Glucose metabolism of human prostate cancer mouse xenografts

We hypothesized that the glucose metabolism of prostate cancer is modulated by androgen. We performed in vivo biodistribution and imaging studies of [F-18] fluorodeoxyglucose (FDG) accumulation in androgen-sensitive (CWR-22) and androgen-independent (PC-3) human prostate cancer xenografts implanted in castrated and noncastrated male athymic mice. The growth pattern of the CWR-22 tumor was best approximated by an exponential function (tumor size in mm3 = 14.913 e(0.1086 x days), R2 = .96, n = 5). The growth pattern of the PC-3 tumor was best approximated by a quadratic function (tumor size in mm3 = 0.3511 x days2 + 49.418 x day - 753.33, R2 = .96, n = 3). The FDG accumulation in the CWR-22 tumor implanted in the castrated mice was significantly lower, by an average of 55%, in comparison to that implanted in the noncastrated host (1.27 vs. 2.83, respectively, p < .05). The 3-week maximal standardized uptake value (SUVmax) was 0.99 +/- 0.43 (mean +/- SD) for CWR-22 and 1.21 +/- 0.32 for PC-3, respectively. The 5-week SUVmax was 1.22 +/- 0.08 for CWR-22 and 1.35 +/- 0.17 for PC-3, respectively. The background muscle SUVmax was 0.53 +/- 0.11. Glucose metabolism was higher in the PC-3 tumor than in the CWR-22 tumor at both the 3-week (by 18%) and the 5-week (by 9.6%) micro-PET imaging sessions. Our results support the notions that FDG PET may be useful in the imaging evaluation of response to androgen ablation therapy and in the early prediction of hormone refractoriness in men with metastatic prostate cancer.     

Glucose and glutamate metabolism ofLegionella pneumophila

Two serotype 1 strains ofLegionella pneumophila, Phildelphia 2 and Bellingham, were tested for their ability to metabolize five common substrates by measuring¹⁴CO₂ released and¹⁴C-carbon incorporated into macromolecules. No major differences were noted between the two strains or preparations grown in the yolk sac of chick embryos or agar-broth diphasic medium, following 2 or 14 pasaages on agar. Glutamate was the most actively metabolized substrate, followed by glutamine. Acetate, glucose, and succinate were utilized at much more moderate rates. Changes in cell density and substrate concentration altered the channeling of glutamate and glucose into CO₂ and macromolecules. Specific CO₂ felease from glutamate was greatest at low cell density and high substrate concentration, while carbon incorporation was increased at high substrate concentration. A reciprocal relationship was noted with glucose: the proportion of carbon incorporation was enhanced at low substrate concentration, but CO₂ release paralleled increases in substrate concentration. The pH optimum for glutamate carbon incorporation and CO₂ release was 5.5 and 6.1, respectively, but 25% of both activities were retained at pH 3.1. CO₂ release from glucose was maximal at pH 7.5 with negligible activity at pH 3.1. Pathways of glucose metabolism were explored by employing glucose, glucose-1-phosphate, and glucose-6-phosphate labeled in various carbon positions. The glycolytic pathway appeared to play a lesser role than the pentose phosphate and/or Entner-Doudoroff pathways. Glucose-1-phosphate was metabolized at a much higher rate than glucose or glucose-6-phosphate. We conclude that glutamate is utilized primarily as an energy source while glucose may serve as an important metabolite for the nutrition ofL. pneumophila.     

Glucose metabolism in Acetobacter aceti

Acetobacter aceti NCIB 8554 grows on a minimal medium with ethanol but not with glucose as carbon and energy source. Addition of glucose to a wild type culture on ethanol has no influence on growth of the organism. Growth of a glucose sensitive mutant A5 is inhibited by the addition of glucose until all glucose has disappeared from the medium. In order to determine the routes by which glucose is metabolised in wild type and mutant, radiorespirometric, enzymatic, and uptake experiments have been performed. For the radiorespirometric experiments of the continuous substrate feeding type an apparatus has been constructed.Of the glucose entering the cells about 30% is excreted as gluconate and 6% metabolised with liberation of C-1 as CO₂. The rest is accumulated intracellularly. No differences were found between wild type and mutant.Under different growth conditions and with different enzymatic assay methods no pyruvate kinase activity (EC 2.7.1.40) could be detected. This might explain the inability of A. aceti to grow on glucose.Abbreviations PPO 2,5-diphenyloxazole - DM-POPOP 2,2-p-phenylene bis(4-methyl-5-phenyloxazole) - TCA trichloroacetic acid     

Glucose metabolism by Lactobacillus divergens

Earlier studies on the fermentation of D-[1-14C]- and D-[3,4-14C]glucose by Lactobacillus divergens showed that lactate was the major fermentation product and that it was probably produced by glycolysis. It was therefore recommend that L. divergens be reclassified as a homofermentative organism. In the present investigation, products of D-[1-14C]-,D-[2-14C]- and D-[3,4-14C]glucose fermented by L. divergens were isolated, and their specific radioactivities and the distribution patterns of radioactivity in their C-atoms were determined. The positional labelling patterns of the fermentation products, their specific radioactivities and their concentrations confirmed that glucose is degraded via the glycolytic pathway. Some secondary decarboxylation/dissimilation of pyruvate to acetate, formate and CO2 was also observed. These results provide conclusive proof that L. divergens is indeed a homofermentative organism. Results obtained with D-[U-14C]glucose showed that approximately three-quarters of the lactate but less than 10% each of the formate and acetate were produced from glucose. The remainder was presumably derived to a varying degree from endogenous non-glucose sources such as fructose and/or amino acids.     

Glucose and fructose metabolism in Zymomonas anaerobia

Isotopic and enzymic evidence indicates that Zymomonas anaerobia ferments glucose via the Entner-Doudoroff pathway. The molar growth yields with glucose (5.89) and fructose (5.0) are lower than those for the related organism Zymomonas mobilis and the observed linear growth suggests that energetically uncoupled growth occurs. A survey of enzymes of carbohydrate metabolism revealed the presence of weak phosphofructokinase and fructose 1,6-diphosphate aldolase activities but phosphoketolase, transketolase and transaldolase were not detected. Fermentation balances for glucose and fructose are reported; acetaldehyde accumulated in both fermentations, to a greater extent with fructose which also yielded glycerol and dihydroxyacetone as minor products.     

Glucose metabolism and dimorphism in Mucor.

Mucor racemosus fermented glucose to ethanol, carbon dioxide, and glycerol. When this fungus was grown anaerobically in either the yeast or mycelial form, the catabolism of glucose was very similar. Yeast cells shifted to aerobic conditions maintained a high flux of glucose carbon through the glycolytic and pentose phosphate pathways. Mycelial cells grown aerobically catabolized glucose in a manner consistent with a respiratory metabolism. Although there was no consistent pattern of glucose metabolism in the mycelial form of Mucor, growth in the yeast form consistently was correlated with a high flux of glucose carbon through the catabolic pathways.     

Glucose metabolism by human placental villi

1. Glucose phosphorylation rates of about 1 mumole/g./min. have been measured at room temperature in homogenates of human placental chorionic villi, and these rates are relatively constant throughout gestation. 2. This reaction has an apparent K(m) for glucose of 3x10(-5)m both in early and term placenta. 3. Human foetal membranes, the amnion and chorion, also phosphorylate glucose at a rate about equal to that of the placenta. 4. On incubation of intact bits of villus tissue from 8-12-week or full-term placenta with labelled pyruvate, followed by paper chromatography of the tissue extract, the following distribution of label was observed: residual pyruvate, 40-60%; lactate, 30-50%; glucose, 6%; fructose, 7%; sorbitol, 0.6%. 5. The concept of the placenta acting as a foetal liver during early pregnancy is inconsistent with the observation that glucose production by this organ persists up to term.     

Glucose metabolism in experimental skin flaps

The metabolism of glucose by rat abdominal skin flaps has been investigated at various times after flap elevation. Biopsies of flap skin taken during the first 3 days after flap elevation and incubated in vitro show a marked increase in glucose consumption and lactate production compared with normal skin. At the same time, flap tissue reserves of glucose and glycogen are lower than those of normal skin. Providing that some circulation persists, the magnitude of the changes in glucose metabolism is proportional to the degree of ischemia experienced by the flap tissue in vivo. In most cases, glucose consumption and lactate production return to normal by the end of the first week after flap elevation. These experiments thus further define a major ischemia-induced shift to anaerobic metabolism (glycolysis) that occurs in skin flaps.     

Glucose metabolism in insulin-producing tumoral cells

Homogenates of insulin-producing tumoral cells catalyzed the phosphorylation of glucose, mannose, and fructose. The kinetics of phosphorylation at increasing glucose concentrations, the inhibitory effect of glucose 6-phosphate, and the comparison of results obtained with distinct hexoses indicated the presence of both low-Km hexokinase-like and high-Km enzymatic activities, the results being grossly comparable to those collected in normal pancreatic islets. Relative to protein content, the glucose-phosphorylating enzymatic activity was higher in tumoral than normal islet cells. The activity of other enzymes was either lower (glutamate dehydrogenase), moderately higher (phosphoglucomutase, lactate dehydrogenase) or considerably greater (ornithine decarboxylase) in tumoral than in normal islet cells. In intact tumoral cells, incubated under increasing glucose concentrations, the oxidation of D-[U-14C]glucose and the output of lactic and pyruvic acids reached a close-to-maximal value at 2.8 mM glucose. The ratios for glucose oxidation/utilization and lactate/pyruvate output were much lower in tumoral than in normal islet cells. Although glucose caused a modest increase in insulin output from the tumoral cells, this effect was saturated at a low glucose concentration (2.8 mM) and less marked than that of other secretagogues (e.g., L-leucine, L-ornithine, or forskolin). Thus, despite a close-to-normal enzymatic equipment for glucose phosphorylation, the tumoral cells displayed severe abnormalities in the metabolism and secretory response to this hexose. These findings point to regulatory mechanisms distal to glucose phosphorylation in the control of glucose metabolism in insulin-producing cells.     

Glucose metabolism by preimplantation pig embryos

Pig embryos were collected, 2-7 days after oestrus, in modified BMOC-2 containing glucose as the only energy source. Embryos were incubated individually in medium containing [5-(3)H]-, [1-(14)C]- or [6-(14)C]glucose. Total glucose metabolism, as measured by [5-(3)H]glucose use, increased steadily from the 1-cell to the 8-cell stage. Total glucose use increased (P less than 0.05) at the compacted morula stage and was highest (P less than 0.05) at the blastocyst stage. Production of 14CO2 from embryos metabolizing [1-(14)C]glucose increased steadily from the unfertilized ovum to the 8-cell stage. Metabolism of [1-(14)C]glucose increased at the compacted morula stage (P less than 0.05) and continued to increase (P less than 0.05) to the blastocyst stage. Metabolism of [6-(14)C]glucose increased steadily from the unfertilized ovum to the compacted morula stage. Metabolism of [6-(14)C]glucose was highest (P less than 0.05) for the blastocyst stage. Percentage pentose phosphate pathway activity of total glucose metabolism before the 4-cell stage was higher (greater than 5%) than that of 8-cell to blastocyst stage embryos (approximately 1%). When embryo metabolism was determined on a per cell basis for each isotope, the compacted morulae stage (16 cells) had a higher total glucose metabolism than all other embryo stages (P less than 0.05), while early blastocyst (32 cells) and blastocyst (64 cells) stage embryos metabolized more [5-(3)H]glucose than all stages except compacted morulae (P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Glucose metabolism in anaerobic rice seedlings

More than 80% of the radioactivity from [U-¹⁴C]glucose metabolised by anaerobic rice seedlings or by excised roots or coleoptiles was recovered as ethanol plus CO₂; less than 5% was recovered as water-soluble acidic components. Rates of ¹⁴CO₂ formation from [U-¹⁴C]glucose were similar in roots and coleoptiles in both N₂ and air atmospheres. More ¹⁴CO₂ was formed from [U-¹⁴C]glucose than could be accounted for by ethanolic fermentation, and the specific yields of ¹⁴CO₂ from [6-¹⁴C]glucose and [1-¹⁴C]glucose gave unusually high C-6/C-1 ratios (1.7) in the anaerobic coleoptile. The results may indicate that appreciable pentan synthesis occurs in the anaerobic coleoptile.     

Glucose metabolism in mouse pancreatic islets

1. Rates of glucose oxidation, lactate output and the intracellular concentration of glucose 6-phosphate were measured in mouse pancreatic islets incubated in vitro. 2. Glucose oxidation rate, measured as the formation of (14)CO(2) from [U-(14)C]glucose, was markedly dependent on extracellular glucose concentration. It was especially sensitive to glucose concentrations between 1 and 2mg/ml. Glucose oxidation was inhibited by mannoheptulose and glucosamine but not by phlorrhizin, 2-deoxyglucose or N-acetylglucosamine. Glucose oxidation was slightly stimulated by tolbutamide but was not significantly affected by adrenaline, diazoxide or absence of Ca(2+) (all of which may inhibit glucose-stimulated insulin release), by arginine or glucagon (which may stimulate insulin release) or by cycloheximide (which may inhibit insulin synthesis). 3. Rates of lactate formation were dependent on the extracellular glucose concentration and were decreased by glucosamine though not by mannoheptulose; tolbutamide increased the rate of lactate output. 4. Islet glucose 6-phosphate concentration was also markedly dependent on extracellular glucose concentration and was diminished by mannoheptulose or glucosamine; tolbutamide and glucagon were without significant effect. Mannose increased islet fructose 6-phosphate concentration but had little effect on islet glucose 6-phosphate concentration. Fructose increased islet glucose 6-phosphate concentration but to a much smaller extent than did glucose. 5. [1-(14)C]Mannose and [U-(14)C]fructose were also oxidized by islets but less rapidly than glucose. Conversion of [1-(14)C]mannose into [1-(14)C]glucose 6-phosphate or [1-(14)C]glucose could not be detected. It is concluded that metabolism of mannose is associated with poor equilibration between fructose 6-phosphate and glucose 6-phosphate. 6. These results are consistent with the idea that glucose utilization in mouse islets may be limited by the rate of glucose phosphorylation, that mannoheptulose and glucosamine may inhibit glucose phosphorylation and that effects of glucose on insulin release may be mediated through metabolism of the sugar.