Evidence for mannolipids as intermediates in mannose transfer to thyroid rough microsomal glycoproteins.

Thyroid rough microsomes catalyzed the transfer of mannose from GDP-mannose to endogeneous glycoprotein(s) and to glycolipids comprising a recently described dolichol phosphomannose extractable with usual organic solvents and a material tentatively identified as an oligosaccharide lipid. The labeling of the two lipids was consistent with a role in mannose transfer to glycoprotein(s). When partially purified dolichol phospho[14C] mannose was incubated with rough microsomes, a part of the label appeared in the second lipid, suggesting a role as intermediate, and less rapidly in glycoprotein(s). Sodium dodecyl sulfate/polyacrylamide gel electrophoresis did not allow to ascertain whether or not the glycoproteins receiving label from these sugar lipids comprised thyroglobulin precursors.     

Isolation of a large glycopeptide from cartilage procollagen by collagenase digestion and evidence indicating the presence of glucose, galactose and mannose in the peptide.

Digestion of cartilage procollagen, pro-α1(II), with bacterial collagenase followed by fractionation of Sephadex G-150 yielded a large glycopeptide (molecular weight 13,200) which could not be demonstrated in a similarly prepared digest of α1(II) chain. Isotopic studies suggested that this glycopeptide contained, in addition to glucose and galactose, mannose, a sugar that is not found in the authentic α-chain of cartilage. The results imply that in pro-α1(II) there is a glycopeptide region differing from the α1(II) chain in amino acid composition and also in the type of carbohydrates attached.     

Molecular dynamics of sugars bound to wheat germ agglutinin, as studied by deuterium nuclear magnetic resonance.

Deuterium nuclear magnetic resonance is used to delineate the molecular dynamics of sugars bound to a lectin. 2H spin-spin relaxation times (from linewidth measurements) and reorientational correlation times are determined for N-acetylglucosamine specifically-labeled with 2H in the N-acetyl group and at carbon-3 of the pyranoside ring, in the presence and absence of wheat germ agglutinin. The correlation time for the 2H-label of N-acetylglucosamine-3-2H in the bound state is the same as that of the protein (3 X 10(-8)S), indicating that the six-membered ring has negligible motional freedom relative to the protein. The correlation time for the C2H3 group of N-acetyl-2H3-glucosamine (1.7 X 10(-9)S) shows that the N-acetyl side chain is also immobilized in the binding site, the only motion available being rotation of the C2H3 group about its threefold axis.     

Quantitative gas—liquid chromatography of neutral sugars in human serum glycoproteins : Fucose, mannose, and galactose as predictors in ovarian and small cell lung carcinoma

A precise and accurate gas—liquid chromatographic (GLC) method has been developed for the quantitative analysis of the neutral sugars -fucose (6-deoxygalactose), mannose, galactose, and glucose in ethanol precipitates of human serum proteins. The chromatographic conditions and sample preparation resulted in short analysis times (20 min per run) and made routine analyses practicable (twelve samples per day). The alditol acetate derivatization yielded single derivatives for each sugar. Complete separation was achieved on a 2.0 m × 2 mm I.D. column with 2.0% Silar-7 CP on Chromosorb W AW 80–100 mesh. The results of hydrolysis showed that the release of fucose and galactose preceded the release of mannose. Hydrolysis with AG 50W-X8 (H⁺) ion-exchange resin in 0.5 N HCI at 100° for 7 h optimized glycosidic bond cleavage with only minimal destruction of fucose, mannose and galactose. A combination of strong cation- and anion-exchange resin columns was used to remove chromatographic background of peptides, amino acids, amino sugars, and inorganic ions. An average R.S.D. of less than 4% with recovery of <86% for the three sugars was achieved. The homogeneity of the chromatographic peaks for the neutral sugars of normal human serum glycoproteins was confirmed by GLC—mass spectrometry. Significantly elevated ratios of fucose, galactose, and mannose to serum protein were observed for patients with small cell lung and ovarian carcinomas.     

Energetic metabolism of glucose, mannose and galactose in glucose-starved rat insulinoma cells anchored on microcarrier beads. A phosphorus-31 NMR study.

Insulin-secreting cells (RINm5F) have successfully been grown on a large scale on poly-L-lysine coated-polystyrene microcarriers, providing a high cell number in a restricted volume under conditions that respect the metabolic integrity of these anchorage-dependent cells. The energetic metabolism of the perfused cells has been followed non-invasively by phosphorus-31 nuclear magnetic resonance spectroscopy. Glucose starvation induced a rapid decrease in nucleoside triphosphates (mainly ATP) pools, correlated with an increase in Pi level. The initial ATP level was rapidly recovered when the cells were refed with glucose or with mannose, but not with galactose, even after 2 h of perfusion. These differential effects of hexoses on energetic metabolism might be related to their various insulin-release actions on tumor islet cells.     

Galactose transport in Saccharomyces cerevisiae. I. Nonmetabolized sugars as substrates and inducers of the galactose transport system

The inducible galactose transport system in bakers' yeast carries out the facilitated diffusion of the nonmetabolized galactose analogues d-fucose and l-arabinose. This capacity depends on the activity of the Ga 2 gene. In some strains, d-fucose and l-arabinose are also gratuitous inducers. Mutants in which the inducibility of the galactose pathway enzymes is altered show a parallel alteration of the inducibility of the galactose transport system.     

Transport of sugars in chick-embryo fibroblasts. Evidence for a low-affinity system and a high-affinity system for glucose transport.

The rate of D-glucose uptake by cells that had been deprived of sugar for 18-24h was consistently observed to be 15-20 times higher than that in control cells maintained for the same length of time in medium containing glucose. This increased rate of glucose transport by sugar-starved cells was due to a 3-5-fold increase in the Vmax. value of a low-affinity system (Km 1 mM) combined with an increase in the Vmax of a separate high-affinity system (Km 0.05-0.2 mM). The high-affinity system, which was most characteristic of starved cells, was particularly sensitive to low concentrations of the thiol reagent N-ethylmaleimide; 50% inhibition of uptake occurred at approx. 0.01 mM-N-ethylmaleimide. In contrast with the high-affinity system, the low-affinity system of either the fed cells or the starved cells was unaffected by N-ethylmaleimide. In addition to the increases in the rate of D-glucose transport, cells deprived of sugar had increased rates of transport of 3-O-methyl-D-glucose and 2-deoxy-D-glucose. No measurable high-affinity transport system could be demonstrated for the transport of 3-O-methylgucose, and N-ethylmaleimide did not alter the initial rate. Thus the transport of 3-O-methyglucose by both fed and starved cells was exclusively by the N-ethylmaleimide-insensitive low-affinity system. The low-affinity system also appeared to be the primary means for the transport of 2-deoxyglucose by fed and starved cells. However, some of the transport of 2-deoxyglucose by starved cells was inhibited by N-ethylmaleimide, suggesting that 2-deoxyglucose may also be transported by a high-affinity system. The results of experiments that measured transport kinetics strongly suggest that glucose can be transported by a least two separate systems, and 3-O-methylglucose and 2-deoxyglucose by one. Support for these interpretations comes from the analysis of the effects of N-ethylmaleimide and cycloheximide as well as from the results of competition experiments. The uptake of glucose is quite different from that of 2-deoxyglucose and 3-O-methylglucose. The net result of sugar starvation serves to emphasize these differences. The apparent de-repression of the transport systems studied presents an interesting basis for further studies of the regulation of transport in a variety of cells.     

Characterization and compartmentation,in green leaves,of hexokinases with different specificities for glucose,fructose, and mannose and for nucleoside triphosphates

When green leaves of spinach (Spinacia oleracea L.) were surveyed for the presence of hexokinases which utilize glucose, fructose and-or mannose as a substrate, four kinases could be distinguished by their order of elution during chromatography on diethylaminoethyl (DEAE)-cellulose: (i) a hexokinase I with a specificity for fructose, glucose, and mannose, (ii) a fructokinase I with a specificity for fructose, (iii) a hexokinase II with a specificity for glucose, fructose and mannose, and (iv) a fructokinase II with a specificity for fructose. Hexokinases I and II had high apparent K_m values for fructose (8 and 15 mM, respectively) and medium or low apparent K_m values for glucose (150 and 18 μM, respectively) and mannose (18 and 15 μM, respectively). Maximal velocities were highest with fructose, medium with glucose and lowest with mannose. That hexokinases I and II used several sugars as substrate was concluded (i) from their identical elution profiles during enzyme separation and (ii) because their activities with two or three sugars at a time was always lower than the sum of activities with one substrate, indicating competition of the sugars for the reaction with the enzymes. Fructokinases I and II were very specific for fructose (85 and 140 μM, respectively) and had only little, if any, activity with glucose or mannose. All kinases showed varying degrees of activity with nucleoside triphosphates other than ATP. In the presence of all three sugars, hexokinases I and II were considerably more active with ATP than with uridine-, cytidine-, and guanosine 5'-triphosphate (UTP, CTP, GTP) except that, in the presence of glucose, hexokinase I was almost as active with UTP as with ATP. In the presence of fructose, fructokinase I exhibited highest activity with GTP and a gradually decreasing level of activity with CTP, UTP, and ATP. The activities in the presence of the other two sugars were highest with ATP. Fructokinase II was most active with ATP and fructose and progressively less active with GTP, UTP, and CTP. Cell fractionation by isopycnic density-gradient centrifugation or differential centrifugation indicated that fructokinase II was associated with chloroplasts, hexokinase II with mitochondria, and the other two kinases with the non-particulate cell fraction. In green leaves of pea (Pisum sativum L.), only a hexokinase (II) and fructokinase (II) were present. Corn (Zea mays L.) leaves exhibited only very low hexokinase activity. Dedicated to Prof. Dr. Hans Mohr on the occasion of his 60th birthday     

Kinetic analysis for the isomerization of glucose,fructose, and mannose in subcritical aqueous ethanol

Fructose, glucose, and mannose were treated with subcritical aqueous ethanol for ethanol concentrations ranging from 0 to 80% (v/v) at 180–200 °C. The aldose–ketose isomerization was more favorable than ketose–aldose isomerization and glucose–mannose epimerization. The isomerization of the monosaccharides was promoted by the addition of ethanol. In particular, mannose was isomerized most easily to fructose in subcritical aqueous ethanol. The apparent equilibrium constants for the isomerizations of mannose to fructose, K_eq,M→F, and glucose to fructose, K_eq,G→F, were independent of ethanol concentration and increased with increasing temperature. Moreover, the K_eq,M→F value was much larger than the K_eq,G→F value. The enthalpies for the isomerization of mannose to fructose, ΔH_M→F, and glucose to fructose, ΔH_G→F, were estimated to be 18 and 24 kJ/mol, respectively, according to van’t Hoff equation. Subcritical aqueous ethanol can be used to produce fructose from glucose and mannose efficiently.     

Mechanism for the autoxidation of hemoglobin by phenols,nitrite and “oxidant” drugs. Peroxide formation by one electron donation to bound dioxygen

The reaction of HbO₂ with phenols to produce metHb shows inverse rate dependence upon [H⁺], direct dependence upon [HbO₂] and [phenol], and a rate that correlates with the electron donor characteristics of the reagents. Thus, the availability of an electron from an external agent permits facile reduction of O₂ to O₂⁼ and the reaction of HbO₂ with phenols gives rise to metHb and peroxide as reaction products. In contrast, with nucleophiles such as azide O₂ is displaced as superoxide. Since reduction of bound O₂ is seen to occur only by reductive displacement or by reaction with a single electron donor, Hb apparently owes its normal resistance to autoxidation to the isolation of the binding site from electron donors and nucleophiles and not to an unique kind of iron-O₂ bonding. Such reasoning explains the effects of structural abnormality that render M-type Hbs susceptible to oxidation. Also the oxidation of HbO₂ upon exposure to “oxidant drugs” is explicable in terms of the drugs acting as one electron reducing agents towards bound dioxygen.     

Functional significance of mitochondrial bound hexokinase in tumor cell metabolism. Evidence for preferential phosphorylation of glucose by intramitochondrially generated ATP

Previous studies from this laboratory have shown that mitochondrial bound hexokinase is markedly elevated in highly glycolytic hepatoma cells (Parry, D. M., and Pedersen, P.L. (1983) J. Biol. Chem. 258, 10904-10912). A pore-forming protein, porin, within the outer membrane appears to comprise at least part of the receptor site (Nakashima, R.A., Mangan, P.S., Colombini, M., and Pedersen, P.L. (1986). Biochemistry 25, 1015-1021). In studies reported here experiments were carried out to assess the functional significance of mitochondrial bound tumor hexokinase. Two approaches were used to determine whether the bound enzyme has preferred access to mitochondrially generated ATP relative to cytosolic ATP. The first approach compared the time course of glucose 6-phosphate formation by AS-30D hepatoma mitochondria under conditions where ATP was regenerated endogenously via oxidative phosphorylation or exogenously by added pyruvate kinase and phosphoenolpyruvate. The second approach involved the measurement of the specific radioactivity of glucose 6-phosphate formed following the addition of [gamma-32P]ATP to either phosphorylating or nonphosphorylating AS-30D mitochondria. Both approaches provided results which show that the source of ATP for bound hexokinase is derived preferentially from the ATP synthase residing within the inner mitochondrial membrane compartment rather than from the medium (i.e. from the cytosolic compartment). These results provide the first direct demonstration that the exceptionally high level of hexokinase bound to mitochondria of highly glycolytic tumor cells has preferred access to mitochondrially generated ATP, a finding that may have rather profound metabolic significance for such tumors.     

Evidence that the lipid carrier for N-acetylglucosamine is different from that for mannose in mung beans and cotton fibers

Cell-free enzyme particles from mung beans (Phaseolus aureus) or cotton (Gossypium hirsutum L.) fibers catalyze the incorporation of mannose from GDP-[¹⁴C]mannose and N-acetylglucosamine from UDP-[³H]-N-acetylglucosamine into polyprenyl-type lipids. These lipids have been synthesized and purified and the lipid moieties compared to each other as well as to dolichyl phosphate and to lipids isolated from similar mannoseand N-acetylglucosamine-containing lipids from liver and aorta.

The following lines of evidence indicate that in plants, the lipid carrier for N-acetylglucosamine is different from the lipid carrier for mannose: [List: see text]

We propose that the apparent difference in the lipid carrier for these two sugars may be a point of control of glycoprotein synthesis.

     

The stability of the heme-globin linkage in some normal, mutant, and chemically modified hemoglobins.

The rates and equilibria of heme exchange between methemoglobin and serum albumin were measured using a simple new spectrophotometric method. It is based on the large difference between the spectrum of methemoglobin and that of methemealbumin at pH 8-9. The rate of heme exchange was found to be independent of the albumin concentration and inversely proportional to the hemoglobin (Hb) concentration. Taken together with the finding that the rate was 10 times greater for Hb Rothschild, which is completely dissociated into alpha beta dimers and 10 times smaller for two cross-linked hemoglobins, the subunits of which cannot dissociate, this showed that the rate of dissociation of heme from alpha beta dimers is very much greater than from tetramers. Conditions were found for the attainment of an equilibrium distribution of hemes between beta globin and albumin. The equilibrium distribution ratio, R = methemealbumin/albumin/methemoglobin/apohemoglobin, for hemoglobin A was 3.4 with human and 0.005 with bovine serum albumin. Both the rates of exchange and the R values of HbS and HbF were the same as that for HbA. The equilibrium distribution ratio for Hb Rothschild was 7 times greater than that for HbA whereas that of one but not the other of the cross-linked hemoglobins was 10 times smaller. The structural bases for these differences are analyzed.     

Direct measurement of carbon monoxide bound to different subunits of hemoglobin A in solution and in red cells by infrared spectroscopy

Infrared spectra for carbon monoxide bound to alpha and beta subunits of human hemoglobin A have subunit differences near 1950 cm-1 and indicate that 92% of the alpha subunits exist in one conformer and 5% in a second conformer under conditions where 99% of the beta subunit is in only one conformation. The sum of the separated subunit spectra is equivalent to the alpha 2 beta 2 tetramer spectrum. CO infrared spectra indicate that CO displaces O2 from HbO2 in red cells or in solution preferentially at the beta subunits. The measurement of C-O stretch bands provides a direct method for characterization of ligand binding sites within intact cells.     

Regulation of phenobarbital-induced ferrochelatase mRNA activity by dibutyryl cAMP and glucose in normal and diabetic rat hepatocytes.

The induction of ferrochelatase activity by phenobarbital and its potentiation by dibutyryl cAMP assayed in normal rat hepatocytes are associated with increased activity of ferrochelatase mRNA. Glucose inhibits this stimulatory effect. This inhibition can be reversed with increasing concentrations of dibutyryl cAMP. The inducing effect exerted by phenobarbital on the activity of ferrochelatase mRNA in diabetic hepatocytes is greater than that observed in normal cells. This enhanced response in diabetic rat hepatocytes is neither potentiated by adding dibutyryl cAMP nor repressed by glucose. The absence of a glucose effect persists even when the endogenous cAMP content is lowered to normal levels. The results obtained in this study are consistent with those reported in other published studies of ferrochelatase activity. This adds more experimental evidence to support the concept that ferrochelatase is inducible. The results obtained suggest that ferrochelatase is more susceptible to induction with phenobarbital in diabetic rat hepatocytes than in normal rat hepatocytes.     

Compared roles of glucose, galactose and fructose as glycogen precursors during the acute response to insulin in cultured rat foetal hepatocytes

1. The efficiency of the contribution of hexoses to basal- and stimulated-glycogenesis, when studied in cultured 18 day-old rat foetal hepatocytes in the presence of glucose, was as follows: galactose greater than glucose greater than fructose. 2. Glucose deprivation had opposite effects on the contributions of [14C]galactose (decreased) and [14C]fructose (increased) to glycogenesis, which occurred independently of insulin and were reversed by glucose concentrations as low as 30-100 microM. 3. The stimulation of glycogenesis by insulin measured with [14C]glucose (3.2-fold) was superior to that obtained with either [14C]galactose or [14C]fructose (2.7-fold in both cases), which revealed a specific beneficial effect of insulin on glucose contribution.     

Implication of the alpha 1 beta 1 interface in the hemoglobin affinity changes. A comparative study between normal and San Diego fully ligated hemoglobins

The alpha 1 beta 1 interface of normal and mutated San Diego hemoglobins in their fully liganded form was investigated, through the SH vibrational absorption of beta-112 cysteine, by Fourier-transform infrared spectroscopy. The center frequency of this thiol group was significantly shifted in San Diego hemoglobin compared with normal human hemoglobin. Different dimer organization between the two proteins was also revealed by circular dichroism of the heme. These findings agree well with assessment that the alpha 1 beta 1 interface, far from being inert, is involved in the affinity changes of the hemoglobin molecule.