Effect of Phenazine Methosulfate on Lipogenesis

Developmental aspects of amperometric ATP biosensors based on entrapped enzymes

A novel concept for a dual-enzyme-based microbiosensor for the detection of adenosine-5'-triphosphate (ATP) was developed. The employed enzymes pyrroloquinoline quinone-dependent glucose dehydrogenase (PQQ-GDH) and hexokinase were entrapped, using pH-shift-induced precipitation of electrodeposition paint (EDP) at platinum microelectrodes (diameter of 25 microm). PQQ-GDH is known showing a superior activity for glucose conversion at the relevant conditions (low oxygen concentration) for ATP detection in targeted biomedical studies. For immobilizing the two enzymes PQQ-GDH and hexokinase, the deposition conditions of EDP Resydrol AY498w/35WA were adapted to ensure high immobilization rates. Prior to ATP sensing, the conversion of glucose, which is the co-substrate for both enzymatic reactions, was optimized. Optimization was targeted towards ATP measurements in biomedical environments by optimizing the PQQ-GDH sensor for glucose. Therefore, different mediators were tested regarding their electron transfer rate and their compatibility with the enzyme: free-diffusing N-methylphenazonium methyl sulfate (PMS) and ferrocenemethanol, and an immobilized chromium hexacyanoferrate layer at platinum electrode. Free-diffusing ferrocenemethanol reveals high sensitivity towards glucose of 1.5 +/- 0.4 nA/mM. In a next step, hexokinase was co-entrapped in the polymer film resulting in a sensitivity of up to 290 pA/microM.

Lactate metabolism and cytosolic NADH reducing equivalents in ovine adipocytes

1. Isolated ovine adipocytes, unlike rat adipose tissue, could utilize lactate at a high rate. 2. When the rate of fatty acid synthesis was attenuated with 5-(tetradecyloxy)-2-furoic acid, a fatty acid synthesis inhibitor, there was a good positive correlation between the rates of lactate oxidation to CO2 and lactate incorporation into fatty acids. 3. Addition of 2,4-dinitrophenol enhanced lactate oxidation to CO2 independent of fatty acid synthesis. Under this condition, estimated cytosolic NADH formation from lactate dehydrogenation exceeded the need of NADH for cytosolic oxaloacetate reduction and for glyceride glycerol formation. 4. Mitochondria isolated from ovine adipocytes oxidized added NADH rapidly in a reconstituted alpha-glycerophosphate shuttle system. 5. It is possible that the ability of ovine adipocytes to utilize lactate may be related to the active alpha-glycerophosphate shuttle for cytosolic NADH reoxidation.

Modulation by ketone bodies of the rate of fatty acid synthesis in mammary gland slices from lactating rats

The absolute rate of fatty acid synthesis was measured in slices of mammary gland from lactating rats by incubation in [3H]2O-labeled medium containing 10 mM D-3-hydroxybutyrate or acetoacetate alone and paired in combination with 10 mM glucose, lactate, or pyruvate. When compared with our previous studies, the ketone bodies alone supported significant fatty acid synthesis; the rate of synthesis from either ketone body and lactate was higher than that from pyruvate and lactate, and that from pyruvate and glucose; the rate of synthesis from D-3-hydroxybutyrate and lactate was the highest we have observed in the absence of an exogenous substrate for the hexose monophosphate pathway. This study confirms our previous contention that, in rat mammary gland, substrates formed in the mitochondria can be utilized in the cytosol to provide some of the NADPH necessary for fatty acid synthesis.

Effects of insulin upon fatty acids synthesis from pyruvate, lactate, and glucose in rat mammary cells

In isolated rat mammary secretory cells, insulin stimulated fatty acid synthesis from pyruvate three times, stimulated glucose conversion to fatty acids 1.2 to 1.5 times, and decreased lactate conversion to fatty acids 20 to 30%. Incubation of glucose and pyruvate together depressed fatty acid synthesis from glucose not attributable to isotope dilution. Glucose stimulated conversion of pyruvate-2-14 carbon to fatty acids without significantly affecting pyruvate-1-14 carbon conversion to 14-carbon dioxide. At differing concentrations, the electron acceptors phenazine methosulfate and N,N,N',N'-tetramethyl-p-phenylene-diamine alleviated the depression by insulin of lactate conversion to fatty acids. The data support concepts that: (1) insulin acts at important sites other than or in addition to glucose transport in regulating mammary secretory cell metabolism and, particularly, fatty acid synthesis; (2) insulin actions upon fatty acid synthesis can vary dependent upon cellular redox state (insulin increases fatty acid synthesis in cells with a low redox state and decreases fatty acid synthesis in cells in a very reduced state); and (3) pyruvate depresses glucose carbon flux through the Embden-Meyerhof pathway.