Inhibitory effect of high oxygen pressure on potassium- induced activation of pyruvate dehydrogenase and glucose metabolism in rat brain slices.

The effects of high oxygen pressure on pyruvate dehydrogenase (pyruvate: lipoate oxidoreductase (decarboxylating and acceptor-acylating), EC 1.2.4.1) activity, tissue concentration of ATP, and CO2 production from glucose were studied in rat brain cortical slices. The increase in pyruvate dehydrogenase activity and the lowering of cellular ATP, occurring during potassium-induced depolarization at 1 atm of oxygen, were reversed by increasing the oxygen pressure to 5 atm. When brain slices were incubated at 1 atm oxygen with [U-14C]glucose, a high potassium medium approximately doubled the production of 14CO2. Oxygen at 5 atm abolished this potassium-dependent increase in 14CO2 production with no significant effect on glucose oxidation in normal Krebs-Ringer phosphate medium. Adding 4 atm helium to 1 atm oxygen did not interfere with the ability of potassium ions to activate pyruvate dehydrogenase, lower ATP, or increase glucose oxidation. The results show that toxic effects of hyperbaric oxygen, not manifest in "resting" tissue, may be revealed during stress such as potassium depolarization. The site of the toxic effects of oxygen is probably the cell membrane where excess oxygen appears to interfere with the action of the sodium pump, calcium transport or other processes stimulated by increased concentrations of extracellular potassium.

Metabolic effects of acarbose administration in normal and diabetic rats.

The effect of acarbose on cardiac and hepatic metabolism was investigated in normal and diabetic rats. Groups of rats were fed one of the three following diets for 7 days: (1) ground Purina chow, (2) ground Purina chow fortified with raw corn starch and sucrose, and (3) the above high carbohydrate diet, with added acarbose (40 mg/100 g food). At the end of the dietary period the rats were decapitated, and a sample of liver tissue was removed and frozen in liquid nitrogen. The heart was extirpated for subsequent perfusion by the Langendorff technique. Increases in liver and heart glycogen produced by the high carbohydrate diet in the normal rats were prevented completely when acarbose was incorporated into the food. In diabetic animals, liver glycogen was uniformly lower than normal, irrespective of the diet or the presence of acarbose. With animals fed the control diet, cardiac glycogen was higher in diabetic than in normal rats. The high carbohydrate diet caused a lowering of heart glycogen in diabetic rats and this reduction in glycogen content was reversed by including acarbose in the diet. Effects of isoproterenol on myocardial phosphorylase a activity were determined in hearts from normal and diabetic rats given one of the three diets. The high carbohydrate diet decreased the enzymatic response to the catecholamine in hearts from both normal and diabetic animals, and this phenomenon was prevented by the presence of acarbose in the diet. In diabetic rats fed any of the three diets, the activation of cardiac phosphorylase by isoproterenol was greatly accentuated. Measurements of heart uridine kinase showed that the activity of this enzyme was lower than normal in hearts from diabetic rats given either the control or the high carbohydrate diet. The presence of acarbose in the latter diet resulted in a significant decrease in cardiac uridine kinase activity in hearts from normal rats. The results of this study demonstrate the effectiveness of acarbose in modulating tissue metabolism in normal and diabetic animals.

Reflections on the role of the thiol group in biology.

This essay is concerned with the role of the thiol or sulfhydrvl group in cellular function and metabolism and with the important investigations over many years that have led us to a better understanding of the importance of this molecular moiety that plays such a vital role in biology. The tools for measuring the SH group and for inhibiting or regenerating it will be discussed as will its essential role in the actions of many enzymes. The importance of the thiol group in glycolysis and in energy production by mitochondria will be emphasized. Of special interest at present is the fact that certain low molecular weight SH-containing substances can mimic some of the actions of insulin and may become of benefit in the treatment of diabetes mellitus. Finally, the toxic effects of oxygen on metabolism and function will be discussed with particular reference to the possibility that oxidation of thiol groups may play a role in the manifestations of oxygen toxicity.

The relationship between uracil nucleotide concentrations and glycogen synthesis in hepatocytes from fed and fasted rats.

The relationship between glycogen synthesis and uracil nucleotide content was studied in rat hepatocytes. When hepatocytes were incubated in the presence of uridine in the incubation medium there was an increase in the rate of incorporation of U-14C-glucose into glycogen. In hepatocytes incubated in the absence of uridine for 1 hr there were large decreases in the cellular contents of UDPG and UTP, while in the presence of 5 mM uridine the concentrations of these nucleotides increased 2 to 3 fold. In hepatocytes from fasted rats uracil nucleotide contents were lower than in hepatocytes from fed rats and the effect of uridine on glycogen synthesis was greater.

Biochemical evaluation of obstructive bladder dysfunction in men secondary to BPH: a preliminary report.

OBJECTIVES: In the rabbit, two of the major cellular alterations that mediate bladder dysfunction secondary to partial outlet obstruction are a decreased ability of the sarcoplasmic reticulum (SR) to store and release Ca2+, and mitochondrial dysfunction. The objective of the current study was to determine whether SR and mitochondrial dysfunctions are associated with symptomatic benign prostatic hyperplasia (BPH) in men. METHODS: Bladder biopsies were obtained from men with symptomatic BPH and from age-matched men with no urologic dysfunction. Each biopsy was analyzed for the following enzyme activities: malate dehydrogenase and citrate synthase (mitochondrial markers) and the sarcoplasmic reticular enzyme Ca2+ -dependent adenosine triphosphatase (ATPase). These values were compared with the enzyme activities of control rabbit bladder smooth muscle and bladder smooth muscle obtained from rabbits subjected to 2 weeks of partial outlet obstruction. RESULTS: The enzymatic activities of all three enzymes are significantly lower in human bladder smooth muscle than in rabbit bladder smooth muscle. The maximal activities of all three enzymes are significantly lower in human bladder samples obtained from men with diagnosed obstructive uropathy than in men of equal age with no urologic dysfunction. CONCLUSIONS: These studies demonstrate that similar to the response of the rabbit to partial outlet obstruction, obstructive dysfunction secondary to BPH is characterized by mitochondrial and SR dysfunction.

Genetic and cellular characteristics of bladder outlet obstruction.

Urinary bladder outlet obstruction is a common medical problem. In order to understand the effects of outlet obstruction on bladder morphology, physiology, and pharmacology, several animal models of obstruction have been developed using a variety of species. Although there are marked differences in bladder size, capacity, compliance, physiology, and pharmacology among these species, responses to outlet obstruction have many common characteristics. This article will be separated into six areas: introduction, genetic factors mediating the response during the initial period of partial outlet obstruction and overdistension, cytostructural alterations that accompany compensated bladder function, alterations in innervation accompanying bladder hypertrophy secondary to partial outlet obstruction, alterations in calcium translocation during bladder hypertrophy, and metabolic factors involved in the response to partial outlet obstruction.

Bladder function in experimental outlet obstruction: pharmacologic responses to alterations in innervation, energetics, calcium mobilization, and genetics.

The two functions of the urinary bladder is to store urine at low intravesical pressures, and to periodically expel the urine through a coordinated contraction of the bladder and relaxation of the urethra. To a large extent, urinary bladder function depends upon the underlying structure of the organ as a whole, particularly on the inter-relationships among the smooth muscle, connective tissue, and neuronal elements. An alteration in the ratio of connective tissue to smooth muscle, for example, can significantly alter compliance and functional capacity, structurally impairing the bladder's ability to empty efficiently and fully. Thus, a change in structural compartmentation can affect bladder function independent of autonomic receptor density, response to receptor stimulation, and the contractile capabilities of the smooth muscle elements. Similarly, a selective alteration in either the afferent or efferent innervation of the bladder or urethra can induce significant alterations in the structural interrelationships between smooth muscle and connective elements. In addition, the bladder responds rapidly to alterations in urine volume and urethral resistance with marked changes in bladder and urethral structure and function, and these changes are under the controls of specific genes that are known to control cellular growth, hypertrophy, and hyperplasia. A knowledge of the mechanisms that control the response to specific forms of stress may lead to novel therapies for specific disease states.