Brain hexokinase has no preexisting allosteric site for glucose 6-phosphate

Difference spectroscopic investigations on the interaction of brain hexokinase with glucose and glucose 6-phosphate (Glc-6-P) show that the binary complexes E-glucose and E-Glc-6-P give very similar UV difference spectra. However, the spectrum of the ternary E-glucose-Glc-6-P complex differs markedly from the spectra of the binary complexes, but resembles that produced by the E-glucose-Pi complex. Direct binding studies of the interaction of Glc-6-P with brain hexokinase detect only a single high-affinity binding site for Glc-6-P (KD = 2.8 microM). In the ternary E-glucose-Glc-6-P complex, Glc-6-P has a much higher affinity for the enzyme (KD = 0.9 microM) and a single binding site. Ribose 5-phosphate displaces Glc-6-P from E-glucose-Glc-6-P only, but not from E-Glc-6-P complex. It also fails to displace glucose from E-glucose and E-glucose-Glc-6-P complexes. Scatchard plots of the binding of glucose to brain hexokinase reveal only a single binding site but show distinct evidence of positive cooperativity, which is abolished by Glc-6-P and Pi. These ligands, as well as ribose 5-phosphate, substantially increase the binding affinity of glucose for the enzyme. The spectral evidence, as well as the interactive nature of the sites binding glucose and phosphate-bearing ligands, lead us to conclude that an allosteric site for Glc-6-P of physiological relevance occurs on the enzyme only in the presence of glucose, as a common locus where Glc-6-P, Pi, and ribose 5-phosphate bind. In the absence of glucose, Glc-6-P binds to the enzyme at its active site with high affinity. We also discuss the possibility that, in the absence of glucose, Glc-6-P may still bind to the allosteric site, but with very low affinity, as has been observed in studies on the reverse hexokinase reaction.     

Regulation of mammalian hexokinase: regulatory differences between isoenzyme I and II

Mammalian hexokinase isoenzymes I and II have been shown to differ qualitatively in response to various modifiers. Although both enzymes are inhibited by glucose 6-phosphate, only isoenzyme II exhibits a slow response to the presence of this inhibitor. P_i decreases the affinity of glucose 6-phosphate for Sarcoma 37 hexokinase I, but has no effect on hexokinase II from the same cell. P_i overcomes all of the inhibition of red cell hexokinase by glucose-6-P and hence the two effectors act competitively. At pH 6.5, catecholamines increase the V of isoenzyme I of Sarcoma 37 and brain in the soluble and mitochondrial forms but do not activate these forms of tumor isoenzyme II. Citrate activates brain and tumor isoenzyme I when they are inhibited by tris(hydroxy-methyl)aminomethylethane sulfonate (TES) and ADP; however, tumor isoenzyme II is not activated.     

Effect of neutral salts on the interaction of rat brain hexokinase with the outer mitochondrial membrane.

The glucose 6-phosphate (Glc-6-P)-induced solubilization of mitochondrial hexokinase (ATP:d-hexose 6-phosphotransferase, EC 2.7.1.1) from rat brain can be reversed by low concentrations (ionic strength <~0.02 m) of neutral salts. When compared to the original particulate enzyme (i.e., enzyme found on the particles prior to solubilization by Glc-6-P), the rebound enzyme is similar in distribution on sucrose gradients, K_m for ATP, inhibition by antiserum to purified brain hexokinase, and resistance to removal by exhaustive washing of the particles. The effectiveness of chloride salts at promoting rebinding increases in the order Cs⁺< Rb⁺< K⁺≤ Na⁺< Li⁺< Mg²⁺. This salt-induced rebinding is attributed to the screening of negative charges on the enzyme and/or membrane by cations, thereby decreasing repulsive forces and enhancing attractive interactions between enzyme and membrane. Solubilization of the enzyme, both in the presence and absence of Glc-6-P, is increased at alkaline pH, as would be expected due to increasing repulsive interactions between negative charges on membrane and enzyme as the pH is increased beyond the pI of the enzyme (pI = 6.3). In contrast to previous interpretations, P_i displayed no special efficacy at reversing Glc-6-P-induced solubilization, being comparable to other neutral salts on an ionic strength basis. However, P_i and its structural analog, arsenate, were shown to counteract specifically the Glc-6-P-induced inhibition and conformational change in the enzyme. At higher concentrations (ionic strength >~ 0.02 m) neutral salts themselves lead to reversible dissociation of the enzyme from the mitochondria. The efficacy of the salts depends primarily on the pH and on the position of the anion in the Hofmeister series, with salts of chaotropic anions (SCN^?, I^?, Br^?) being most effective. At pH 6, both chaotropic and nonchaotropic salts solubilize the enzyme, while at pH 8.5, only the chaotropes retain this ability. Neutral salts also have a reversible effect on the conformation of the enzyme, as reflected by enzymatic activity, with chaotropic salts again being most effective; there is no pronounced influence of pH (in the range of pH 6–8.5) on the ability of the salts to cause conformational change in the enzyme. Based on a lack of correlation between saltinduced solubilization and conformational changes affecting activity, it is concluded that the latter are not directly responsible for release of the enzyme from the membrane. In the presence of KSCN, the extent of solubilization decreased with increase in temperature, indicating a negative enthalpy for solubilization. In contrast, in the absence of salt, the enthalpy for solubilization was positive. These temperature effects and the effects of neutral salts on the hexokinase-membrane interaction are interpreted in terms of a model in which electrostatic forces are considered to be of major importance. At low ionic strength, repulsive forces between negative charges on enzyme and membrane predominate; screening of these charges by cations diminishes the repulsion, effectively enhancing attractive electrostatic forces between enzyme and membrane and thus promoting their interaction. At higher ionic strengths, the attractive electrostatic forces are themselves disrupted, resulting in dissociation of the enzyme from the membrane. It is proposed that the greater effectiveness of chaotropic salts at disrupting these attractive forces is due to their increased ability to penetrate through hydrophobic regions of enzyme and membrane to relatively inaccessible sites of electrostatic-interaction.     

Complementarity in the regulation of phosphoglucomutase, phosphofructokinase and hexokinase; the role of glucose 1,6-bisphosphate.

ATP and citrate, the well known inhibitors of phosphofructokinase (ATP: D-fructose 6-phosphate 1-phosphotransferase, EC 2.7.1.11), were found to inhibit the activities of the multiple forms of phosphoglucomutase (alpha-D-glucose 1,6-bisphosphate: alpha-D-glucose 1-phosphate phosphotransferase, EC 2.7.5.1) from rat muscle and adipose tissue. This inhibition could be reversed by an increase in the glucose 1,6-bisphosphate (Glc-1,6-P2) concentration. Other known activators (deinhibitors) of phosphofructokinase, viz. cyclic AMP, AMP, ADP or Pi, had no direct deinhibitory action on the ATP or citrate inhibited multiple phosphoglucomutases. Cyclic AMP and AMP, could however lead indirectly to deinhibition of the phosphoglucomutases, by activating phosphofructokinase which catalyzes the ATP-dependent phosphorylation of glucose 1-phosphate to form Glc-1,6-P2, the la-ter then released the multiple phosphoglucomutases from ATP or citrate inhibition. The Glc-1,6-P2 was also found to exert a selective inhibitory effect on hexokinase (ATP: D-hexose 6-phosphotransferase, EC 2.7.1.1) type II, the predominant form in skeletal muscle. This selective inhibition by Glc-1,6-P2 was demonstrated on the multiple hexokinases which were resolved by cellogel electrophoresis or isolated by chromatography on DEAE-cellulose. Based on the in vitro studies it is suggested that during periods of highly active epinephrine-induced glycogenolysis in muscle, the Glc-1,6-P2, produced by the cyclic AMP-stimulated reaction of phosphofructokinase with glucose 1-phosphate, will release the phosphoglucomutases from ATP or citrate inhibition, and will depress the activity of muscle type II hexokinase.     

Hexokinase II of Pea Seeds

A second hexokinase (EC 2.7.1.1) was obtained from pea seed (Pisum sativum L. var. Progress No. 9) extracts. The enzyme, termed hexokinase II, had a high affinity (K_m, 48 micromolar) for glucose and a relatively low affinity (K_m, 10 millimolar) for fructose. The K_m for MgATP was 86 micromolar. Mg²⁺ was required for activity, but excess Mg²⁺ was inhibitory. MgADP inhibited hexokinase II. The addition of salts of monovalent cations increased hexokinase II activity. Al³⁺ was a strong inhibitor of the enzyme at pH 6.6 but not at the optimum pH (8.2). Citrate and 3-phosphoglycerate activated pea seed hexokinase II at pH 6.6, probably by coordinating with aluminum present as a contaminant in commercial ATP. The properties of hexokinase II are compared with those of the other three hexose kinases obtained from pea seed extracts. The possible role of these enzymes in plant carbohydrate metabolism is discussed.     

Separation and characteristics of galactose-1-phosphate and glucose-1-phosphate uridyltransferase from fruit peduncles of cucumber

Galactose-1-phosphate uridyltransferase (EC 2.7.7.10), responsible for the conversion of galactose-1-phosphate (Gal-1-P) to uridine diphosphate galactose (UDPgal) was examined in fruit peduncles of Cucumis sativus L. Two uridyltransferases (pyrophosphorylases), from I and II, were partially purified and resolved on a diethylamino-ethyl-cellulose column. Form I can utilize glucose-1-phosphate (Glc-1-P), while form II can utilize either Gal-1-P or Glc-1-P, with a preference for Gal-1-P. Form I was more heat stable than form II. Both Glc-1-P and Gal-1-P activities of form II were inactivated at the same rate by heating. The finding of a uridyltransferase with preference for Gal-1-P indicates that cucumber may have a Gal-1-P uridyltransferase (pyrophosphorylase) pathway for the catabolism of stachyose in the peduncles. The absence of the enzyme UDP-glucose-hexose-1-phosphate uridyltransferase (EC 2.7.7.12) in this tissue rules out catabolism by the classical Leloir pathway. The incorporation of carbon from UDPglc into Glc-1-P as opposed to sucrose may be regulated by the activities of the uridyltransferases. Pyrophosphate, in the same concentration range, inhibits UDP-gal formation (K_i=0.58±0.10 mM) and stimulates Glc-1-P formation. The ratio of units of pyrophosphatase to units of Gal-1-P uridyltransferase was higher in peduncles from growing fruit than from unpollinated fruit. Modulation of carbon partitioning through a uridyltransferase pathway may be a factor controlling growth of the cucumber fruit.Abbreviations Gal-1-P Galactose-1-phosphate - Glc-1-P glucose-1-phosphate - UDPgal uridine diphosphate galactose - UDPglc uridine diphosphate glucose Paper No. 6908 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh. The use of trade names in this publication does not imply endorsement by the North Carolina Agricultural Research Service of products named, nor criticism of similar ones not mentioned     

Functional characteristics of hexokinase bound to the type a and type B sites of bovine brain mitochondria.

Hexokinase is released from Type A sites of brain mitochondria in the presence of glucose 6-phosphate (Glc-6-P); enzyme bound to Type B sites remains bound. Hexokinase of freshly isolated bovine brain mitochondria (Type A:Type B, approximately 40:60) selectively uses intramitochondrial ATP as substrate and is relatively insensitive to the competitive (vs ATP) inhibitor and Glc-6-P analog, 1,5-anhydroglucitol 6-phosphate (1,5-AnG-6-P). After removal of hexokinase bound at Type A sites, the remaining enzyme, bound at Type B sites, does not show selectivity for intramitochondrial ATP and has increased sensitivity to 1,5-AnG-6-P. Thus, the properties of the enzyme bound at Type B sites are modified by removal of hexokinase bound at Type A sites. It is suggested that mechanisms for regulation of mitochondrial hexokinase activity, and thereby cerebral glycolytic metabolism, may depend on the ratio of Type A:Type B sites, which varies in different species.     

Action of 5-thio-D-glucose and its 1-phosphate with hexokinase and phosphoglucomutase.

Previous work from this laboratory has shown that 5-thio-d-glucose is a competitive inhibitor for active transport of d-glucose. The present work indicates that the thiosugar analog and its 1-phosphate can also interfere with d-glucose 6-P formation.5-Thio-d-glucose serves as a substrate for yeast hexokinase with a K_m of 4 mm, and V of 8.8 nmol/min/μg of protein. The analog competitively inhibits d-glucose phosphorylation with a K_i of 20 mm.5-Thio-d-glucose 1-P can act as a substrate for rabbit skeletal muscle phosphoglucomutase with a K_m of 60 μm and V of 0.17 μmol/min/μg of protein. Thus, 5-thio-d-glucose 1-P behaves as a near metabolic analog of d-glucose 1-P. 5-Thio-d-glucose 1-P is a competitive inhibitor of d-glucose 1-P conversion to the 6-P with a K_i of 16.2 μm.5-Thio-d-glucose 6-P produced by phosphorylation of 5-thio-d-glucose and by conversion from 5-thio-d-glucose 1-P was identified by chromatographic mobility and by color reactions.     

Regulation of glucose metabolism in rat lung: Subcellular distribution,isozyme pattern,and kinetic properties of hexokinase

The subcellular distribution and isozyme pattern of hexokinase in rat lung were studied. Of the total hexokinase activity of lung, one-third was bound to mitochondria and one-third of the mitochondrial activity was in a latent form. The overt-bound mitochondrial hexokinase was specifically solubilized by physiological concentrations of glucose 6-phosphate and ATP. Inorganic phosphate partially prevented the solubilization by glucose 6-phosphate (Glc 6-P), whereas Mg²⁺ ions promoted rebinding of the solubilized enzyme to mitochondria. Thus, the distribution of hexokinase between soluble and particulate forms in vivo is expected to be controlled by the relative concentrations of Glc 6-P, ATP, P_i, and Mg²⁺. Study of the isozyme pattern showed that hexokinase types I, II, and III constitute the cell-sap enzyme of lung. The overt and latent hexokinase activities could be separately isolated by successive treatments of mitochondria with Glc 6-P and Triton X-100. The overt-bound activity consisted primarily of hexokinase type I, with a small proportion of type II isozyme. The latent activity, on the other hand, exclusively consisted of type I isozyme. Type I hexokinase, the predominant isozyme in lung, was strongly inhibited by intracellular concentration of Glc 6-P and this inhibition was counteracted by P_i. The bound form of hexokinase exhibited a significantly higher apparent K_i for Glc 6-P inhibition and a lower apparent K_m for ATP as compared to the soluble form. Thus, the particulate form of hexokinase is expected to promote glycolysis and may provide a mechanism for the high rate of aerobic glycolysis in lung.     

Cerebral-cortex hexokinase. Comparison of properties of solubilized mitochondrial and cytoplasmic activities

1. Cerebral-cortex mitochondria, after purification by using high-density sucrose solutions, were extracted with Triton X-100. The total hexokinase activity of the intact mitochondria was increased by 50–80% in the Triton extracts. 2. Triton X-100 was removed from mitochondrial extracts by a combination of ammonium sulphate fractionation and DEAE-cellulose chromatography. Mitochondrial hexokinase remained soluble after removal of extractant. 3. The behaviour of solubilized mitochondrial hexokinase was compared with soluble cytoplasmic hexokinase from the same samples of cerebral cortex on identical columns of DEAE-cellulose. Two peaks were eluted from each source of hexokinase. The distribution between hexokinase peaks was similar for the two sources. Peak I (approx. 80% of the total hexokinase) from each was eluted at identical concentrations of potassium chloride and slight differences were observed in the elution profiles for peak II. 4. The purified mitochondrial hexokinase showed the following kinetic properties: peak I, K_m(ATP) 0.60mm, K_m(glucose) 0.042mm; peak II, K_m(ATP) 0.66mm, K_m(glucose) 0.043mm. The purified cytoplasmic hexokinase Michaelis constants were: peak I, K_m(ATP) 0.56mm, K_m(glucose) 0.048mm; peak II, K_m(ATP) 0.68mm, K_m(glucose) 0.062mm. 5. Although no significant differences between mitochondrial and cytoplasmic hexokinases were noted in chromatographic behaviour or in the kinetic properties studied, the purified mitochondrial enzyme was activated slightly (approx. 20%) by Triton X-100, in contrast with the cytoplasmic enzyme, which was not affected. 6. The results, taken to indicate basic similarity between mitochondrial and cytoplasmic hexokinases, are discussed in relation to the role of the two sources of enzyme in the metabolism of the tissue.     

Substrate kinetics and substrate effects on the quaternary structure of barley UDP-glucose pyrophosphorylase

UDP-Glc pyrophosphorylase (UGPase) is an essential enzyme responsible for production of UDP-Glc, which is used in hundreds of glycosylation reactions involving addition of Glc to a variety of compounds. In this study, barley UGPase was characterized with respect to effects of its substrates on activity and quaternary structure of the protein. Its K_m values with Glc-1-P and UTP were 0.33 and 0.25 mM, respectively. Besides using Glc-1-P as a substrate, the enzyme had also considerable activity with Gal-1-P; however, the K_m for Gal-1-P was very high (>10 mM), rendering this reaction unlikely under physiological conditions. UGPase had a relatively broad pH optimum of 6.5–8.5, regardless of the direction of reaction. The enzyme equilibrium constant was 0.4, suggesting slight preference for the Glc-1-P synthesis direction of the reaction. The quaternary structure of the enzyme, studied by Gas-phase Electrophoretic Mobility Macromolecule Analysis (GEMMA), was affected by addition of either single or both substrates in either direction of the reaction, resulting in a shift from UGPase dimers toward monomers, the active form of the enzyme. The substrate-induced changes in quaternary structure of the enzyme may have a regulatory role to assure maximal activity. Kinetics and factors affecting the oligomerization status of UGPase are discussed.     

Studies on substrate specificity and activity regulating factors of trehalose-6-phosphate synthase of Saccharomyces cerevisiae

Purified trehalose-6-phosphate synthase (TPS) of Saccharomyces cerevisiae was effective over a wide range of substrates, although differing with regard to their relative activity. Polyanions heparin and chondroitin sulfate were seen to stimulate TPS activity, particularly when a pyrimidine glucose nucleotide like UDPG was used, rather than a purine glucose nucleotide like GDPG. A high V_max and a low K_m value of UDPG show its greater affinity with TPS than GDPG or TDPG. Among the glucosyl acceptors TPS showed maximum activity with G-6-P which was followed by M-6-P and F-6-P. Effect of heparin was also extended to the purification of TPS activity, as it helped to retain both stability and activity of the final purified enzyme. Metal co-factors, specifically MnCl₂ and ZnCl₂ acted as stimulators, while enzyme inhibitors had very little effect on TPS activity. Metal chelators like CDTA, EGTA stimulated enzyme activity by chelation of metal inhibitors. Temperature and pH optima of the purified enzyme were determined to be 40 °C and pH 8.5 respectively. Enzyme activity was stable at 0–40 °C and at alkaline pH.     

Regulation of the tyrosine oxidizing system in fetal rat liver

The formation of glucose 6-arsenate and glucose 6-phosphate shows similar thermodynamic constants: both reactions are endothermic, endergonic, and occur with a decrease of entropy. However, the kinetic coefficients of the spontaneous formation of the arsenate esters are ca. 10⁵ times greater than those of their homologous phosphate esters. The activation energy of the spontaneous formation of glucose 6-arsenate (E = + 12 kcal mol^?1) is even smaller than that of the formation of glucose 6-phosphate by alkaline phosphate (E = + 13 kcal mol^?1). Similar to the case of the monoalkylphosphates, the monoanion species of glucose 6-arsenate is much more reactive than the dianion species. This is an important difference with respect to glucose 6-phosphate. The calculated half-lives at 25 °C and pH 7.0 of glucose 6-arsenate and 6-arsenogluconate are only ca. 6 and 30 min, respectively; they increase at lower temperatures and alkaline pH. At 0 °C and pH 9.0 the half-life of glucose 6-arsenate is ca. 20 h. Therefore, arsenate esters could probably be isolated for use as a tool in biochemical studies. Arsenate esters are good analogs of the phosphate esters for a variety of enzymes. Glucose-6-phosphate dehydrogenase shows nearly similar values of K_m and V for either glucose 6-phosphate or glucose 6-arsenate, and hexokinase is similarly inhibited by both compounds. 6-Phosphogluconate dehydrogenase has the same V with respect to 6-phosphogluconate and 6-arsenogluconate although the enzyme shows a much lower affinity for the latter substrate.     

Proton relay system in the active site of maltodextrinphosphorylase via hydrogen bonds with large proton polarizability: an FT-IR difference spectroscopy study

Maltodextrinphosphorylase (MDP) was studied in the pH range 5.4–8.4 by Fourier transform infrared (FT-IR) spectroscopy. The pK _a value of the cofactor pyridoxalphosphate (PLP) was found between 6.5 and 7.0, which closely resembles the second pK _a of free PLP. FT-IR difference spectra of the binary complex of MDP+α-d-glucose-1-methylenephosphonate (Glc-1-MeP) minus native MDP were taken at pH 6.9. Following binary complex formation, two Lys residues, tentatively assigned to the active site residues Lys533 and Lys539, became deprotonated, and PLP as well as a carboxyl group, most likely of Glu637, protonated. A system of hydrogen bonds which shows large proton polarizability due to collective proton tunneling was observed connecting Lys533, PLP, and Glc-1-MeP. A comparison with model systems shows, furthermore, that this hydrogen bonded chain is highly sensitive to local electrical fields and specific interactions, respectively. In the binary complex the proton limiting structure with by far the highest probability is the one in which Glc-1-MeP is singly protonated. In a second hydrogen bonded chain the proton of Lys539 is shifted to Glu637. In the binary complex the proton remains located at Glu637. In the ternary complex composed of phosphorylase, glucose-1-phosphate (Glc-1-P), and the nonreducing end of a polysaccharide chain (primer), a second proton may be shifted to the phosphate group of Glc-1-P. In the doubly protonated phosphate group the loss of mesomeric stabilization of the phosphate ester makes the C₁–O₁ bond of Glc-1-P susceptible to bond cleavage. The arising glucosyl carbonium ion will be a substrate for nucleophilic attack by the nonreducing terminal glucose residue of the polysaccharide chain. Received: 15 June 1997 / Revised version: 15 October 1998 / Accepted: 15 October 1998     

Kinetic characterization of phosphoenolpyruvate carboxylase extracted from whole-leaf and from guard-cell protoplasts of Vicia faba L. (C3 plant) with respect to tissue pre-illumination

Summary Whole leaves and guard-cell protoplasts of the C₃ plant Vicia faba L. (broad bean) were separately extracted following a period of illumination or following a period of darkness. Kinetic parameters of phosphoenolpyruvate carboxylase (PEPC, EC 4.1.1.31), V_max and K_{m (PEP · Mg)}, were determined as a function of assay pH (7.0 or 8.1), the presence of 5 mm glucose-6-P_free (Glc-6-P, an activator), and the presence of 5 mm malate_free (an inhibitor). On the basis of these parameters, guard-cell PEPC was distinguished from that of whole leaf, indicating either that guard cells contain a unique isoenzyme of PEPC or a different complement of isoenzymes or - and less likely - that the obligatorily different methodologies for the leaf (intact organ) and the guard-cell (protoplast) enzymes altered them specifically.The values of V_max were relatively unchanged, regardless of assay conditions or tissue pretreatment. The values obtained for whole-leaf PEPC V_max were restricted to a small range (52.4 ± 5.9 (SD) to 64.4 ± 4.8 (SD) mol · g fresh mass^-1 · h^-1; the high value coincided with the presence of Glc-6-P, and the low value was obtained in the presence of malate. Guard-cell PEPC V_max was also restricted to a small range: 7.48 ± 0.89 (SD) pmol · guard-cell pair^-1 · h^-1 (pH 8.1, light, +Glc-6-P) to 5.79 ± 0.60 (SD) pmol · guard-cell pair^-1 · h^-1 (pH 7.0, dark, +malate). Depending on effectors, and particularly pH, large changes in K_{m (PEP · Mg}) were calculated (whole-leaf PEPC: 0.03 to 3.84 mm; guard-cell PEPC: 0.06 to 3.43 mm). For both extracts, the low values were obtained at pH 8.1, +Glc-6-P, and the high values at pH 7.0, +malate. Although the ranges of K_m values were broadly similar, the PEPCs reacted differently to individual changes in assay components. In very general terms, whole-leaf PEPC was relatively more efficient at pH 8.1, whereas at pH 7.0, the enzymes behaved more similarly.An effect of in vivo pre-illumination on guard-cell PEPC was not detected. A leaf pre-illumination effect on whole-leaf PEPC was highly statistically significant when assayed under control conditions at pH 7.0. The effect was small - typically a 26% decrease in K_{m (PEP · Mg}) this typical decrease was less than the range of values in replicate experiments. Such a small pre-illumination effect (even if real) could, therefore, easily go undetected. Whether such a small change could have physiological relevance is an open question. Neither with the whole-leaf PEPC nor with the guard-cell PEPC was the IC₅₀ (malate) or A_0.5 (Glc-6-P) determined for any condition. These kinetic parameters are a focus of present work.     

Metabolism of glucose by unicellular blue-green algae

Summary A facultative photo- and chemoheterotroph, the unicellular bluegreen alga Aphanocapsa 6714, dissimilates glucose with formation of CO₂ as the only major product. A substantial fraction of the glucose consumed is assimilated and stored as polyglucose (probably glycogen). The oxidation of glucose proceeds through the pentose phosphate pathway. The first enzyme of this pathway, glucose-6-phosphate dehydrogenase, is partly inducible. In addition, the rate of glucose oxidation is controlled, at the level of glucose-6-phosphate dehydrogenase function, by the intracellular level of an intermediate of the Calvin cycle, ribulose-1,5-diphosphate, which is a specific allosteric inhibitor of this enzyme. As a consequence, the rate of glucose oxidation is greatly reduced by illumination, an effect reversed by the presence of DCMU, an inhibitor of photosystem II.Two obligate photoautotrophs, Synechococcus 6301 and Aphanocapsa 6308, produce CO₂ from glucose at extremely low rates, although their levels of pentose pathway enzymes and of hexokinase are similar to those in Aphanocapsa 6714. Failure to grow with glucose appears to reflect the absence of an effective glucose permease. A general hypothesis concerning the primary pathways of carbon metabolism in blue-green algae is presented.Abbreviations A (U)DPG ADP-glucose or UDP-glucose - G-1-P glucose-1-phosphate - G-6-P glucose-6-phosphate - G_(int.) intracellular glucose - F-6-P fructose-6-phosphate - 6-PG 6-phosphogluconate - Ru-5-P ribulose-5-phosphate - RUDP ribulose-1,5-diphosphate - PGA 3-phosphoglycerate - GAP glyceraldehyde-3-phosphate     

Subcellular localization of hexose kinases in pea stems: mitochondrial hexokinase

The subcellular localization of hexose phosphorylating activity in extracts of pea stems has been studied by differential centrifugation and sucrose density gradient centrifugation. The hexokinase (EC 2.7.1.1) was associated with the mitochondria, whereas fructokinase (EC 2.7.1.4) was in the cytosolic fraction. Some properties of the mitochondrial hexokinase were studied. The enzyme had a high affinity for glucose (K_m 76 micromolar) and mannose (K_m 71 micromolar) and a relatively low affinity for fructose (K_m 15.7 millimolar). The K_m for MgATP was 180 micromolar. The addition of salts stimulated the activity of the hexokinase. Al³⁺ was a strong inhibitor at pH 7 but not at the optimum pH (8.2). The enzyme was not readily solubilized but, in experiments with intact mitochondria, was susceptible to proteolysis. A location on the outer mitochondrial membrane is suggested for the hexokinase of pea stems.     

Characterization of mannitol metabolism in the mangrove red algaCaloglossa leprieurii (Montagne) J.Agardh

A metabolic pathway, known as the mannitol cycle in fungi, has been identified as a new entity in the eulittoral mangrove red algaCaloglossa leprieurii (Montagne) J. Agardh. Three specific enzymes, mannitol-1-phosphate dehydrogenase (Mt1PDH; EC 1.1.1.17), mannitol-1-phosphatase (MtlPase; EC 3.1.3.22), mannitol dehydrogenase (MtDH; EC 1.1.1.67) and one nonspecific hexokinase (HK; EC 2.7.1.1) were determined and biochemically characterized in cell-free extracts. Mannitol-1-phosphate dehydrogenase showed activity maxima at pH 7.0 [fructose-6-phosphate (F6P) reduction] and pH 8.5 [oxidation of mannitol-1-phosphate (Mt1P)], and a very high specificity for both carbohydrate substrates. TheK _m values were 1.4 mM for F6P, 0.09 mM for MOP, 0.020 mM for NADH and 0.023 mM for NAD⁺. For the dephosphorylation of MOP, MtlPase exhibited a pH optimum at 7.2, aK _m value of 1.2 mM and a high requirement of Mg²⁺ for activation. Mannitol dehydrogenase had activity maxima at pH 7.0 (fructose reduction) and pH 9.8 (mannitol oxidation), and was less substrate-specific than Mt1PDH and MtlPase, i.e. it also catalyzed reactions in the oxidative direction with arabitol (64.9%), sorbitol (31%) and xylitol (24.8%). This enzyme showedK _m values of 39 mM for fructose, 7.9 mM for mannitol, 0.14 mM for NADH and 0.075 mM for NAD⁺. For the non-specific HK, only theK _m values for fructose (0.19 mM) and glucose (7.5 mM) were determined. The activities of the anabolic enzymes Mt1PDH and MtlPase were always at least two orders of magnitude higher than those of the degradative enzymes, indicating a net carbon flow towards a high intracellular mannitol pool. The function of mannitol metabolism inC. leprieurii as a biochemical adaptation to the environmental extremes in the mangrove habitat is discussed.Abbreviations F6P fructose-6-phosphate - HK hexokinase - Mt1P mannitol-1-phosphate - Mt1PDH mannitol-1-phosphate dehydrogenase - Mt1Pase mannitol-1-phosphatase - MtDH mannitol dehydrogenase     

Magnetic resonance studies on interaction of bovine brain hexokinase with manganous ion, glucose, and glucose 6-phosphate

Bovine brain hexokinase enhances the effect of Mn(II) on the longitudinal relaxation rate of water protons. Direct interaction of Mn(II) with the enzyme has been studied using electron spin resonance and proton relaxation rate enhancement methods. The results indicate that brain hexokinase has 1.05 ± 0.13 tight binding sites and 7 ± 2 weak binding sites with a dissociation constant, K_D = 25 ± 4 μM and K′_D = 1050 ± 290 μM, respectively, at pH 8.0, 23 °C. The characteristic enhancement ?_b) for hexokinase-Mn(II) complex evaluated from proton relaxation rate enhancement studies, gave ?_b = 3.5 ± 0.4 for tight binding sites and an average ?_b = 2.3 ± 0.5 per site for weak binding sites at 9 MHZ. The dissociation constant of Mn(II) for tight binding sites on the enzyme exhibits strong temperature dependence. In the low-temperature region (5–12 °C) brain hexokinase probably undergoes a conformational change. Frequency dependence of the normalized relaxation rate for bound water at various temperatures has shown that the number of exchangeable water molecules left in the first coordination sphere of bound Mn(II) is about one at 30 °C and about two at 18 °C. Binding of glucose 6-phosphate to hexokinase results in large-line broadening of the resonances of anomeric protons of the sugar. However, no such effect was observed in the case of glucose binding. These results suggest different modes of interaction of these two sugars to hexokinase. Line broadening of the C-(1) hydrogen resonances of glucose caused by Mn(II) in the presence of hexokinase suggests the proximity of the Mn(II) binding site to that of glucose. A lower limit of 1330 ± 170 s^?1 for the rate of dissociation of glucose from enzyme-Mn(II)-glucose complex has been obtained from these studies.     

Radiolysis of aqueous solutions of sugar phosphates

The mechanism of the radiation-induced dephosphorylation reaction was investigated by studying the γ-radiolysis of 10mM solutions of D-glucopyranosyl phosphate, D-glucose 6-phosphate (Glc-6-P), and d-ribose 5-phosphate (Rib-5-P). Dephosphorylation occurred with OH-radical participation, since G(H₃PO₄) values for nitrous oxide-saturated solutions were 4.1, 1.7, and 2.3, and for nitrogen-saturated solutions 2.6, 1.1, and 1.6, respectively. The formation of phosphate-free compounds accompanied the release of inorganic phosphate. The main, neutral products of the radiolysis of Glc-6-P were 6-deoxyhexos-5-ulose (G = 0.2) and D-gluco-hexodialdose (G = 0.3). Irradiation of Rib-5-P gave ribo-pentodialdose and 5-deoxypentos-4-ulose as the main, neutral products. A scheme for the dephosphorylation process is proposed.