Compartmentation of NADPH in rat liver.

Rat liver slices were incubated with specifically ³H-labeled glucoses and [2-³H]sorbitol, and the incorporations of ³H into fatty acids and cholesterol were determined. Incorporation of ³H from [1-³H]glucose relative to that from [3-³H]glucose via NADPH formed in the pentose cycle was similar into fatty acids and cholesterol. This indicates (1) the presence of a common pool of NADPH formed via the pentose cycle, from which is derived the reductive hydrogens for fatty acid and cholesterol synthesis; (2) the absence of a major separate pool of NADPH formed from glucose by microsomal glucose dehydrogenase (EC 1.1.1.47) catalysis for use in cholesterol synthesis. ³H from [4-³H]glucose and from [2-³H]sorbitol was incorporated into cholesterol more than into fatty acids relative to the incorporations of ³H from [3-³H]glucose. Assuming that the ³H from [4-³H]glucose and from [2-³H]sorbitol were incorporated via the conversion, catalyzed by malic enzyme, of NADH to NADPH, this indicates the Compartmentation of the NADPH formed via malic enzyme catalysis from that formed via the pentose cycle. Alternatively, NADH provides reductive hydrogens for cholesterol synthesis in greater measure than in fatty acid formation or the stereochemistry of the synthetic processes are such that [A-³H]NADPH has greater excess than [B-³H]NADPH to cholesterol synthesis relative to fatty acid synthesis.     

Transfer of reducing equivalents into mitochondria by the interconversions of proline and Δ1-pyrroline-5-carboxylate

Direct evidence is presented for a proline cycle using a cell-free experimental system which sequentially transfers ³H from [1-³H]glucose to NADP⁺ to Δ¹-pyrroline-5-carboxylate and yields [³H]proline. The formation of [³H]proline depends on the presence of NADP, Δ¹-pyrroline-5-carboxylate, and the enzymes glucose-6-phosphate dehydrogenase and Δ¹-pyrroline-5-carboxylate reductase. The production of [³H]proline from unlabeled proline in the presence of mitochondria provides direct evidence for one complete turn of a proline cycle which transfers reducing equivalents produced by glucose oxidation in the pentose pathway into mitochondria. In this cycle, proline is oxidized to Δ¹-pyrroline-5-carboxylate by mitochondrial proline oxidase. Δ¹-pyrroline-5-carboxylate is released from mitochondria and is recycled back to proline by Δ¹-pyrroline-5-carboxylate reductase with concomitant oxidation of NADPH. At the maximal rate observed, 60% of Δ¹-pyrroline-5-carboxylate produced is recycled back to proline. This cycle provides a mechanism for transferring reducing equivalents from NADPH into mitochondria and is linked to glucose oxidation in the pentose pathway by NADPH turnover.     

Activity of the pentose phosphate pathway during lignification

Summary We did this work to see if there is a correlation between lignin synthesis and the activity of the pentose phosphate pathway. Excision of the third internode of the stem of Coleus blumei Benth. followed by incubation on sucrose and indoleacetic acid led to extensive formation of tracheids. During this lignification we determined the activities of glucose-6-phosphate dehydrogenase and fructose-1,6-diphosphate aldolase, and the extent to which [1-¹⁴C]-,[3,4-¹⁴C]-, and [6-¹⁴C]glucose labelled CO₂ and the major cellular components. The results indicate that the pentose phosphate pathway was active during lignification, and that the activity of this pathway relative to glycolysis increased at the onset of lignification. Explants of storage tissue of Helianthus tuberosus L. were cultured under conditions which caused extensive lignification. ¹⁴CO₂ production from [1-¹⁴C]-, [3,4-¹⁴C]-, and [6-¹⁴C]glucose indicated activity of the pentose phosphate pathway during tracheid formation. We suggest that lignification is accompanied by appreciable activity of the pentose phosphate pathway and that this could provide the reducing power for lignin synthesis.Abbreviations NADP nicotinamide-adenine dinucleotide phosphate - IAA indoleacetic acid     

Effectors of fatty acid synthesis in hepatoma tissue culture cells

An investigation was undertaken to better understand the process of fatty acid synthesis in hepatoma tissue culture (HTC) cells. By comparing the findings to the normal liver some of the differences between normal and cancer tissue were defined. Incubation of the HTC cells in a buffered salt-defatted albumin medium showed that fatty acid synthesis was dependent upon the addition of substrate. The order of stimulation was glucose + pyruvate ～- glucose + alanine ～- glucose + lactate ～- pyruvate > glucose > alanine ? no additions. Fatty acid synthesis in HTC cells was decreased by oleate. In these respects HTC cells are similar to the liver; however, in contrast to the normal liver, N⁶, O²-dibutyryl cyclic adenosine 3′,5′-monophosphate (dibutyryl-cAMP) did not inhibit glycolysis or fatty acid synthesis. The cytoplasmic redox potential, as reflected by the lactate to pyruvate ratio, was found to be elevated compared to normal liver but unchanged by the addition of dibutyryl cAMP. Since higher rates of fatty acid synthesis are associated with lower lactate-to-pyruvate ratios in normal liver, it was expected that by decreasing the lactate-to-pyruvate ratio in HTC cells the rate of fatty acid synthesis would increase. One way to lower the lactate to pyruvate ratio is to increase the activity of the malate-aspartate shuttle. Stimulators of the hepatic malate-aspartate shuttle in normal liver (ammonium ion, glutamine, and lysine) had mixed effects on the redox state and fatty acid synthesis in HTC cells. Both ammonium ion and glutamine decreased the redox potential and increased the rate of fatty acid synthesis. Lysine was without effect on either process. Since NH₄Cl and glutamine stimulate the movement of reducing equivalents into the mitochondria and decrease the redox potential, then the stimulation of fatty acid synthesis by NH₄Cl and glutamine may be due to an increase in the movement of reducing equivalents into the mitochondria. However, if the shuttle were rate determining for fatty acid synthesis the rate from added lactate would be the same as from glucose alone but would be lower than from pyruvate which does not require the movement of reducing equivalents. This was not the case. Lactate and pyruvate gave comparable rates which were higher than glucose alone. Other possible sites of stimulation were investigated. The possibility that NH₄⁺ and glutamine stimulated fatty acid synthesis by activating pyruvate dehydrogenase was excluded by finding that dichloroacetate, an activator of pyruvate dehydrogenase, did not stimulate fatty acid synthesis when glucose was added. Stimulation by NH₄⁺ and glutamine at steps beyond pyruvate dehydrogenase was ruled out by the observation that NH₄⁺ caused no stimulation from added pyruvate. NH₄⁺ and glutamine did not alter the pentose phosphate pathway as determined by ¹⁴CO₂ production from [1-¹⁴C]- or [6-¹⁴C]glucose. Ammonium ion and glutamine increased glucose consumption and increased lactate and pyruvate accumulation. The increased glycolysis in HTC cells appears to be the explanation for the stimulation of fatty acid synthesis by NH₄⁺ and glutamine, even though glycolysis is much more rapid than fatty acid synthesis in these cells. The following observations support this conclusion. First, the percentage increase in glycolysis caused by NH₄⁺ or glutamine is closely matched by the percentage increase in fatty acid synthesis. Second, the malate-aspartate shuttle, the pentose phosphate pathway, and the steps past pyruvate are not limiting in the absence of NH₄⁺ or glutamine.     

Interrelationship and control of glucose metabolism and lipogenesis in isolated fat-cells. Effect of the amount of glucose uptake on the rates of the pentose phosphate cycle and of fatty acid synthesis

In order to study the quantitative relationship between fatty acid synthesis and pentose phosphate-cycle activity under different hormonal and dietary conditions affecting the extent of glucose uptake, cells isolated from rat epididymal adipose tissue were incubated in bicarbonate buffer containing [U-(14)C]-, [1-(14)C]- or [6-(14)C]-glucose. From the amount of glucose taken up, the production of lactate and pyruvate, and the incorporation of (14)C from differently labelled [(14)C]glucose into CO(2), fatty acids and glyceride glycerol, the rates of glucose metabolism via different pathways and the extent of lipogenesis under various experimental conditions were determined. The contribution of the pentose phosphate-cycle to glucose metabolism under normal conditions was calculated to be 8%. Starvation and re-feeding, and the presence of insulin, caused an enhancement of glucose uptake, pentose phosphate-cycle activity and fatty acid synthesis. Plots of both pentose phosphate-cycle activity and fatty acid synthesis versus glucose uptake revealed that the extent of glucose uptake, over a wide range, determines the rates of fatty acid synthesis and glucose metabolism via the pentose phosphate cycle. A balance of formation and production of nicotinamide nucleotides in the cytoplasm was established. The total amount of cytoplasmic NADH and NADPH formed was only in slight excess over the hydrogen equivalents required for the synthesis of fatty acids, glyceride glycerol and lactate. Except in cells from starved animals, the pentose phosphate cycle was found to provide only about 60% of the NADPH required for fatty acid synthesis. The results are discussed with respect to an overall control of the different metabolic and biosynthetic reactions in the fat-cells by the amount of glucose transported into the cell.     

The role of the pentose phosphate shunt in glucose-induced insulin release: In vitro studies with 6-aminonicotinamide, methylene blue, NAD, NADH, NADP, NADPH and nicotinamide on isolated pancreatic rat islets

The possible role of the pentose phosphate shunt in insulin release was investigated in vitro with collagenase isolated pancreatic islets of rats. Parameters measured were insulin released into the medium and measured by an immunoassay and formation of ¹⁴CO₂ from glucose labeled either in the C-1 or C-6 position. The in vitro effect of the following substances was studied:

1. 1. 6-Aminonicotinamide, an antimetabolite in the synthesis of pyridine nucleotides. In islets of animals pretreated with 6-amino nicotinamide 6 h previously and in the presence of 3 mg/ml glucose in the incubation medium, 6-aminonicotinamide markedly reduced oxidation of [1-¹⁴C]glucose but did not affect that of glucose labeled in C-6. Concomitantly there was a marked decrease in insulin release. This action of 6-aminonicotinamide did not take place when it was added only to the incubation medium. Pretreatment with 6-aminonicotinamide did not change the insulin concentration of the islets, making it unlikely that it interfered with insulin synthesis. The effect of 6-aminonicotinamide is consistent with partial inhibition of the pentose shunt.

2. 2. Methylene blue: this agent was selected because it is known from studies with red blood cells that it will oxidize NADPH and thus stimulate activity of the pentose shunt. In concentrations of 0.5 and 2 μg/ml, methylene blue markedly stimulated oxidation of [1-¹⁴C]glucose but not that of C-6. Simultaneously there was a dose related decrease of insulin released.

3. 3. Pyridine nucleotides: in the absence of glucose only NADPH exhibited a significant effect of insulin release. If glucose (3 mg/ml) was present 1 or 10 mM of NAD⁺ or NADH exhibited a significant effect, NADP⁺ or NADPH were less effective. If the pentose shunt was blocked by pretreatment with 6-aminonicotinamide, all 4 pyridine nucleotides stimulated insulin release. Similarly there was an increase in oxidation of [1-¹⁴C]glucose, consitent with restimulation of the pentose shunt.

4. 4. Nicotinamide by itself exhibited a small effect; however, it was much less than the one produced by equimolar concentrations of the pyridine nucleotides.

Conclusion: Restricted availability of NADPH either less production or by fast removal leads to a decrease in glucose-induced insulin release. Pyridine nucleotides will restimulate 6-aminonicotinamide blockade insulin release and glucose oxidation by the pentose shunt. Recently it has been proposed by others that the polyol pathway may play a key role in insulin release, our data are consistent with such a hypothesis. Furthermore they do support a major role of the pentose shunt in insulin release.     

Sucrose and starch metabolism in carrot (Daucus carota L.) cell suspensions analysed by 13-labelling: indications for a cytosol and a plastid-localized oxidative pentose phosphate pathway

Cells were grown in batch culture on a mixture of 50 mM glucose and fructose as the carbon source; either the glucose or the fructose was [1-¹³C]-labelled. In order to investigate the uptake and conversion of glucose and fructose during long-term labelling experiments in cell suspensions of Daucus carota L., samples were taken every 2 d during a 2 week culture period and sucrose and starch were assayed by means of HPLC and ¹³C-nuclear magnetic resonance. The fructose moieties of sucrose had a lower labelling percentage than the glucose moieties. Oxidative pentose phosphate pathway activity in the cytosol is suggested to be responsible for this loss of label of especially C-1 carbons. A combination of oxidative pentose phosphate pathway activity, a relatively high activity of pathway to sucrose synthesis and a slow equilibration between glucose-6-phosphate and fructose-6-phosphate could explain these results. Starch contained glucose units with a much lower labelling percentage than glucose moieties of sucrose: it was concluded that a second, plastid-localized, oxidative pentose phosphate pathway was responsible for removal of C-1 carbons of the glucosyl units used for synthesis of starch. Redistribution of label from [1-¹³C]-hexoses to [6-¹³C]-hexoses also occurred: 18-45% of the label was found at the C-6 carbons. This is a consequence of cycling between hexose phosphates and those phosphates in the cytosol catalysed by PFP. The results indicate that independent (oxidative pentose phosphate pathway mediated) sugar converting cycles exist in the cytosol and plastid.Key words: Daucus carotaL., cell suspensions, carbon-13 nuclear magnetic resonance, ¹³C-NMR, carbohydrate cycling, oxidative pentose phosphate pathway, plastid.      

The utilization of glucose for the synthesis of milk components in the fed and starved lactating goat in vivo.

1. [U-14C]Glucose and [3-3H]glucose were infused into fed and starved lactating goats in order to study glucose metabolism in the mammary gland. 2. Glucose carbon was oxidized and metabolizet to milk lactose, citrate and triacylglycerol in the lactating goat udder. 3. Recycling of glucose carbon in the lactating animal accounted for 10-20% of the total glucose turnover in the whole animal. Recycling of glucose 6-phosphate in the udder accounted for about 25% of the glucose 6-phosphate metabolized. 4. Flux of glucose 6-phosphate through the pentose phosphate pathway was sufficient to account for 34% of the NADPH required for fatty acid synthesis in the gland in the fed animal. 5. Net metabolism of glucose 6-phosphate via the pentose phosphate pathway accounted for 17.8 and 1.2% of the glucose phosphorylated by the mammary gland in the fed and starved animal respectively. Metabolism of glucose 6-phosphate via the pentose phosphate pathway was sufficient to account for all the CO2 produced from glucose in the fed animal, but only 17% of the CO2 produced from glucose in the starved animal.     

Characterization of oil-producing yeast Lipomyces starkeyi on glycerol carbon source based on metabolomics and 13C-labeling

Lipomyces starkeyi is an oil-producing yeast that can produce triacylglycerol (TAG) from glycerol as a carbon source. The TAG was mainly produced after nitrogen depletion alongside reduced cell proliferation. To obtain clues for enhancing the TAG production, cell metabolism during the TAG-producing phase was characterized by metabolomics with ¹³C labeling. The turnover analysis showed that the time constants of intermediates from glycerol to pyruvate (Pyr) were large, whereas those of tricarboxylic acid (TCA) cycle intermediates were much smaller than that of Pyr. Surprisingly, the time constants of intermediates in gluconeogenesis and the pentose phosphate (PP) pathway were large, suggesting that a large amount of the uptaken glycerol was metabolized via the PP pathway. To synthesize fatty acids that make up TAG from acetyl-CoA (AcCoA), 14 molecules of nicotinamide adenine dinucleotide phosphate (NADPH) per C16 fatty acid molecule are required. Because the oxidative PP pathway generates NADPH, this pathway would contribute to supply NADPH for fatty acid synthesis. To confirm that the oxidative PP pathway can supply the NADPH required for TAG production, flux analysis was conducted based on the measured specific rates and mass balances. Flux analysis revealed that the NADPH necessary for TAG production was supplied by metabolizing 48.2% of the uptaken glycerol through gluconeogenesis and the PP pathway. This result was consistent with the result of the ¹³C-labeling experiment. Furthermore, comparison of the actual flux distribution with the ideal flux distribution for TAG production suggested that it is necessary to flow more dihydroxyacetonephosphate (DHAP) through gluconeogenesis to improve TAG yield.

     

Mitochondria Contribute to NADPH Generation in Mouse Rod Photoreceptors

NADPH is the primary source of reducing equivalents in the cytosol. Its major source is considered to be the pentose phosphate pathway, but cytosolic NADP⁺-dependent dehydrogenases using intermediates of mitochondrial pathways for substrates have been known to contribute. Photoreceptors, a nonproliferating cell type, provide a unique model for measuring the functional utilization of NADPH at the single cell level. In these cells, NADPH availability can be monitored from the reduction of the all-trans-retinal generated by light to all-trans-retinol using single cell fluorescence imaging. We have used mouse rod photoreceptors to investigate the generation of NADPH by different metabolic pathways. In the absence of extracellular metabolic substrates, NADPH generation was severely compromised. Extracellular glutamine supported NADPH generation to levels comparable to those of glucose, but pyruvate and lactate were relatively ineffective. At low extracellular substrate concentrations, partial inhibition of ATP synthesis lowered, whereas suppression of ATP consumption augmented NADPH availability. Blocking pyruvate transport into mitochondria decreased NADPH availability, and addition of glutamine restored it. Our findings demonstrate that in a nonproliferating cell type, mitochondria-linked pathways can generate substantial amounts of NADPH and do so even when the pentose phosphate pathway is operational. Competing demands for ATP and NADPH at low metabolic substrate concentrations indicate a vulnerability to nutrient shortages. By supporting substantial NADPH generation, mitochondria provide alternative metabolic pathways that may support cell function and maintain viability under transient nutrient shortages. Such pathways may play an important role in protecting against retinal degeneration.     

Pentose cycle and reducing equivalents in rat mammary-gland slices

1. Slices of mammary gland of lactating rats were incubated with glucose labelled uniformly with (14)C and in positions 1, 2, 3 and 6, and with (3)H in all six positions. Glucose carbon atoms are incorporated into CO(2), fatty acids, lipid glycerol, the glucose and galactose moieties of lactose, lactate, soluble amino acids and proteins. C-3 of glucose appears in fatty acids. The incorporation of (3)H into fatty acids is greatest from [3-(3)H]glucose. (3)H from [5-(3)H]glucose appears, apart from in lactose, nearly all in water. 2. The specific radioactivity of the galactose moiety of lactose from [1-(14)C]- and [6-(14)C]-glucose was less, and that from [2-(14)C]- and [3-(14)C]-glucose more, than that of the glucose moiety. There was no randomization of carbon atoms in the glucose moiety, but it was extensive in galactose. 3. The pentose cycle was calculated from (14)C yields in CO(2) and fatty acids, and from the degradation of galactose from [2-(14)C]glucose. A method for the quantitative determination of the contribution of the pentose cycle, from incorporation into fatty acids from [3-(14)C]glucose, is derived. The rate of the reaction catalysed by hexose 6-phosphate isomerase was calculated from the randomization pattern in galactose. 4. Of the utilized glucose, 10-20% is converted into lactose, 20-30% is metabolized via the pentose cycle and the rest is metabolized via the Embden-Meyerhof pathway. About 10-15% of the triose phosphates and pyruvate is derived via the pentose cycle. 5. The pentose cycle is sufficient to provide 80-100% of the NADPH requirement for fatty acid synthesis. 6. The formation of reducing equivalents in the cytoplasm exceeds that required for reductive biosynthesis. About half of the cytoplasmic reducing equivalents are probably transferred into mitochondria. 7. In the Appendix a concise derivation of the randomization of C-1, C-2 and C-3 as a function of the pentose cycle is described.     

Changes in pathways of pentose phosphate formation in relation to phosphoribosyl pyrophosphate synthesis in the developing rat kidney. Effects of glucose concentration and electron acceptors

Phosphoribosyl pyrophosphate (PPRibP), required in nucleotide synthesis, increases 2-fold in rat kidney from 1 day post partum to adult stage; there is no accompanying increase in PPRibP synthetase activity measured in vitro. Ribose 5-phosphate is a key factor in the regulation of PPRibP synthesis. The activity and regulation of 3 routes of ribose 5-phosphate formation have been measured in renal growth: (i) the flux through the oxidative pentose phosphate pathway was high in the neonatal period but increased only +50% thereafter; (ii) the non-oxidative pentose phosphate pathway, including transketolase, increased by +145%; (iii) the rate-limiting enzymes of the glucuronate-xylulose route increased +200% from 1 day to the adult stage. The importance of systems reoxidizing NADPH was shown by: (i) the stimulation of renal PPRibP formation from glucose by phenazine methosulphate; (ii) the early involvement of the oxidative pentose phosphate pathway at the stage where NADPH is used for biosynthetic routes; (iii) the increasing involvement of the glucuronate-xylulose route, which acts as a transhydrogenase producing NADP+ in addition to pentose phosphate formation and (iv) the correlation between renal PPRibP content and the activity of aldose reductase, which, by utilization of NADPH, stimulates ribose 5-phosphate formation via the oxidative pentose phosphate pathway. Evidence is adduced that the contribution of the 3 routes of ribose 5-phosphate formation in the kidney varies at different stages of development.     

Regulation of pathways of glucose metabolism in kidney. The effect of experimental diabetes on the activity of the pentose phosphate pathway and the glucuronate-xylulose pathway.

Measurements have been made of the activities of enzymes of the pentose phosphate pathway, the glucuronate-xylulose pathway, hexokinase and phosphofructokinase in kidney of diabetic and normal rats. The activities of these enzymes keep pace with kidney growth, remaining constant per gram tissue but showing a marked increase on the basis of total activity per 100 g body wt. The formation of ¹⁴CO₂ from [1-¹⁴C]glucose and [6-¹⁴C]glucose by kidney slices from diabetic rats was decreased to approximately half the control value; evidence was obtained for an equivalent dilution of the glucose 6-phosphate pool. Correction of the ¹⁴CO₂ yields for the change in specific activity of glucose 6-phosphate yielded values consistent with the enzyme profile. Calculations from specific yields of ¹⁴CO₂ provided evidence for an increased flux of glucose via the pentose phosphate pathway in the kidney in diabetes. The results are discussed in relation to kidney hypertrophy in diabetes and the requirement for ribose 5-phosphate and NADPH for biosynthetic reactions and in relation to the thickening of the basement membrane in diabetes. These results are in accord with the concept of glucose overutilization by non-insulin-requiring tissues.     

NADPH production in the oxidative pentose phosphate pathway as source of reducing equivalents in glycolysis of human red cells in vitro.

Studies have been carried out on human erythrocytes in vitro to clarify the deficit of pyruvate formation under conditions when 2,3 DPG is degraded. The results lead to the conclusion that there exist a cross connection between the glycolytic and the oxidative pentose phosphate pathway which is mediated by the NADP/NADPH couple. NADPH serves as additional reducing equivalent in the reaction of the LDH. In the absence of glucose the pool of the metabolites of the pentose phosphate pathway is able to supply glucose-6-phosphate for the production of NADPH by recombination. The reaction of NADPH at the LDH is probably of significance under in vivo conditions.     

A carbon-13 nuclear magnetic resonance investigation of the metabolic fluxes associated withy glucose metabolism in human erythrocytes

We have used [2-¹³C]d-glucose and carbon-13 nuclear magnetic resonance (NMR) spectroscopy to investigate metabolic fluxes through the major pathways of glucose metabolism in intact human erythrocytes and to determine the interactions among these pathways under conditions that perturb metabolism. Using the method described, we have been able to measure fluxes through the pentose phosphate pathway, phosphofructokinase, the 2,3-diphosphoglycerate bypass, and phosphoglycerate kinase, as well as glucose uptake, concurrently and in a single experiment. We have measured these fluxes in normal human erythrocytes under the following conditions: (1) fully oxygenated; (2) treated with methylene blue; and (3) deoxygenated. This method makes it possible to monitor various metabolic effects of stresses in normal and pathological states. Not only has ¹³C-NMR spectroscopy proved to be a useful method for measuring in vivo flux through the pentose phosphate pathway, but it has also provided additional information about the cycling of metabolites through the non-oxidative portion of the pentose phosphate pathway. Our evidence from experiments with [1-¹³C]-, [2-¹³C]-, and [3-¹³C]d-glucoses indicates that there is an observable reverse flux of fructose 6-phosphate through the reactions catalyzed by transketolase and transaldolase, even in the presence of a net flux through the pentose phosphate pathway.     

Importance of the pentose phosphate pathway for d-glucose catabolism in the obligatory aerobic yeast Rhodotorula gracilis

d-Glucose catabolism of a phosphofructokinase-deficient yeast Rhodotorula gracilis has been studied. By using d-glucose specifically ¹⁴C-labelled at different positions and measuring the distribution of the label in various fractions of cell metabolism, the following results were found. 1. The pentose phosphate pathway, being the main pathway of d-glucose catabolism, simultaneously converts glucose molecules into pentose phosphates oxidatively by using two NADP-linked dehydrogenases and via the non-oxidative transketolase–transaldolase pathway. 2. From the correlation of the ¹⁴CO₂ liberation and the d-glucose consumption and from the fact that the pentose phosphate moiety in nucleic acids is almost equally labelled from d-[1-¹⁴C]- and d-[6-¹⁴C]-glucose, it is concluded that of the glucose utilized about 80% undergoes transformation via the non-oxidative pentose phosphate pathway. Only about 20% of glucose is directly decarboxylated to pentose phosphate. 3. For further degradation it is postulated that the pentose phosphates are split into C₂ fragments and glyceraldehyde 3-phosphates. 4. All three loci of oxidative decarboxylation appear to be effective in Rh. gracilis, the oxidative part of the pentose phosphate pathway, the decarboxylation of pyruvate in the later part of the glycolytic pathway as well as the oxidation in the tricarboxylic acid cycle. 5. d-Glucose molecules taken up are only partially oxidized to CO₂: about four-fifths of each glucose molecule metabolized is incorporated into cell constituents. 6. The quantitative interrelations of the fluxes of d-glucose subunits along the catabolic pathways have been estimated and are discussed.     

Characterization of enzymes involved in the central metabolism of Gluconobacter oxydans

Gluconobacter oxydans is an industrially important bacterium that lacks a complete Embden–Meyerhof pathway (glycolysis). The organism instead uses the pentose phosphate pathway to oxidize sugars and their phosphorylated intermediates. However, the lack of glycolysis limits the amount of NADH as electron donor for electron transport phosphorylation. It has been suggested that the pentose phosphate pathway contributes to NADH production. Six enzymes predicted to play central roles in intracellular glucose and gluconate flux were heterologously overproduced in Escherichia coli and characterized to investigate the intracellular flow of glucose and gluconates into the pentose phosphate pathway and to explore the contribution of the pentose phosphate pathway to NADH generation. The key pentose phosphate enzymes glucose 6-phosphate dehydrogenase (Gox0145) and 6-phosphogluconate dehydrogenase (Gox1705) had dual cofactor specificities but were physiologically NADP- and NAD-dependent, respectively. Putative glucose dehydrogenase (Gox2015) was NADP-dependent and exhibited a preference for mannose over glucose, whereas a 2-ketogluconate reductase (Gox0417) displayed dual cofactor specificity for NAD(P)H. Furthermore, a putative gluconokinase and a putative glucokinase were identified. The gluconokinase displayed high activities with gluconate and is thought to shuttle intracellular gluconate into the pentose phosphate pathway. A model for the trafficking of glucose and gluconates into the pentose phosphate pathway and its role in NADH generation is presented. The role of NADPH in chemiosmotic energy conservation is also discussed.     

Metabolic evolution of two reducing equivalent-conserving pathways for high-yield succinate production in Escherichia coli

Reducing equivalents are an important cofactor for efficient synthesis of target products. During metabolic evolution to improve succinate production in Escherichia coli strains, two reducing equivalent-conserving pathways were activated to increase succinate yield. The sensitivity of pyruvate dehydrogenase to NADH inhibition was eliminated by three nucleotide mutations in the lpdA gene. Pyruvate dehydrogenase activity increased under anaerobic conditions, which provided additional NADH. The pentose phosphate pathway and transhydrogenase were activated by increased activities of transketolase and soluble transhydrogenase SthA. These data suggest that more carbon flux went through the pentose phosphate pathway, thus leading to production of more reducing equivalent in the form of NADPH, which was then converted to NADH through soluble transhydrogenase for succinate production. Reverse metabolic engineering was further performed in a parent strain, which was not metabolically evolved, to verify the effects of activating these two reducing equivalent-conserving pathways for improving succinate yield. Activating pyruvate dehydrogenase increased succinate yield from 1.12 to 1.31 mol/mol, whereas activating the pentose phosphate pathway and transhydrogenase increased succinate yield from 1.12 to 1.33 mol/mol. Activating these two pathways in combination led to a succinate yield of 1.5 mol/mol (88% of theoretical maximum), suggesting that they exhibited a synergistic effect for improving succinate yield.     

The NADPH consumption regulates the NADPH-producing pathways (pentose phosphate cycle and malic enzyme) in rat adipocytes

The changes in the activity of the pentose phosphate cycle and the malic enzyme produced by the activation or inhibition of different NADPH-consuming pathways have been studied. The inhibition of the fatty acid synthesis by kynurenate produced a decrease in the flux through the pentose phosphate cycle and a diminution in the malic enzyme pathway. The incubation of the adipocytes in the presence of ter-butyl-hydroperoxide, a compound which is metabolized via a NADPH-consuming pathway, produced a big increase in the pentose phosphate cycle and the malic enzyme activities. The regulation of these NADPH-producing pathways by the NADPH/NADP ratio is discussed.     

Sterol synthesis by the ocular lens of the rat during postnatal development

Great amounts of plasma membranes are formed during early postnatal development of the ocular lens as lens epithelial cells differentiate into fiber cells. Little information is available on the source of the lipids, and particularly cholesterol, required for formation of these plasma membranes. The present study measured the capacity of the lens of the rat to synthesize cholesterol during this dynamic period of growth. Incorporation by lens of (3)H(2)O into total fatty acids was also examined. Absolute rates of cholesterol synthesis per whole lens were estimated in vitro from incorporation of (3)H from (3)H(2)O into digitonide precipitable sterols (DPS) by intact lenses of 6- to 30-day old rats. Rates of cholesterol synthesis were calculated which were adequate to furnish from either 50-100% or 20-40% of the cholesterol required by the lens for growth, depending upon the animal's age and upon whether one considered NADPH to be generated by the pentose phosphate pathway or by oxidative enzymatic processes (NADPH from the pentose pathway is not labeled from (3)H(2)O). Generation of the NADPH necessary for cholesterol synthesis principally by the pentose pathway would support the higher percent contribution of synthesis to the total growth requirement. The pentose pathway was clearly active in the young rat lens, since between 7.5 to 9.0 times more [1-(14)C]glucose than [6-(14)C]glucose was oxidized in vitro to (14)CO(2) by 6- and 22-day old lenses. Incorporation of (3)H(2)O into DPS decreases sharply after 2 weeks of age in spite of a constant rate of cholesterol accumulation by the lens. These results indicate that the ocular lens of the rat can furnish most if not all of its cholesterol requirements by synthesis de novo during the first 2 weeks of life, and imply a contribution from another source at older ages. Whether lipoproteins can supply cholesterol to the lens is still unclear, although neither HDL nor LDL altered the incorporation in vitro of [U-(14)C]glucose into DPS by lens.-Cenedella, R. J. Sterol synthesis by the ocular lens of the rat during postnatal development.