Phosphorylation of glucose by a guanosine-5′-triphosphate (GTP)-dependent glucokinase in Fibrobacter succinogenes subsp. succinogenes S85

Cell extracts of Fibrobacter succinogenes subsp. succinogenes S85 phosphorylated glucose with a GTP-dependent glucokinase. The enzyme showed little activity with ATP (12% of that with GTP). Of other phosphate donors tested, only dGTP and ITP gave high glucokinase activities. Dialyzed extracts required Mg⁺² and K⁺ for maximal activity. In potassium phosphate buffer, glucokinase showed maximum activity at pH 7.5 with glucose-6-phosphate dehydrogenase as the coupling enzyme. In this assay, glucokinase was active with glucose (100%), 2-deoxy-d-glucose (40%), and mannose (20%). Partially purified glucokinase had a molecular weight of 82,000 and a pl of 4.82. Double-reciprocal plots of substrate concentration versus velocity were linear and the enzyme had apparent K_m values of 55 M for glucose and 72 M for GTP. Dialyzed cell extracts of Fibrobacter intestinalis C1A also contained a GTP-dependent glucokinase that showed little activity with ATP. Potassium also stimulated the activity of this enzyme. These results suggest that this unusual glucokinase may be characteristic of the genus Fibrobacter.Abbreviations CHES cyclohexylaminoethanesulfonic acid - GK glucokinase - PEP phosphoenolpyruvate Published with the approval of the Director of the North Dakota Agricultural Experiment Station as journal article no. 2186     

Studies on Glucose Isomerizing Enzyme of Bacteria

The activity ratio of glucose isomerization to glucose-6-phosphate isomerization was practically constant during the course of purification of the enzyme, and it was impossible to separate the two isomerizing activities by means of Sephadex G-150 and DEAE-Sephadex column chromatographies. Furthermore, the similarlity in pH stability and thermal stability, and the competitive inhibition by 6-phosphogluconate were observed in both isomerizing reactions. In kinetic experiments, however, Michaelis constants (Km) were calculated to be 1.6 m for the arsenate-requiring glucose isomerization, and 1.4 × 10^?3M for the glucose-6-phosphate isomerization. These results indicate that the arsenate-requiring glucose- and the arsenate-independent glucose-6-phosphate-isomerizing reactions are catalyzed by the same enzyme, and that the glucose-isomerizing enzyme is a glucose phosphate isomerase itself.     

Glucose Phosphorylation Is Required for Mycobacterium tuberculosis Persistence in Mice

Mycobacterium tuberculosis (Mtb) is thought to preferentially rely on fatty acid metabolism to both establish and maintain chronic infections. Its metabolic network, however, allows efficient co-catabolism of multiple carbon substrates. To gain insight into the importance of carbohydrate substrates for Mtb pathogenesis we evaluated the role of glucose phosphorylation, the first reaction in glycolysis. We discovered that Mtb expresses two functional glucokinases. Mtb required the polyphosphate glucokinase PPGK for normal growth on glucose, while its second glucokinase GLKA was dispensable. ¹³C-based metabolomic profiling revealed that both enzymes are capable of incorporating glucose into Mtb''s central carbon metabolism, with PPGK serving as dominant glucokinase in wild type (wt) Mtb. When both glucokinase genes, ppgK and glkA, were deleted from its genome, Mtb was unable to use external glucose as substrate for growth or metabolism. Characterization of the glucokinase mutants in mouse infections demonstrated that glucose phosphorylation is dispensable for establishing infection in mice. Surprisingly, however, the glucokinase double mutant failed to persist normally in lungs, which suggests that Mtb has access to glucose in vivo and relies on glucose phosphorylation to survive during chronic mouse infections.     

Glucose inhibits Ca efflux from pancreatic β-cells also in the absence of Na-Ca countertransport

During perifusion with medium deprived of Ca²⁺, addition of glucose or omission of Na⁺ resulted in prompt and quantitatively similar inhibitions of ⁴⁵Ca efflux from β-cell rich pancreatic islets microdissected from ob / ob mice. Glucose had no additional inhibitory effect when Na⁺ was isoosmotically replaced by sucrose or choline⁺. When K⁺ was used as a substitute for Na⁺, the inhibitory effect of Na⁺ removal on ⁴⁵Ca efflux became additive to that of glucose. The observation that glucose can be equally effective in inhibiting ⁴⁵Ca efflux in the presence or absence of Na⁺ is difficult to reconcile with the postulate that the Na⁺-Ca²⁺ countertransport mechanism is a primary site of action for glucose.     

Cooperative Anti-Diabetic Effects of Deoxynojirimycin-Polysaccharide by Inhibiting Glucose Absorption and Modulating Glucose Metabolism in Streptozotocin-Induced Diabetic Mice

We had previously shown that deoxynojirimycin-polysaccharide mixture (DPM) not only decreased blood glucose but also reversed the damage to pancreatic β-cells in diabetic mice, and that the anti-hyperglycemic efficacy of this combination was better than that of 1-deoxynojirimycin (DNJ) or polysachharide alone. However, the mechanisms behind these effects were not fully understood. The present study aimed to evaluate the therapeutic effects of DPM on streptozotocin (STZ)-induced diabetic symptoms and their potential mechanisms. Diabetic mice were treated with DPM (150 mg/kg body weight) for 90 days and continued to be fed without DPM for an additional 30 days. Strikingly, decrease of blood glucose levels was observed in all DPM treated diabetic mice, which persisted 30 days after cessation of DPM administration. Significant decrease of glycosylated hemoglobin and hepatic pyruvate concentrations, along with marked increase of serum insulin and hepatic glycogen levels were detected in DPM treated diabetic mice. Results of a labeled ¹³C₆-glucose uptake assay indicated that DPM can restrain glucose absorption. Additionally, DPM down-regulated the mRNA and protein expression of jejunal Na⁺/glucose cotransporter, Na⁺/K⁺-ATPase and glucose transporter 2, and enhanced the activities as well as mRNA and protein levels of hepatic glycolysis enzymes (glucokinase, phosphofructokinase, private kinase and pyruvate decarboxylas E1). Activity and expression of hepatic gluconeogenesis enzymes (phosphoenolpyruvate carboxykinase and glucose-6-phosphatase) were also found to be attenuated in diabetic mice treated with DPM. Purified enzyme activity assays verified that the increased activities of glucose glycolysis enzymes resulted not from their direct activation, but from the relative increase in protein expression. Importantly, our histopathological observations support the results of our biochemical analyses and validate the protective effects of DPM on STZ-induced damage to the pancreas. Thus, DPM has significant potential as a therapeutic agent against diabetes.     

ADP-dependent glucokinase from the hyperthermophilic sulfate-reducing archaeon<Emphasis Type="Italic"> Archaeoglobus fulgidus</Emphasis> strain 7324

The hyperthermophilic sulfate-reducing archaeon Archaeoglobus fulgidus strain 7324 has been shown to degrade starch via glucose using a modified Embden-Meyerhof pathway. The first enzyme of this pathway, ADP-dependent glucokinase, was purified 600-fold to homogeneity. The enzyme is a monomeric protein with an apparent molecular mass of 50 kDa. It had a temperature optimum at 83 °C and showed a significant thermostability up to 100 °C. The enzyme was highly specific for ADP and glucose as substrates; it did not use ATP, CDP, UDP, or GDP as phosphoryl donors, or mannose, fructose and fructose 6-phosphate as phosphoryl acceptors (at 80 °C). Only glucosamine was phosphorylated at significant rates. The apparent K_m values for ADP and glucose (at 50 °C) were 0.07 mM and 0.78 mM, respectively; the apparent V_max value was about 50 U/mg at 50 °C and 350 U/mg at 80 °C. Divalent cations were required for maximal activity; Mn²⁺, Mg²⁺ and Ca²⁺, which were most effective, could be replaced partially by Cu²⁺, Ni²⁺, Co²⁺ and Zn²⁺. The N-terminal amino acid sequence (42 amino acids) of ADP-dependent glucokinase was almost identical to that of ADP-dependent glucokinase from Thermococcus litoralis. In the genome of the closely related Archaeoglobus fulgidus strain VC16 a homologous gene for ADP-dependent glucokinase could not be identified.     

Glucose repression in Streptomyces coelicolor A3(2): a likely regulatory role for glucose kinase

The glucose kinase gene (glkA-ORF3) of Streptomyces coelicolor A3(2) plays an essential role in glucose utilisation and in glucose repression of a variety of genes involved in the utilisation of alternative carbon sources. These genes include dagA, which encodes an extracellular agarase that permits agar utilisation. Suppressor mutants of glkA-ORF3 deletion strains capable of utilising glucose (Glc⁺) arise at a frequency of about 10^–5 on prolonged incubation. The Glc⁺ phenotype of the mutants is reversible (at a frequency of about 10^–3) and reflects either the activation of a normally silent glucose kinase gene or the modification of an existing sugar kinase. Although the level of glucose kinase activity in the Glc⁺ supressor mutants is similar to that in the glkA ⁺ parental strain, glucose repression of dagA remains defective. Expression of the glucose kinase gene of Zymomonas mobilis in glkA-ORF3 mutants restored glucose utilisation, but not glucose repression of dagA. Over-expression of glkA-ORF3 on a high-copy-number plasmid failed to restore glucose repression of dagA in glkA-ORF3 mutants and led to loss of glucose repression of dagA in a glkA ⁺ strain. These results suggest that glucose phosphorylation itself is not sufficient for glucose repression and that glkA-ORF3 plays a specific regulatory role in triggering glucose repression in S. coelicolor A3(2).     

Expression of a novel gene, <Emphasis Type="Italic">gluP</Emphasis>, is essential for normal <Emphasis Type="Italic">Bacillus subtilis</Emphasis> cell division and contributes to glucose export

Background  

The Bacillus subtilis glucokinase operon was predicted to be comprised of the genes, yqgP (now named gluP), yqgQ, and glcK. We have previously established a role for glcK in glucose metabolism. In the absence of enzymes that phosphorylate glucose, such as GlcK and/or enzyme II^Glc, accumulated cytoplasmic glucose can be transported out of the cell. Genes within the glucokinase operon were not previously known to play a role in glucose transport. Here we describe the expression of gluP and its function in glucose transport.     

Glucose regulation of specific gene expression is altered in a glucokinase-deficient mutant of Tetrahymena

Summary Expression of the galactokinase gene in Tetrahymena thermophila can be repressed by glucose, glucose analogs, and epinephrine, each apparently acting through increased intracellular levels of adenosine 3′:5′-cyc lic monophosphate (cAMP) (1). To characterize further the initial steps in the control of galactokinase gene-expression by glucose, we have analyzed mutants which are defective in the metabolism of this sugar; these mutants were selected for their resistance to the glucose analog, 2-deoxyglucose (2). In one such mutant that is deficient in glucokinase, the synthesis of galactokinase is totally resistant to repression by glucose or its analogs, while repression by exogenous catecholamines or dibutyryl cAMP is unaffected. Radiochromatographic analyses of extracts of wild-type cells incubated with [¹⁴C]-deoxyglucose reveal intracellular conversio to several deoxyglucose metabolites, principally deoxyglucose-6-P and smaller amounts of deoxyglunose 1-P and 2-deoxygluconate; extracts of glucokinase-deficient cells prepared in a similar manner contain only trace amounts of deoxyglucose-6-P. The glucose analog 3-O-methylglucose, which is transported but not phosphorylated in wild-type cells, also cannot maintain repression of galactokinase. These results establish that the transport and subsequent phosphorylation of glucose are required for glucose-initiated repression of galactokinase gene expression, possibly acting by modulation of catecholamine or cyclic AMP levels. Additionally, we show unequivocally that: (a) cells containing derepressed levels of galactokinase are repressed upon the addition of glucose by inhibition of the synthesis of new enzyme and dilution of preformed enzyme concomitant with cell division, rather than through selective inactivation or degradation of galactokinase; and (b) glycerol kinase, glucokinase and fructokinase activities also are repressed by glucose in wild-type Tetrahymena, indicating that the glucose repression phenomenon is pleiotropic. Because the glucose repression of the synthesis of each of these enzymes is abolished in cells deficient in glucokinase, the regulatory mechanisms elucidated for repression of galactokinase synthesis are likely to be of wide significance.     

Purification, Immobilization, and Some Properties of Glucose Isomerase from Streptomyces flavogriseus

Glucose isomerase (EC 5.3.1.5) produced from Streptomyces flavogriseus was purified by fractionation with (NH₄)₂SO₄ and chromatography on diethylaminoethyl (DEAE)-cellulose and DEAE-Sephadex A-50 columns. The purified enzyme was homogeneous as shown by ultracentrifugation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Benzyl DEAE-cellulose, triethylaminoethyl-cellulose, and DEAE-cellulose were effective in the immobilization of partially purified glucose isomerase. Several differences in properties were found between purified soluble enzyme, immobilized enzyme (DEAE-cellulose-glucose isomerase), and heat-treated whole cells. Glucose and xylose served as substrate for the enzyme. Whole cells had the highest K_m values for glucose and xylose; the soluble enzyme had the lowest values. The optimum temperature for activity of the soluble and immobilized enzymes was 70°C; that for whole cells was 75°C. The pH optimum for the three enzyme preparations was 7.5. Magnesium ion or Co²⁺ was required for enzyme activity; an addition effect resulted from the presence of both Mg²⁺ and Co²⁺. The enzyme activity was inhibited by Hg²⁺, Ag⁺, or Cu²⁺. The conversion ratio of the enzyme for isomerization was about 50%. The soluble and immobilized enzymes showed a greater heat stability than whole cells. The soluble enzyme was stable over a slightly wider pH (5.0 to 9.0) range than the immobilized enzyme and whole cells (pH 5.5 to 9.0). The molecular weight of the enzyme determined by the sedimentation equilibrium method was 171,000. A tetrameric structure for the enzyme was also indicated. After operating at 70°C for 5 days, the remaining enzyme activity of the immobilized enzyme and whole cells, which were used for the continuous isomerization of glucose in a plug-flow type of column in the presence of Mg²⁺ and Co²⁺, was 75 and 55%, respectively. Elimination of Co²⁺ decreased operational stability.     

The Actual Ionic Nature of the Leak Current through the Na/Glucose Cotransporter SGLT1

Expression of the Na⁺/glucose cotransporter SGLT1 in Xenopus oocytes is characterized by a phlorizin-sensitive leak current (in the absence of glucose) that was originally called a “Na⁺ leak” and represents some 5-10% of the maximal Na⁺/glucose cotransport current. We analyzed the ionic nature of the leak current using a human SGLT1 mutant (C292A) displaying a threefold larger leak current while keeping a reversal potential (V_R) of ≈−15 mV as observed for wt SGLT1. V_R showed only a modest negative shift when extracellular Na⁺ concentration ([Na⁺]_o) was lowered and it was completely insensitive to changes in extracellular Cl⁻. When extracellular pH (pH_o) was decreased from 7.5 to 6.5 and 5.5, V_R shifted by +15 and +40 mV, respectively, indicating that protons may be the main charge carrier at low pH_o but other ions must be involved at pH_o 7.5. In the presence of 15 mM [Na⁺]_o (pH_o = 7.5), addition of 75 mM of either Na⁺, Li⁺, Cs⁺, or K⁺ generated similar increases in the leak current amplitude. This observation, which was confirmed with wt SGLT1, indicates a separate pathway for the leak current with respect to the cotransport current. This means that, contrary to previous beliefs, the leak current cannot be accounted for by the translocation of the Na-loaded and glucose-free cotransporter. Using chemical modification and different SGLT1 mutants, a relationship was found between the cationic leak current and the passive water permeability suggesting that water and cations may share a common pathway through the cotransporter.     

Characterization of Polyphosphate Glucokinase SCO5059 from Streptomyces coelicolor A3(2)

SCO5059, encoded in Streptomyces coelicolor A3(2), was identified as a polyphosphate glucokinase. The K _m values of SCO5059 for glucose and polyphosphate (poly(P)₆) were estimated to be 12 and 4 µM, respectively, and the k _cat value was 0.3 s^?1 at pH 7.7 at 28 °C. SCO5059 homologs are highly conserved among Streptomyces, and can work as polyphosphate glucokinase as well.     

Characterization of the Zymomonas mobilis glucose facilitator gene product (glf) in recombinant Escherichia coli: examination of transport mechanism, kinetics and the role of glucokinase in glucose transport

Zymomonas mobilis is known to transport glucose by a facilitated diffusion process. A putative glucose facilitator gene (glf), closely related to a large family of glucose transporters, is located in a cluster of genes that code for enzymes of glucose metabolism. The Z. mobilis glf gene is able to complement glucose transport in an Escherichia coli strain that is defective in native glucose transport and glucokinase. In this study, the recombinant E coli was shown to be capable of influx counterflow when preloaded with glucose and had an apparent K_m for glucose of approximately 1.1 - 2.9 mM, consistent with the function of Gif as a low-affinity glucose facilitator. The ability of glucokinase mutants expressing glf to transport glucose made it clear that glucokinase activity was not required for Glf-dependent glucose transport. The possibility that glucokinase can interact with Glf to improve the affinity for glucose was not supported since expression of the Z mobilis glucokinase gene, in addition to glf, did not affect the K_m of Glf for glucose in recombinant E. coli The inability of various sugars to compete with glucose during glucose transport by recombinant E. coli expressing glf indicated that Glf is specific for glucose. While the results of fructose transport assays did not completely rule out the possibility of very low affinity for fructose, the apparent specificity of Gif for glucose makes it possible that Z. mobilis utilizes a different transporter(s) for fructose.     

Changes in Sodium or Glucose Filtration Rate Modulate Expression of Glucose Transporters in Renal Proximal Tubular Cells of Rat

Renal glucose reabsorption is mediated by luminal sodium-glucose cotransporters (SGLTs) and basolateral facilitative glucose transporters (GLUTs). The modulators of these transporters are not known, and their substrates glucose and Na⁺ are potential candidates. In this study we examined the role of glucose and Na⁺ filtration rate on gene expression of glucose transporters in renal proximal tubule. SGLT1, SGLT2, GLUT1 and GLUT2 mRNAs were assessed by Northern blotting; and GLUT1 and GLUT2 proteins were assessed by Western blotting. Renal cortex and medulla samples from control rats (C), diabetic rats (D) with glycosuria, and insulin-resistant 15-month old rats (I) without glycosuria; and from normal (NS), low (LS), and high (HS) Na⁺-diet fed rats were studied. Compared to C and I rats, D rats increased (P < 0.05) gene expression of SGLT2 by ∼36%, SGLT1 by ∼20%, and GLUT2 by ∼100%, and reduced (P < 0.05) gene expression of GLUT1 by more than 50%. Compared to NS rats, HS rats increased (P < 0.05) SGLT2, GLUT2, and GLUT1 expression by ∼100%, with no change in SGLT1 mRNA expression, and LS rats increased (P < 0.05) GLUT1 gene expression by ∼150%, with no changes in other transporters. In summary, the results showed that changes in glucose or Na⁺ filtrated rate modulate the glucose transporters gene expression in epithelial cells of the renal proximal tubule. Received: 14 July 2000/Revised: 8 March 2001     

Glucose transport in isolated brush-border and lateral-basal plasma-membrane vesicles from intestinal epithelila cells

Free-flow electrophoresis was used to separate microvilli from the lateral basal plasma membrane of the epithelial cells from rat small intestine. The activities of the marker enzyme for the microvillus membrane, i.e. alkaline phosphatase (EC 3.1.31), was clearly separated from the marker for the lateral-basal plasma membrane, i.e. the (Na⁺, K⁺)-ATPase (EC 3.6.1.3). A microvillus membrane fraction was obtained with a high specific activity of alkaline phosphatase (an 8-fold enrichement over the starting homogenate). The lateral-basal plasma membrane fraction contained (Na⁺, K⁺)-ATPase (5-fold over homogenate) with some alkaline phosphatase (2-fold over homogenate).Glucose transport was studied in both membrane fractions. The uptake of d-glucose was much faster than that of l-glucose in either plasma membrane, d-Glucose uptake could be accounted for completely by its transport into an osmotically active space. Interestingly, the characteristics of the glucose transport of the microvillus membrane were different from those of the lateral-basal plasma membrane. In particular: Na⁺ stimulated the d-glucose transport by the microvillus membrane, but not by the lateral-basal plasma membrane. In addition, the glucose transport of the microvillus membrane was much more sensitive to phlorizin inhibition than that of the lateral-basal plasma membrane.These experiments thus provide evidence not only for an asymmetrical distribution of the enzymes, but also for differences in the transport properties with respect to glucose between the two types of plasma membrane of the intestinal epithelial cell.     

Presteady-State Currents of the Rabbit Na+/Glucose Cotransporter (SGLT1)

The rabbit Na⁺/glucose cotransporter (SGLT1) exhibits a presteady-state current after step changes in membrane voltage in the absence of sugar. These currents reflect voltage-dependent processes involved in cotransport, and provide insight on the partial reactions of the transport cycle. SGLT1 presteady-state currents were studied as a function of external Na⁺, membrane voltage V _m , phlorizin and temperature. Step changes in membrane voltage—from the holding V _h to test values, elicited transient currents that rose rapidly to a peak (at 3–4 msec), before decaying to the steady state, with time constants τ≈4–20 msec, and were blocked by phlorizin (K _i ≈30 μm). The total charge Q was equal for the application of the voltage pulse and the subsequent removal, and was a function of V _m . The Q-V curves obeyed the Boltzmann relation: the maximal charge Q _max was 4–120 nC; V _0.5, the voltage for 50% Q _max was −5 to +30 mV; and z, the apparent valence of the moveable charge, was 1. Q _max and z were independent of V _h (between 0 and −100 mV) and temperature (20–30°C), while increasing temperature shifted V _0.5 towards more negative values. Decreasing [Na⁺] _o decreased Q _max, and shifted V _0.5 to more negative voltages 9by −100 mV per 10-fold decrease in [Na⁺] _o ). The time constant τ was voltage dependent: the τ-V relations were bell-shaped, with maximal τ_max 8–20 msec. Decreasing [Na⁺] _o decreased τ_max, and shifted the τ-V curves towards more negative voltages. Increasing temperature also shifted the τ-V curves, but did not affect τ_max. The maximum temperature coefficient Q ₁₀ for τ was 3–4, and corresponds to an activation energy of 25 kcal/mole. Simulations of a 6-state ordered kinetic model for rabbit Na⁺/glucose cotransport indicate that charge-movements are due to Na⁺-binding/dissociation and a conformational change of the empty transporter. The model predicts that (i) transient currents rise to a peak before decay to steady-state; (ii) the τ-V relations are bell-shaped, and shift towards more negative voltages as [Na⁺] _o is reduced; (iii) τ_max is decreased with decreasing [Na⁺] _o ; and (iv) the Q-V relations are shifted towards negative voltages as [Na⁺] _o is reduced. In general, the kinetic properties of the presteady-state currents are qualitatively predicted by the model. Received: 12 August 1996/Revised: 30 September 1996     

Uncoupler-Resistant Glucose Uptake by the Thermophilic Glycolytic Anaerobe Thermoanaerobacter thermosulfuricus (Clostridium thermohydrosulfuricum)

The transport of glucose across the bacterial cell membrane of Thermoanaerobacter thermosulfuricus (Clostridium thermohydrosulfuricum) Rt8.B1 was governed by a permease which did not catalyze concomitant substrate transport and phosphorylation and thus was not a phosphoenolpyruvate-dependent phosphotransferase. Glucose uptake was carrier mediated, could not be driven by an artificial membrane potential (Δψ) in the presence or absence of sodium, and was not sensitive to inhibitors which dissipate the proton motive force (Δp; tetrachlorosalicylanilide, N,N-dicyclohexylcarboiimide, and 2,4-dinitrophenol), and no uptake of the nonmetabolizable analog 2-deoxyglucose could be demonstrated. The glucokinase apparent K_m for glucose (0.21 mM) was similar to the K_t (affinity constant) for glucose uptake (0.15 mM), suggesting that glucokinase controls the rate of glucose uptake. Inhibitors of ATP synthesis (iodoacetate and sodium fluoride) also inhibited glucose uptake, and this effect was due to a reduction in the level of ATP available to glucokinase for glucose phosphorylation. These results indicated that T. thermosulfuricus Rt8.B1 lacks a concentrative uptake system for glucose and that uptake is via facilitated diffusion, followed by ATP-dependent phosphorylation by glucokinase. In T. thermosulfuricus Rt8.B1, glucose is metabolized by the Embden-Meyerhof-Parnas pathway, which yields 2 mol of ATP (G. M. Cook, unpublished data). Since only 1 mol of ATP is used to transport 1 mol of glucose, the energetics of this system are therefore similar to those found in bacteria which possess a phosphotransferase.     

Photosynthetic performance in Sphagnum transplanted along a latitudinal nitrogen deposition gradient

Increased N deposition in Europe has affected mire ecosystems. However, knowledge on the physiological responses is poor. We measured photosynthetic responses to increasing N deposition in two peatmoss species (Sphagnum balticum and Sphagnum fuscum) from a 3-year, north–south transplant experiment in northern Europe, covering a latitudinal N deposition gradient ranging from 0.28 g N m⁻² year⁻¹ in the north, to 1.49 g N m⁻² year⁻¹ in the south. The maximum photosynthetic rate (NP_max) increased southwards, and was mainly explained by tissue N concentration, secondly by allocation of N to the photosynthesis, and to a lesser degree by modified photosystem II activity (variable fluorescence/maximum fluorescence yield). Although climatic factors may have contributed, these results were most likely attributable to an increase in N deposition southwards. For S. fuscum, photosynthetic rate continued to increase up to a deposition level of 1.49 g N m⁻² year⁻¹, but for S. balticum it seemed to level out at 1.14 g N m⁻² year⁻¹. The results for S. balticum suggested that transplants from different origin (with low or intermediate N deposition) respond differently to high N deposition. This indicates that Sphagnum species may be able to adapt or physiologically adjust to high N deposition. Our results also suggest that S. balticum might be more sensitive to N deposition than S. fuscum. Surprisingly, NP_max was not (S. balticum), or only weakly (S. fuscum) correlated with biomass production, indicating that production is to a great extent is governed by factors other than the photosynthetic capacity.     

Response surface optimization for the continuous glucose isomerization process

Production of fructose via a continuous glucose isomerization process was optimized using response surface methodology. Glucose isomerization was performed using immobilized glucose isomerase in a flow-through tubular reactor. Process factors eg pH (7.0–7.8), temperature (50–60°C), flow rate (5–17 ml min^–1) and glucose content (30–50% w/w) of the feedstock solution were simultaneously tested according to a central composite experimental design. Measured responses such as % isomerization, and fructose yield (gh^–1) has an excellent correlation with tested factors. The highest desirability,D, (geometric mean of % isomerization and fructose yield) was obtained when the feedstock (56–60°C) had 34–36% glucose, a pH of 7.4–7.8 and was pumped at 15 ml min^–1.     

Na+ requirement for glutamate-dependent sugar transport byFusobacterium nucleatum ATCC 10953

Resting cells ofFusobacterium nucleatum ATCC 10953, when provided with glutamic acid (Na⁺ salt) as fermentable energy source, rapidly accumulated [¹⁴C]glucose, from the medium. Sugar accumulation was not observed when Na⁺ glutamate was replaced by ammonium glutamate. However, addition of Na⁺ (chloride) to the latter system elicited uptake of [¹⁴C]glucose by the organism. Of other monovalent cations tested, only Li⁺ was found to be slightly stimulatory, but K⁺, Rb⁺, and Cs⁺ ions were ineffective. For determination of the role(s) of Na⁺ in sugar accumulation, the transport of [¹⁴C]glucose and [¹⁴C]glutamic acid by the cells was studied independently, with lysine as an alternate (and Na⁺-independent) energy source. In the presence of lysine, cells ofF. nucleatum 10953 accumulated [¹⁴C]glucose from a Na⁺-free medium, but, in contrast, uptake and fermentation of [¹⁴C]glutamic acid was Na⁺-dependent. The glucose transport system is Na⁺-independent. However, our data indicate dual role(s) for Na⁺ in the transport and intracellular metabolism of glutamic acid. The Na⁺-dependent glutamate fermentation pathway provides the necessary energy for active transport of glucose by the resting cell.