The metal ion catalyzed decomposition of nucleoside diphosphate sugars.

The metal ion catalysed decomposition of the nucleotide diphosphate sugars, uridine diphosphate glucose, uriding diphosphate galactose, uridine diphosphate N-acetylglucosamine, guanosine diphosphate mannose, and guanosine diphosphate fucose (UDPGlc, UDPGal, UDPGlc-NAc, GDPMan, and GDPFuc, respectively), has been studies as a function of pH. UDPDlc and UDPGal decompose readily to the a,2-cycle phosphate derivative of the sugar and uridine 5'-phosphoric acid (UMP) in the presence of Mn2+. Under all conditions tested, UDPGal decomposes two to three times more rapidly than does UDPGlc. GDPFuc is slowly degraded to free fucose under similar conditions; the other nucleotide diphosphate sugars are stable. The rate of reaction increases with increasing hydroxide ion concentration from pH 6.5 to 7.9 and with metal ion concentration from 10 to 200 mm. Several metal ions are effective catalysts; at pH 7.5 WITH 20 mM UDPGal and 20 mM metal ion, the following apparent first-order rate constants (min-1 x 10(4)) were obtained: Eu3+ 700; Mn2+, 70; Co2+ 27; Zn2+, 22; Ca2+, 3.0; Cu2+, 2.4; and Mg2+, 0. It appears that Mn2+ concentrations that have been used in studies with nucleotide diphosphate sugars at neutral pH can catalyze significant decomposition leading to erroneous interpretation of kinetic and incorporation experiments.     

Chemico-enzymatic synthesis of Salmonella newington O-specific polysaccharide and its modified derivatives

Treatment of the DMan (beta 1-4) LRha (alpha 1-3) D [3H]Gal-derivative of moraprenyl pyrophosphate with the cell envelope preparation from S. newington results in the formation of polysaccharide with beta 1-6 linkage between the trisaccharide units (polymerization degree approximately 8). The synthetic derivatives of moraprenyl pyrophosphate which contain D-talose, 4-deoxy-D-xylo-hexose, LRha (alpha 1-3) DGlc or LRha (alpha 1-3) DGlc (alpha 1-6) DGal were found to serve as substrates for the biosynthesis of the corresponding modified polysaccharides.     

Conversion of dolichyl pyrophosphate N,N'-diacetylchitobiose to lipid-tri- to heptasaccharides by liver microsomes from hibernating ground squirrels (Citellus citellus L.)

Incubation of liver microsomes from hibernating ground squirrel with GDP-[14C]mannose and exogenous dolichyl phosphate resulted in the synthesis of dolichyl phosphate [14C]mannose. The mannosyltransferase activity was about 3-fold higher in microsomes from hibernating ground squirrels than in those from active animals. Incubation for 30 min of liver microsomes from hibernating animals with dolichyl pyrophosphate N,N'-diacetyl-[14C]chitobiose and GDP-[14C]mannose led to the synthesis of lipid-[14C]trisaccharide. When liver microsomes were incubated with lipid-[14C]trisaccharide and unlabelled GDP-mannose, lipid-tetra- to heptasaccharides were discovered in the chloroform-methanol (2:1) extract. Since, under the experimental conditions, negligible synthesis of dolichyl phosphate mannose was observed, it was assumed that GDP-mannose was a donor of mannose in the conversion of lipid-trisaccharide into lipid-oligosaccharides containing 2-5 mannose residues.     

Acceptor specificity of mannosyl transferases from Salmonella of serotypes C2 and C3

Synthetic mono- and disaccharide derivatives of moraprenyl pyrophosphate were studied as mannose acceptors during the assembly of the repeating unit Rha-Man-Man-Gal of the Salmonella newport (serogroup C2) and S. kentucky (serogroup C3) O-antigens. Mannosyl transferases revealed strict specificity towards the configuration of terminal monosaccharide residue at C1 as well as to the type of linkage between monosaccharide residues in the disaccharide acceptor. The specificity of mannosyl transferases towards the structure of subterminal monosaccharide was not absolute. Alpha-D-Glucose and alpha-D-mannose derivatives were found not to serve as mannosyl residue acceptors, whereas those of alpha-D-talose, alpha-D-fucose, 4-deoxy-D-xylo-hexose and Man (alpha 1-3) glucose were substrates in enzymatic mannosylation with formation of polyprenyl pyrophosphate trisaccharides. These derivatives could serve as substrates for two subsequent enzymatic reactions: rhamnosylation and polymerization of the repeating units, yielding 40-60% of the polysaccharides.     

Biosynthesis of oleanolic acid glycosides by subcellular fractions of Calendula officinalis seedlings

The synthesis of oleanolic acid 3β-d-glucuronoside from oleanolic acid and UDPGlcA has been demonstrated in cell-free preparations from C. officinalis seedlings. Moreover, the formation of more complex glycosides by successive additions of galactose and glucose to oleanolic acid glucuronoside was observed when cell-free preparations were incubated with UDPGal or UDPGlc. The consecutive steps of oleanolic acid glycosylation are localized in three different cellular compartments. The biosynthesis of the 3-glucuronoside takes place in the microsomes, the elongation of the sugar chain at C-3 of the aglycone proceeds in heavy membrane structures which are probably fragments of the Golgi complex while a cytosol enzyme(s) is involved in glucosylation of the C-17 carboxyl group of oleanolic acid.     

Purification and some regulatory properties of glycogen synthase I from rabbit renal medulla

1. Glycogen synthase I (activity ratio approximately equal to 1) was purified over 10,000-fold from rabbit renal medulla. 2. The purified synthase was stimulated about 1.5-fold by glucose-6-P and other divalent anions when assayed at pH 7.7 and near saturating UDPGlc. When assayed at physiological UDPGlc (75-100 microM), the enzyme was stimulated about 5-fold by glucose-6-P. 3. At pH 7.7 the activation by either Na2SO4 or glucose-6-P was due to an increase in V and a decrease in S0.5 for UDPGlc. At pH. 6.9, activation was due to a decrease in S0.5. 4. At low UDPGlc, synthase activity was inhibited by adenine nucleotides and the inhibition was partially relieved by glucose-6-P, UDP inhibited in a competitive manner with respect to UDPGlc. 5. These results suggest that the activity of renal medullary synthase I may be regulated by cellular metabolites.     

Regulation of malate oxidation in isolated mung bean mitochondria: I. Effects of oxaloacetate, pyruvate, and thiamine pyrophosphate

In order to investigate the relationship between malate oxidation and subsequent cycle reactions, the effects of oxaloacetate, pyruvate, and thiamine pyrophosphate on malate oxidation in mung bean (Phaseolus aureus var. Jumbo) hypocotyl mitochondria were quantitatively examined. Malate oxidation was optimally stimulated by addition of pyruvate and thiamine pyrophosphate, whose addition lowered the apparent Km for malate from 5 mm to 0.1 mm. Intermediate analysis showed that the stimulatory effect was correlated with removal of oxaloacetate to citrate. Oxaloacetate added alone was shown not to be metabolized until addition of pyruvate and thiamine pyrophosphate; then oxaloacetate was converted in part to pyruvate and also to citrate. These results establish that malate oxidation in mung bean mitochondria is subject to control by oxaloacetate levels, which are primarily determined by the resultant of the activities of malate dehydrogenase, citrate synthase, and pyruvate dehydrogenase.     

Early explorations of the pathways of uridine diphosphate galactose in man and in microorganisms

Thirty years ago, a number of human inborn errors in carbohydrate metabolism were explored with specific enzymatic tests on blood samples (hemolysates). Hereditary galactosemia was the first example. When the inoperative step in galactose metabolism was specified, the basis for the diet therapy used on the galactosemic infants, namely galactose-free diet, could be shown to be securely founded. As far as galactose metabolism is concerned, the cells of the infant are faced with two problems: (i) the conversion of dietary lactose (galactosyl glucose) to glucose and its catabolites involved in energy metabolism, and (ii) the conversion of dietary glucose or lactose to galactosyl units of glycolipids and glycoprotein cell structures. Subsequent studies on microorganisms revealed several types of hereditary defect in galactose metabolism. One type which permits the bacteria to develop a normal carbohydrate pattern in their cell walls includes an enzyme defect, like that described in the cells of the galactosemic infant. Two other types, with the inability to synthesize UDPGlc or UDPGal from glucose, do not permit the bacteria to build the fabric of the normal bacterial cell wall. This is the subject for discussion.     

Sucrose is metabolised by sucrose synthase and glycolysis within the phloem complex of Ricinus communis L. seedlings

Metabolites and enzyme activities were measured in the phloem sap exuding from a cut hypocotyl of germinating castor-bean (Ricinus communis L.) seedlings. The sap contained considerable quantities of adenine nucleotides, uridine nucleotides, uridine diphosphoglucose (UDPGlc), all the major phosphorylated metabolites required for glycolysis, fructose-2,6-bisphosphate and pyrophosphate. Supplying 200 mM glucose instead of sucrose to the cotyledons resulted in high concentrations of glucose in the sap, but did not modify the metabolite levels. In contrast, when 200 mM fructose was supplied we found only a low level of fructose but a raised sucrose concentration in the sap, which was accompanied by a three-to fourfold decrease of UDPGlc, and an increase of pyrophosphate, UDP and UTP. The measured levels of metabolites are used to estimate the molar mass action ratios and in-vivo free-energy change associated with the various reactions of sucrose breakdown and glycolysis in the phloem. It is concluded that the reactions catalysed by ATP-dependent phosphofructokinase and pyruvate kinase are removed from equilibrium in the phloem, whereas the reactions catalysed by sucrose synthase, UDPGlc-pyrophosphorylase, phosphoglucose mutase, phosphoglucose isomerase, aldolase, triose-phosphate isomerase, phosphoglycerate mutase and enolase are close to equilibrium within the conducting elements of the phloem. Since the exuded sap contained negligible or undetectable activities of the enzymes, it is concluded, that the responsible proteins are bound, or sequesterd behind plasmodesmata, possibly in the companion cells. It is argued that sucrose mobilisation via a reversible reaction catalysed by sucrose synthase is particularily well suited to allow the rate of sucrose breakdown in the phloem to respond to changes in the metabolic requirement for ATP, and for UDPGlc during callose production. It is also calculated that the transport of nucleotides in the phloem sap implies that there must be a very considerable uptake or de-novo biosynthesis of these cofactors in the phloem.     

Chemico-enzymatic synthesis of branched O-specific polysaccharides of Salmonella serotype C2 and C3]

The possibility of chemical-enzymatic synthesis of branched polysaccharides was demonstrated with the enzymes from Salmonella newport and S. kentucky using synthetic polyprenyl pyrophosphate oligosaccharides. Formation of polymers with alpha 1-2-, beta 1-2-alpha 1-4- and beta 1-4-linkages between glucose residues in the branch and galactose residues of the main chain was shown.     

Prenyltransferase: the mechanism of the reaction.

The enzyme, prenyltransferase, which normally catalyzes the addition of an allylic pyrophosphate to isopentenyl pyrophosphate, has been found to catalyze the hydrolysis of its allylic substrate. The rate of this hydrolysis is markedly stimulated by inorganic pyrophosphate. Competition experiments with 2-fluoroisopentenyl pyrophosphate and inorganic pyrophosphate demonstrated that inorganic pyrophosphate stimulated hydrolysis by binding at the isopentenyl pyrophosphate site. Hydrolysis carried out in H218O or with (1S)-[1-3H]geranyl pyrophosphate show the C-O bond is broken and the C1 carbon of geranyl pyrophosphate is inverted in the process. These results are interpreted to favor a carbonium ion mechanism for the prenyltransferase reaction.     

Two forms of farnesyl pyrophosphate synthetase from hog liver

Two forms of farnesyl pyrophosphate synthetase were separated from hog liver extracts by DEAE-Sephadex chromatography. They were designated as farnesyl pyrophosphate synthetase A and B, in order of elution. Both enzymes catalyzed the exclusive formation of E,E-farnesyl pyrophosphate from isopentenyl pyrophosphate and either dimethylallyl pyrophosphate or geranyl pyrophosphate. They also showed no detectable differences in pH optima, molecular weights, and susceptibilities to metal ions. However, the catalytic activity of the synthetase B was greatly stimulated by the addition of common sulfhydryl reagents. This stimulation was the result of conversion of the synthetase B into the synthetase A. Conversely the synthetase A was converted into form B when it was dialyzed against a buffer solution containing cupric ions. It is suggested that the formation and cleavage of disulfide bond(s) is involved in the interconversion between the two forms.     

Receptor function of mouse sperm surface galactosyltransferase during fertilization

Past studies from this laboratory have suggested that mouse sperm binding to the egg zona pellucida is mediated by a sperm galactosyltransferase (GalTase), which recognizes and binds to terminal N-acetylglucosamine (GlcNAc) residues in the zona pellucida (Shur, B. D., and N. G. Hall, 1982, J. Cell Biol. 95:567-573; 95:574-579). We now present evidence that directly supports this mechanism for gamete binding. GalTase was purified to homogeneity by sequential affinity-chromatography on GlcNAc-agarose and alpha-lactalbumin-agarose columns. The purified enzyme produced a dose-dependent inhibition of sperm binding to the zona pellucida, relative to controls. To inhibit sperm/zona binding, GalTase had to retain its native conformation, since neither heat-inactivated nor Mn++-deficient GalTase inhibited sperm binding. GalTase inhibition of sperm/zona binding was not due to steric blocking of an adjacent sperm receptor on the zona, since GalTase could be released from the zona pellucida by forced galactosylation with UDPGal, and the resulting galactosylated zona was still incapable of binding sperm. In control experiments, when UDPGal was replaced with the inappropriate sugar nucleotide, UDPglucose, sperm binding to the zona pellucida remained normal after the adsorbed GalTase was washed away. The addition of UDPGal produced a dose-dependent inhibition of sperm/zona binding, and also dissociated preformed sperm/zona adhesions by catalyzing the release of the sperm GalTase from its GlcNAc substrate in the zona pellucida. Under identical conditions, UDP-glucose had no effect on sperm binding to the zona pellucida. The ability of UDPGal to dissociate sperm/zona adhesions was both time- and temperature-dependent. UDPGal produced nearly total inhibition of sperm/zona binding when the zonae pellucidae were first galactosylated to reduce the number of GalTase binding sites. Finally, monospecific anti-GalTase IgG and its Fab fragments produced a dose-dependent inhibition of sperm/zona binding and concomitantly blocked sperm GalTase catalytic activity. Preimmune IgG or anti-mouse brain IgG, which also binds to the sperm surface, had no effect. The sperm GalTase was localized by indirect immunofluorescence to a discrete plasma membrane domain on the dorsal surface of the anterior head overlying the intact acrosome. These results, along with earlier studies, show clearly that sperm GalTase serves as a principal gamete receptor during fertilization.     

The concentration of red blood cell UDPglucose and UDPgalactose determined by high-performance liquid chromatography.

We have developed a sensitive method that employs high-performance liquid chromatography to separate and quantitate uridine diphosphogalactose (UDPGal) and uridine diphosphoglucose (UDPGlu) in human red blood cells. The trichloracetic acid extracts of red blood cells were chromatographed using a Dionex CarboPac anion-exchange resin and a 20-40% potassium phosphate buffer, pH 4.5, in a gradient-elution program. UDPGal and UDPGlu were detected spectrophotometrically at 254 nm. Recoveries of UDPGal and UDPGlu ranged from 96 to 106%. Under these conditions, there was exceptionally good reproducibility in stored specimens, and the method was sensitive in the low picamole range. The mean values and standard deviations in adults were 2.9 +/- 0.4 and 7.8 +/- 0.8 mumol/100 g Hgb for UDPGal and UDPGlu, respectively. The values in children were 4.5 +/- 1.2 and 10.2 +/- 1.7 mumol/100 g Hgb for UDPGal and UDPGlu, respectively. Values determined by the HPLC method are in excellent agreement with those obtained by enzyme analysis.     

Formation of 3-hexaprenyl-4-hydroxybenzoate by matrix-free mitochondrial membrane-rich preparations of yeast.

It has been shown that a 10 000 x g matrix-free mitochondrial membrane-rich preparation from commercial bakers' yeast is able to synthesize 3-all-transhexaprenyl-4-hydroxybenzoate from 4-hydroxybenzoate and isopentenyl pyrophosphate. The synthesis is Mg2+ dependent and is stimulated markedly by the primer for polyprenylpyrophosphate synthesis of 3-hexaprenyl-4-hydroxybenzoate from 4-hydroxybenzoate, isopentenyl pyrophosphate and 3,3-dimethylallyl pyrophosphate the priming function of 3,3-dimethylallyl pyrophosphate can be performed by either geranyl pyrophosphate (most efficient) or farnesyl pyrophosphate. At high Mg2+ concentrations, however, geranyl pyrophosphate and farnesyl pyrophosphate act mainly as sources of preformed side chains and 3-diprenyl- and 3-tripenyl-4-hydroxybenzoate, respectively, are produced. In the presence of a source of preformed polyprenyl pyrophosphates the membrane preparations catalysed the polyprenylation of methyl-4-hydroxybenzoate, 4-hydroxybenzaldehyde, 4-hydroxybenzylalcohol and 4-hydroxycinnamate. No evidence was obtained for the involvement of either 4-hydroxybenzoyl CoA or 4-hydroxybenzoyl-S-protein in the formation of 3-polyprenyl-4-hydroxybenzoates.     

The stereochemistry of betulaprenol biosynthesis

By using stereospecifically double-labelled radioactive mevalonates it was shown that betulaprenols-6 to -9, found in the woody tissue of Betula verrucosa, each contain three biogenetically trans-isoprene residues and that the remaining residues are biogenetically cis. The results obtained with these radioactive mevalonates also indicated that the activity of isopentenyl pyrophosphate isomerase is low relative to the activity of prenyltransferase in this woody tissue. The incorporation of radioactive farnesyl pyrophosphate and radioactive geranylnerol and the lack of incorporation of radioactive geranylgeraniol into betulaprenols-6 to -9 demonstrated that they are formed by the cis-additions of isoprene residues to all-trans-farnesyl pyrophosphate.     

Effect of d-galactosamine administration on nucleotide and protein metabolism in isolated rat Kupffer cells.

The nucleoti-e contents of isolated rat Kupffer cells were found to be smaller than those of hepatocytes. The rate of UDPGal formation from D-galactose was much lower in Kupffer cells than in hepatocytes. The viability of the former was checked by measuring the leakage of enzymes and the formation of UTP from uridine. Addition of GalN to isolated Kupffer cells did not decrease their UTP and UDPG contents as much as those of hepatocytes. The same results were obtained when cells were isolated from GalN-pretreated animals. The incorporation of labeled amino acids into protein after GalN addition was much less reduced in Kupffer cells than in hepatocytes. The data suggest that Kupffer cells do not contribute to GalN-induced liver injury as a result of uridylate trapping.     

Interaction of uridine diphosphate glucose with calf liver uridine diphosphate glucose dehydrogenase. Significance of hydroxyl groups at C-3, C-4 and C-6 of hexosyl residue.

Analogs of uridine diphosphate glucose (UDPGlc) with a modified hexosyl residue which contained a deoxy-unit at C-3 or C-4 were tested as substrates of calf liver UDPGlc dehydrogenase (EC 1.1.1.22). The 3-deoxyglucose derivative was found not to serve as a substrate for the enzyme whereas the 4-deoxyglucose analog was able to participate in the reaction. The apparent Km of the latter was 5.3 times that of UDPGlc and the relative V was 0.04. The reaction product was identified as uridine diphosphate deoxyhexuronic acid. UDP-deoxyhexoses were non-competitive inhibitors of UDPGlc enzymic oxidation, inhibition increased in the sequence: 2-deoxy-less than 3-and 6-deoxy-less than 4-deoxyglucose derivative. The significance of different HO-groups in hexosyl residue for interaction of UDPGlc with the enzyme is discussed.     

Adenylate cyclase of human articular chondrocytes. Responsiveness to prostaglandins and other hormones.

Adenylate cyclase [ATP pyrophosphate lyase (cyclizing), EC 4.6.1.1] was shown to be present in cultured human articular chondrocytes. Optimal conditions of incubation time, protein and substrate concentrations and pH were determined in whole cell lysates. Maximal activity occurred at pH 8.5 with no decrease in activity up to pH 10.0. Adenylate cyclase activity of particulate membrane preparations was enhanced by the addition of crude cytosol preparations. The prostaglandins E1, E2, F1 alpha, F2 alpha, D2, B1, B2, A1 and A2, as well as adrenaline and isoprenaline, stimulated adenylate cyclase derived from either adult or foetal chondrocytes. No significant stimulation was observed in the presence of human calcitonin or glucagon. Bovine parathyroid hormone always significantly stimulated the adenylate cyclase derived from foetal chondrocytes, but not from adult chondrocytes. Preincubation of the chondrocytes in culture with indomethacin and with or without supernatant medium from cultured mononuclear cells increased the responsiveness of the adenylate cyclase to prostaglandin E1.     

Isoprenoid enzyme systems of silkworm. I. Partial purification of isopentenyl pyrophosphate isomerase, farnesyl pyrophosphate synthetase, and geranylgeranyl pyrophosphate synthetase

Isopentenyl pyrophosphate isomerase, farnesyl pyrophosphate synthetase, and geranylgeranyl pyrophosphate synthetase were detected in cell-free extracts of Bombyx mori and were partially purified by hydroxyapatite and Sephadex G-100 chromatography. Two forms of farnesyl pyrophosphate synthetase were chromatographically separated. They were designated as farnesyl pyrophosphate synthetases I and II in the order of their elution from hydroxyapatite. Both enzymes catalyzed the exclusive formation of (E,E)-farnesyl pyrophosphate from isopentenyl pyrophosphate and either dimethylallyl pyrophosphate or geranyl pyrophosphate. However, they were not interconvertible, unlike the enzyme from pig liver. These two enzymes resembled each other in pH optima and molecular weights but differed in susceptibility to metal ions. Farnesyl pyrophosphate synthetase II was stimulated by Triton X-100 while synthetase I was inhibited by the same reagent.