gluconeogenesis rate from malate and lactate demonstrated significant increases of glucose formation rate when kidney cortex slices of the vitamin D3 treated animals were analyzed. Further studies on the mechanism of the observed phenomenon were performed using kidney cell fractionation procedure and fluorometric estimation of the concentration of selected gluconeogenetic metabolites. Significant increases of phosphoenolpyruvate concentration in the cytosol fraction and citrate concentration in the mitochondrial fraction were observed. Comparison of the described action of vitamin D3 on gluconeogenesis and the effect of parathyriod hormone, as known from the literature suggests similar mechanism of both factor actions. A possibility of vitamin D3 action through the increase in intracellular calcium has been discussed.