A convenient program for the rapid calculation of sedimentation coefficients in linear salt or sucrose gradients

A program is presented for calculating s_20,w values from data obtained by zone sedimentation in linear sucrose or salt gradients in a variety of rotors at temperatures ranging from 0° to 20°C. The program can be either run with the use of high-speed computers or performed with the aid of a small calculator in a reasonably short time.     

Influence of Carbon Source on Nitrate Removal by Nitrate-Tolerant Klebsiella oxytoca CECT 4460 in Batch and Chemostat Cultures

The nitrate-tolerant organism Klebsiella oxytoca CECT 4460 tolerates nitrate at concentrations up to 1 M and is used to treat wastewater with high nitrate loads in industrial wastewater treatment plants. We studied the influence of the C source (glycerol or sucrose or both) on the growth rate and the efficiency of nitrate removal under laboratory conditions. With sucrose as the sole C source the maximum specific growth rate was 0.3 h⁻¹, whereas with glycerol it was 0.45 h⁻¹. In batch cultures K. oxytoca cells grown on sucrose or glycerol were able to immediately use sucrose as a sole C source, suggesting that sucrose uptake and metabolism were constitutive. In contrast, glycerol uptake occurred preferentially in glycerol-grown cells. Independent of the preculture conditions, when sucrose and glycerol were added simultaneously to batch cultures, the sucrose was used first, and once the supply of sucrose was exhausted, the glycerol was consumed. Utilization of nitrate as an N source occurred without nitrite or ammonium accumulation when glycerol was used, but nitrite accumulated when sucrose was used. In chemostat cultures K. oxytoca CECT 4460 efficiently removed nitrate without accumulation of nitrate or ammonium when sucrose, glycerol, or mixtures of these two C sources were used. The growth yields and the efficiencies of C and N utilization were determined at different growth rates in chemostat cultures. Regardless of the C source, yield carbon (Y_C) ranged between 1.3 and 1.0 g (dry weight) per g of sucrose C or glycerol C consumed. Regardless of the specific growth rate and the C source, yield nitrogen (Y_N) ranged from 17.2 to 12.5 g (dry weight) per g of nitrate N consumed. In contrast to batch cultures, in continuous cultures glycerol and sucrose were utilized simultaneously, although the specific rate of sucrose consumption was higher than the specific rate of glycerol consumption. In continuous cultures double-nutrient-limited growth appeared with respect to the C/N ratio of the feed medium and the dilution rate, so that for a C/N ratio between 10 and 30 and a growth rate of 0.1 h⁻¹ the process led to simultaneous and efficient removal of the C and N sources used. At a growth rate of 0.2 h⁻¹ the zone of double limitation was between 8 and 11. This suggests that the regimen of double limitation is influenced by the C/N ratio and the growth rate. The results of these experiments were validated by pulse assays.     

Interaction of cell turgor and hormones on sucrose uptake in isolated Phloem of celery

Phloem tissue isolated from celery (Apium graveolens L.) was used to investigate the regulation of sucrose uptake by turgor (manipulated by 50-400 milliosomolal solutions of polyethylene glycol) and hormones indoleacetic acid (IAA) and gibberillic acid (GA₃). Sucrose uptake was enhanced under low cellular turgor (increase in the V_max). Furthermore, enhancement of sucrose uptake was due to a net increase in influx rates since sucrose efflux was not affected by cell turgor. Manipulations of cell turgor had no effect on 3-O-methyl glucose uptake. When 20 millimolar buffer was present in uptake solutions, low turgor-induced effects were observed only at low pH range (4.5-5.5). However, the effect was extended to higher external pH (up to 7.5) when buffer was omitted from uptake solutions. A novel interaction between cellular turgor and hormone treatments was observed, in that GA₃ (10 micromolar) and IAA (0.1-100 micromolar) enhanced sucrose uptake only at moderate turgor levels. The hormones elicited little or no response on sucrose uptake under conditions of low or high cell turgor. Low cell turgor, IAA, GA₃, and fusicoccin caused acidification by isolated phloem segments in a buffer-free solution. It is suggested that enhanced sucrose uptake in response to low turgor and/or hormones was mediated through the plasmalemma H⁺-ATPase and most likely occurred at the site of loading.     

Simultaneous production of citric acid and invertase by Yarrowia lipolytica SUC+ transformants

Simultaneous production of citric acid (CA) and invertase by Yarrowia lipolytica A-101-B56-5 (SUC⁺ clone) growing from sucrose, mixture of glucose and fructose, glucose or glycerol was investigated. Among the tested substrates the highest concentration of CA was reached from glycerol (57.15 g/L) with high yield (Y_CA/S = 0.6 g/g). When sucrose was used, comparable amount of CA was secreted (45 g/L) with slightly higher yield (Y_CA/S = 0.643 g/g). In all cultures amount of isocitrate (ICA) was below 2% of total citrates. Considering invertase production, the best carbon source appeared to be sucrose (72 380 U/L). The highest yield of CA and invertase biosynthesis calculated for 1 g of biomass was obtained for cells growing from glycerol (9.9 g/g and 4325 U/g, respectively). Concentrates of extra- and intracellular invertase of the highest activity were obtained from sucrose as substrate (0.5 and 1.8 × 10⁶ U/L, respectively).     

Isolation and characterization of pyruvate carboxylase from Azotobacter vinelandii OP

Pyruvate carboxylase has been detected in, and partially purified from, cell-free extracts of Azotobacter vinelandii OP. The best preparations obtained have specific activities in the range of 4 units/mg and appear approximately 15% pure when analyzed by polyacrylamide gel electrophoresis. The partially purified enzyme is activated by both univalent and divalent cations, contains one or more functional biotinyl residues, and exhibits apparent Michaelis constants for the substrates (pyruvate, Mg-ATP^2?, and HCO₃^?) which are in the same range as those observed for other pyruvate carboxylases. However, A. vinelandii pyruvate carboxylase is fully active in the absence of added acetyl-coenzyme A and is insensitive to inhibition by dicarboxylic acids such as l-aspartate, l-glutamate, and α-ketoglutarate. The molecular weight of the catalytically active species is obtained as 296,000.The level of pyruvate carboxylase is highest in extracts of A. vinelandii grown on pyruvate or l-lactate as sole carbon source and this level is further enhanced on addition of succinate to the medium. The enzyme is absent from cells grown on succinate and is present at intermediate levels in cells grown on sucrose, glucose, glycerol, or acetate. In contrast, the level of phosphoenolypyruvate carboxylase in these extracts is essentially independent of the carbon source. These data suggest that pyruvate carboxylase in A. vinelandii is induced by pyruvate or some closely related metabolite.     

Conductance studies on the interaction of sucrose with symmetrical tetraalkylammonium halides in formamide

The interaction of sucrose with symmetrical tetraalkylammoniurn halides (R₄NX) in formamide has been studied by employing conductance measurements. Conductance data of these salts in formamide saturated by sucrose at 50.0 ±0.05° are reported in the temperature range 25 to 70°. Plots of —log (specific conductance) against 1/T showed a break at the saturation temperature, where two straight lines intersect one another. Divergence of the pairs of straight lines in these homogeneous, ternary systems was found to be highly influenced by the structure-making or -breaking properties of the electrolytes. The results are interpreted in terms of the structural properties of the electrolytes and the hydrogen-bonding capabilities of the formamide and sucrose molecules. A similarity in the conductance behavior of R₄N⁺ ions in both aqueous and formamide solutions containing sucrose at saturation concentration has been observed. The transitional effect is more pronounced for R₄N⁺ ions in formamide than in aqueous systems, and this is attributed to the less-structured nature and higher dielectric constant of formamide.     

A method for predicting the location of particles sedimenting in sucrose gradients

A theory was developed for the calculation of the positions of zones of particles sedimenting through a sucrose gradient. Equations were derived for particles sedimenting through gradients in which the sucrose concentration is (a) a linear function of radius, or (b) a hyperbolic function of radius. Computations were made for both swing-out and zonal rotors. The theory, which is based on direct integration of the sedimentation equation, exploits equations relating (a) the density of sucrose solutions to sucrose concentration and (b) the viscosity of sucrose solutions to sucrose concentration, and also the concept of reduced time (T/2 = S20.w integral of t to w2dt) of Fujita. The required computations may be made using a scientific calculator. Experimental support for the theory was obtained.     

The effect of amphotericin B on the water and nonelectrolyte permeability of thin lipid membranes

This paper reports the effects of amphotericin B, a polyene antibiotic, on the water and nonelectrolyte permeability of optically black, thin lipid membranes formed from sheep red blood cell lipids dissolved in decane. The permeability coefficients for the diffusion of water and nonelectrolytes (P_DDi) were estimated from unidirectional tracer fluxes when net water flow (J_w) was zero. Alternatively, an osmotic water permeability coefficient (P_f) was computed from J_w when the two aqueous phases contained unequal solute concentrations. In the absence of amphotericin B, when the membrane solutions contained equimolar amounts of cholesterol and phospholipid, P_f was 22.9 ± 4.6 µsec^-1 and P _DDHDH2O was 10.8 ± 2.4 µsec^-1. Furthermore, P_DDi was < 0.05 µsec^-1 for urea, glycerol, ribose, arabinose, glucose, and sucrose, and σ_i, the reflection coefficient of each of these solutes was one. When amphotericin B (10^-6 M) was present in the aqueous phases and the membrane solutions contained equimolar amounts of cholesterol and phospholipid, P _DDHDH2O was 18.1 ± 2.4 µsec^-1; P_f was 549 ± 143 µsec^-1 when glucose, sucrose, and raffinose were the aqueous solutes. Concomitantly, P_DDi varied inversely, and σ_i directly, with the effective hydrodynamic radii of the solutes tested. These polyene-dependent phenomena required the presence of cholesterol in the membrane solutions. These data were analyzed in terms of restricted diffusion and filtration through uniform right circular cylinders, and were compatible with the hypothesis that the interactions of amphotericin B with membrane-bound cholesterol result in the formation of pores whose equivalent radii are in the range 7 to 10.5 A.     

Studies on electrolyte-nonelectrolyte interactions: Viscosity behavior of alkali halides aqueous sucrose solutions

The effect of various added electrolytes (sodium and potassium halides of progressively increasing molecular volume) on the viscosity behavior of aqueous sucrose solution (292mM) has been investigated. Data are presented for the concentration range 0.125–3M of the electrolytes over the temperature range of 25 to 40°. The data have been found to satisfy Moulik's equation,(η/η₀)²M +K¹C², for concentrated solutions of electrolytes beyond the Einstein region. The “effective” rigid, molar volume (V_e) and apparent. Jones-Dole B-coefficient (in sucrose solution) have been computed by employing the Breslau-Miller treatment. The change in the viscosity behavior is attributed to structuring effects in solution.     

Cation-Dependent Binding of Substrate to the Folate Transport Protein of Lactobacillus casei

Lactobacillus casei cells grown in the presence of limiting folate contained large amounts of a membrane-associated binding protein which mediates folate transport. Binding to this protein at 4°C was time and concentration dependent and at low levels (1 to 10 nM) of folate required 60 min to reach a steady state. The apparent dissociation constant (K_d) for folate was 1.2 nM at pH 7.5 in 100 mM K-phosphate buffer, and it varied by less than twofold when measured over a range of pH values (5.5 to 7.5) or in buffered salt solutions of differing ionic compositions. Conversely, removal of ions and their replacement with isotonic sucrose (pH 7.5) led to a 200-fold reduction in binding affinity for folate. Restoration of the high-affinity state of the binding protein could be achieved by the readdition of various cations to the sucrose medium. K_d measurements over a range of cation concentrations revealed that a half-maximal restoration of binding affinity was obtained with relatively low levels (10 to 50 μM) of divalent cations (e.g., Ca²⁺, Mg²⁺, and ethylenediammonium²⁺ ions). Monovalent cations (e.g., Na⁺, K⁺, and Tris⁺) were also effective, but only at concentrations in the millimolar range. The K_d for folate reached a minimum of 0.6 nM at pH 7.5 in the presence of excess CaCl₂. In cells suspended in sucrose, the affinity of the binding protein for folate increased 20-fold by decreasing the pH from 7.5 to 4.5, indicating that protons can partially fulfill the cation requirement. These results suggest that the folate transport protein of L. casei may contain both a substrate- and cation-binding site and that folate binds with a high affinity only after the cation-binding site has been occupied. The presence of these binding sites would support the hypothesis that folate is transported across the cell membrane via a cation-folate symport mechanism.     

The calculation of sedimentation coefficients in vertical rotors

A program for the calculation of sedimentation coefficients of molecules centrifuged in sucrose in vertical rotors has been developed. The program has been tested with both protein and RNA of known sedimentation coefficients. The preparation can accept any shape of gradient in the 0–70% sucrose and any temperature in the range of 0–60°C. The program can be used with any vertical rotor for which the dimensions are known.     

l-Lactate Production from Biodiesel-Derived Crude Glycerol by Metabolically Engineered Enterococcus faecalis: Cytotoxic Evaluation of Biodiesel Waste and Development of a Glycerol-Inducible Gene Expression System

Biodiesel waste is a by-product of the biodiesel production process that contains a large amount of crude glycerol. To reuse the crude glycerol, a novel bioconversion process using Enterococcus faecalis was developed through physiological studies. The E. faecalis strain W11 could use biodiesel waste as a carbon source, although cell growth was significantly inhibited by the oil component in the biodiesel waste, which decreased the cellular NADH/NAD⁺ ratio and then induced oxidative stress to cells. When W11 was cultured with glycerol, the maximum culture density (optical density at 600 nm [OD₆₀₀]) under anaerobic conditions was decreased 8-fold by the oil component compared with that under aerobic conditions. Furthermore, W11 cultured with dihydroxyacetone (DHA) could show slight or no growth in the presence of the oil component with or without oxygen. These results indicated that the DHA kinase reaction in the glycerol metabolic pathway was sensitive to the oil component as an oxidant. The lactate dehydrogenase (Ldh) activity of W11 during anaerobic glycerol metabolism was 4.1-fold lower than that during aerobic glycerol metabolism, which was one of the causes of low l-lactate productivity. The E. faecalis pflB gene disruptant (Δpfl mutant) expressing the ldhL1_LP gene produced 300 mM l-lactate from glycerol/crude glycerol with a yield of >99% within 48 h and reached a maximum productivity of 18 mM h⁻¹ (1.6 g liter⁻¹ h⁻¹). Thus, our study demonstrates that metabolically engineered E. faecalis can convert crude glycerol to l-lactate at high conversion efficiency and provides critical information on the recycling process for biodiesel waste.     

In Vitro Sugar Transport in Zea mays L. Kernels : I. Characteristics of Sugar Absorption and Metabolism by Developing Maize Endosperm

Short-term transport studies were conducted using excised whole Zea mays kernels incubated in buffered solutions containing radiolabeled sugars. Following incubation, endosperms were removed and rates of net ¹⁴C-sugar uptake were determined. Endogenous sugar gradients of the kernel were estimated by measuring sugar concentrations in cell sap collected from the pedicel and endosperm. A sugar concentration gradient from the pedicel to the endosperm was found. Uptake rates of ¹⁴C-labeled glucose, fructose, and sucrose were linear over the concentration range of 2 to 200 millimolar. At sugar concentrations greater than 50 millimolar, hexose uptake exceeded sucrose uptake. Metabolic inhibitor studies using carbonylcyanide-m-chlorophenylhydrazone, sodium cyanide, and dinitrophenol and estimates of Q₁₀ suggest that the transport of sugars into the developing maize endosperm is a passive process. Sucrose was hydrolyzed to glucose and fructose during uptake and in the endosperm was either reconverted to sucrose or incorporated into insoluble matter. These data suggest that the conversion of sucrose to glucose and fructose may play a role in sugar absorption by endosperm. Our data do not indicate that sugars are absorbed actively. Sugar uptake by the endosperm may be regulated by the capacity for sugar utilization (i.e. starch synthesis).     

H-pumping driven by the vanadate-sensitive ATPase in membrane vesicles from corn roots

The initial rate of quenching of quinacrine fluorescence was used to monitor Mg:ATP-dependent H⁺-pumping in membrane vesicles from corn (Zea mays L. cv WF9 × MO17) roots and obtain a preparation in which vanadate-sensitive H⁺-pumping could be observed. Separation of membranes on a linear sucrose density gradient resulted in two distinct peaks of H⁺-pumping activity: a major one, at density 1.11 grams per cubic centimeter, was sensitive to NO₃⁻ and resistant to vanadate, while a minor one, at density 1.17 grams per cubic centimeter, was substantially resistant to NO₃⁻ and sensitive to vanadate. A membrane fraction enriched in the vanadate-sensitive H⁺-pump could be obtained by washing microsomes prepared in the presence of 10% glycerol with 0.25 molar KI. The kinetics of inhibition of H⁺-pumping by vanadate in this membrane preparation indicated that most of the H⁺-pumping activity in this fraction is sensitive to inhibition by vanadate, 50% inhibition being reached at about 60 micromolar vanadate. This value is fairly close to that observed for inhibition by vanadate of the ATPase activity in similar experimental conditions (40 micromolar). The inhibitor sensitivity, divalent cation dependence, pH optimum (6.5), and K_m for ATP (0.7 millimolar) of the H⁺-pumping activity match quite closely those reported for the plasma membrane ATPase of corn roots and other plant materials.     

In Vitro Growth of Curcuma longa L. in Response to Five Mineral Elements and Plant Density in Fed-Batch Culture Systems

Plant density was varied with P, Ca, Mg, and KNO₃ in a multifactor experiment to improve Curcuma longa L. micropropagation, biomass and microrhizome development in fed-batch liquid culture. The experiment had two paired D-optimal designs, testing sucrose fed-batch and nutrient sucrose fed-batch techniques. When sucrose became depleted, volume was restored to 5% m/v sucrose in 200 ml of modified liquid MS medium by adding sucrose solutions. Similarly, nutrient sucrose fed-batch was restored to set points with double concentration of treatments’ macronutrient and MS micronutrient solutions, along with sucrose solutions. Changes in the amounts of water and sucrose supplementations were driven by the interaction of P and KNO₃ concentrations. Increasing P from 1.25 to 6.25 mM increased both multiplication and biomass. The multiplication ratio was greatest in the nutrient sucrose fed-batch technique with the highest level of P, 6 buds/vessel, and the lowest level of Ca and KNO₃. The highest density (18 buds/vessel) produced the highest fresh biomass at the highest concentrations of KNO₃ and P with nutrient sucrose fed-batch, and moderate Ca and Mg concentrations. However, maximal rhizome dry biomass required highest P, sucrose fed-batch, and a moderate plant density. Different media formulations and fed-batch techniques were identified to maximize the propagation and storage organ responses. A single experimental design was used to optimize these dual purposes.     

Permeability of the human erythrocyte to glycerol in 1 and 2 m solutions at 0 or 20 °C

There are increasing numbers of exceptions to a central tenet in cryobiology that low-molecular-weight protective solutes such as glycerol must permeate cells in high concentration in order to protect them from freezing injury. To test this supposition, it is necessary to determine the amount of solute that has permeated a cell prior to freezing. The amount in human red cells was estimated from the flux equation $\text{ds}\text{dt}\text{= P}{}_{\mathrm{<mtext>\gamma </mtext>}}\text{A}$[(activity external solute) — (activity internal solute)]. Solving the equation required knowledge of P_γ the permeability constant for the solute. Estimates of P_γ for glycerol were made in two ways: (i) by measuring the time to 50% hemolysis of human red cells suspended in 1 or 2 m solutions of glycerol that were hypotonic with respect to NaCl, and (ii) by measuring the time required for red cells in 1 or 2 m solutions of glycerol in isotonic saline-buffer to undergo osmotic shock upon tenfold dilution with isotonic saline-buffer. The measurements were made at 0 and 20 °C. The values of P_γ were about 2.5 × 10^?4 cm/min at 20 °C and about 0.9 × 10^?4 cm/min at 0 °C. The difference corresponds to an activation energy of 7.2 kcal/mole. These values of P_γ are 100 to 600 times higher than those for glycerol permeation in the bovine erythrocyte. The values of P were relatively unaffected by whether calculations were based on classical or irreversible thermodynamics and by the choice of concentration units in the flux equations. Calculations of the kinetics of glycerol entry using these P values showed that the concentration of intracellular glycerol reaches 90% of equilibrium in 1.2 min at 0 °C and in 0.6 min at 20 °C. The osmolal ratio of intracellular glycerol to intracellular nonpermeating solutes reaches 90% of equilibrium in 7 min at 0 °C and in 3.2 min at 20 °C.     

Interaction of insecticides with human plasma lipoproteins

The binding of chlorinated hydrocarbon, carbamate and organophosphate insecticides to human low density plasma lipoproteins (LDL) and high density plasma lipoproteins (HDL) was studied at pH 7.0 and 16°C and 26°C by equilibrium dialysis, difference spectra and fluorescence. The results suggest interaction to be a partitioning rather than a stoichiometric binding process. Distribution is related to lipid content and composition of the lipoproteins. The K-values vary from 3 × 10⁵ M^?1 for 1,1,1-trichloro-2,2-bis(p-chlorophenyl)ethane (DDT) to less than 10 M^?1 for nicotine and aldicarb, and ΔG_tr° is in the range of 7400 cal for DDT to less than 1000 cal for aldicarb and nicotine. The K and ΔG_tr° are inversely related to the water solubility of the insecticides. A significant role of plasma lipoproteins in the transport of slightly water soluble insecticides is suggested.     

Sporulation in Hansenula wingei Is Induced by Nitrogen Starvation in Maltose-Containing Media

The sexually agglutinative yeast Hansenula wingei lives in association with bark beetles that inhabit coniferous trees. This yeast was induced to sporulate by malt extract, which contains a high percentage of maltose (50%) and a low percentage of nitrogen (0.5%). A solution of 1.5% maltose without any growth factors also induced ascosporogenesis in H. wingei. Thus, only a carbon source is required for sporulation as in Saccharomyces. However, potassium acetate did not induce sporulation in H. wingei as it does in S. cerevisiae. Instead, disaccharides (such as maltose, sucrose, or cellobiose) promote sporulation better than either monosaccharides (such as dextrose, fructose, or mannose) or respiratory substrates (such as ethanol or glycerol). The specificity of disaccharides in promoting sporulation in H. wingei may be considered an adaptation since these disaccharides are present in the natural environment of this yeast. In addition, the specificity of disaccharides may be related to the induction of the disaccharidase because cells precultured on dextrose sporulate well on maltose, but cells precultured on maltose sporulate poorly on maltose. When (NH₄)₂SO₄ was added at a low concentration (3 mM) to synthetic sporulation medium (1.5% maltose solution), sporulation was abolished, whereas other salts and nitrogen sources inhibited to a lesser extent and vitamins and trace elements had no effect. Oxygen was required for sporulation, as expected for an obligate aerobe. Maximal sporulation was achieved in 2% malt extract broth at high cell density (10⁹ cells per ml), pH 5, and 25°C. By using these optimal physiological conditions and hybrid strains selected from an extensive genetic breeding program, about 30% asci (10% tetrads) were obtained routinely. Thus, the genetics of cell recognition in this yeast can now be studied.     

The Influence of Sodium-Free Solutions on the Membrane Potential of Frog Muscle Fibers

The membrane potential of frog sartorius muscle fibers in a Cl- and Na-free Ringer's solution when sucrose replaces NaCl is about the same as that in normal Ringer's solution. The K⁺ efflux is also about the same in the two solutions but muscles lose K and PO₄ in sucrose Ringer's solutions. The membrane potential in sucrose Ringer's solution is equal to that given by the Nernst equation for a K⁺ electrode, when corrections are made for the activity coefficients for K⁺ inside and outside the fiber. For a muscle in normal Ringer's solution, the measured membrane potential is within a few millivolts of E_K. This finding is incompatible with a 1:1 coupled Na-K pump. It is consistent with either no coupling of Na efflux to K influx, or a coupling ratio of 3 or greater.     

Metabolic Fluxes in Corynebacterium glutamicum during Lysine Production with Sucrose as Carbon Source

Metabolic fluxes in the central metabolism were determined for lysine-producing Corynebacterium glutamicum ATCC 21526 with sucrose as a carbon source, providing an insight into molasses-based industrial production processes with this organism. For this purpose, ¹³C metabolic flux analysis with parallel studies on [1-¹³C^Fru]sucrose, [1-¹³C^Glc]sucrose, and [¹³C₆^Fru]sucrose was carried out. C. glutamicum directed 27.4% of sucrose toward extracellular lysine. The strain exhibited a relatively high flux of 55.7% (normalized to an uptake flux of hexose units of 100%) through the pentose phosphate pathway (PPP). The glucose monomer of sucrose was completely channeled into the PPP. After transient efflux, the fructose residue was mainly taken up by the fructose-specific phosphotransferase system (PTS) and entered glycolysis at the level of fructose-1,6-bisphosphate. Glucose-6-phosphate isomerase operated in the gluconeogenetic direction from fructose-6-phosphate to glucose-6-phosphate and supplied additional carbon (7.2%) from the fructose part of the substrate toward the PPP. This involved supply of fructose-6-phosphate from the fructose part of sucrose either by PTS^Man or by fructose-1,6-bisphosphatase. C. glutamicum further exhibited a high tricarboxylic acid (TCA) cycle flux of 78.2%. Isocitrate dehydrogenase therefore significantly contributed to the total NADPH supply of 190%. The demands for lysine (110%) and anabolism (32%) were lower than the supply, resulting in an apparent NADPH excess. The high TCA cycle flux and the significant secretion of dihydroxyacetone and glycerol display interesting targets to be approached by genetic engineers for optimization of the strain investigated.