Chemical and enzymic degradations of nucleoside mono- and diphosphate sugars. I. Determination of the degradation rate during the glycosyltransferase assays

A kinetic study on the chemical cleavage of nucleoside diphosphate sugars

Nucleoside diphosphate sugars serve in essential roles in metabolic processes. They have, therefore, been used in mechanistic studies on glycosylation reactions, and their analogues have been synthesised as enzyme and receptor inhibitors. Despite extensive biochemical research, little is known about their chemical reactions. In the present work the chemical cleavage of two different types of nucleoside diphosphate sugars has been studied. UDP-Glc is phosphorylated at the anomeric carbon, whereas in ADP-Rib C-1 is unsubstituted, allowing hence the equilibrium between cyclic hemiacetal and acyclic carbonyl forms. Due to the structural difference, these substrates react via different pathways under slightly alkaline conditions: while UDP-Glc reacts exclusively by a nucleophilic attack of a glucose hydroxyl group on the diphosphate moiety, ADP-Rib undergoes a complex reaction sequence that involves isomerisation processes of the acyclic ribose sugar and results in a release of ADP.

Determination of the intracellular sites and topology of glucosylceramide synthesis in rat liver

We examined the intracellular site(s) and topology of glucosylceramide (GlcCer) synthesis in subcellular fractions from rat liver, using radioactive and fluorescent ceramide analogues as precursors, and compared these results with those obtained in our recent study of sphingomyelin (SM) synthesis in rat liver [Futerman, Stieger, Hubbard & Pagano (1990) J. Biol. Chem. 265, 8650-8657]. In contrast with SM synthesis, which occurs principally at the cis/medial Golgi apparatus, GlcCer synthesis was more widely distributed, with substantial amounts of synthesis detected in a heavy (cis/medial) Golgi-apparatus subfraction, a light smooth-vesicle fraction that is almost devoid of an endoplasmic-reticulum marker enzyme (glucose-6-phosphatase), and a heavy vesicle fraction. Furthermore, no GlcCer synthesis was detected in an enriched plasma-membrane fraction after accounting for contamination by Golgi-apparatus membranes. These results suggest that a significant amount of GlcCer may be synthesized in a pre- or early Golgi-apparatus compartment. Unlike SM synthesis, which occurs at the luminal surface of the Golgi apparatus, GlcCer synthesis appeared to occur at the cytosolic surface of intracellular membranes, since (i) limited proteolytic digestion of intact Golgi-apparatus vesicles almost completely inhibited GlcCer synthesis, and (ii) the extent of UDP-glucose translocation into the Golgi apparatus was insufficient to account for the amount of GlcCer synthesis measured. These findings imply that, after its synthesis, GlcCer must undergo transbilayer movement to the luminal surface to account for the known topology of higher-order glycosphingolipids within the Golgi apparatus and plasma membrane.

Improved assays of alpha-lactalbumin and galactosyltransferase

The development and evaluation of a method for the determination of galactosyltransferase and alpha-lactalbumin activities using the addition of Dowex resin to the sample to separate substrate from products are described. For both assays galactosyltransferase activity was optimized by the addition of detergent, and relevant control incubations were included. The assay conditions were optimized for epididymal tissue and standards, and the assays were validated for accuracy and specificity with authentic bovine proteins and lactating rat mammary gland homogenates. Galactosyltransferase and alpha-lactalbumin activities in tissues were dependent on the extraction procedure used. Epididymal and testicular homogenates reduced the slopes of internal standards of galactosyltransferase but only testicular homogenates depressed slopes of internal standards of alpha-lactalbumin, necessitating the use of internal standards in the validation of the assays.

Serum galactosyltransferase activity with three acceptors in ovarian cancer patients

Several laboratories have demonstrated the usefulness of serum galactosyltransferase as a biological marker for ovarian neoplasms. However, contradictory results have been published recently, which might be partially explained by differences in methodology. We thus decided to measure serum galactosyltransferase activity in patients with ovarian cancer and benign gynecological diseases using three different assay systems. A very good correlation was obtained between the results of these assays. Furthermore, we confirm that serum GT is frequently elevated in cancer patients, and is of potential value for their follow-up.

The attachment of UDP-hexosamines to the ribosomes isolated from rat liver

The binding of UDP-N-acetylhexosamines with purified ribosomes was studied and it was found that the radioactive nucleotides can be attached to these particles. The radioactivity of the purified ribosomal pellet depends on the amounts of ribosomes and UDP-N-acetylhexosamines. Some characteristics of the binding system indicate that the attachment of UDP-sugar to ribosome does not require the participation of glycosyltransferases. The results of the competition experiment would suggest that there are specific sites on ribosomes for the binding of UDP-N-acetylglucosamine.

The binding of decomposition products of UDP-galactose to the microsomes and polyribosomes isolated from rat liver

UDP-D-[U-14C]galactose is decomposed to [U-14C]galactose-1-phosphate and [U-14C]galactose by rat liver microsomal and crude polyribosomal fractions, under conditions commonly used to assay of glycosyltransferase activities. UDP-D-[U-14C]galactose, at neutral pH, is also chemically degraded to the [U-14C]galactose-1,2-cyclic phosphate. The 1,2-cyclic phosphate derivative of galactose also exists in the commercial UDP-D-[U-14C]galactose. It is a very important finding that products of the UDP-D-[U-14C]galactose decomposition are tightly, although nonenzymatically, bound to tested subcellular fractions and may create a false impression of protein glycosylation. The application of controls containing all radioactive substances present in suitable samples is recommended in order to avoid incorrect interpretations of the results.

A collagen:glucosyltransferase at the surface of malignant fibroblasts

3T12 fibroblasts possess glucosyltransferases that catalyze the transfer of glucose from UDP-Glucose to galactosylhydroxylysyl residues on collagenous acceptors. The presence of the enzyme activity at the cell surface is indicated by the following findings: a) suspensions of intact cells, as well as intact cell monolayers, glucosylate gelatinized collagen b) glucose transfer is not due to UDP-Glucose hydrolysis and subsequent intracellular utilization of the free glucose c) experiments using cell suspensions with known proportions of broken cells indicate that the glucosyltransferase activity is attributable to intact cells and not to contamination by intracellular enzymes from broken cells. The Km value for UDP-Glucose is about 20 microM. The enzyme has a pronounced requirement for manganese, and shows highest activity between 2 and 10 mM. The optimal Mn2+ concentration for the intracellular gelatin:glucosyltransferase activity is more restricted (5 to 10 mM). Glucosyltransferase activity is strongly inhibited by diamide and N-ethylmaleimide (5 mM), suggesting that intact sulfhydryl residues present in the enzyme are essential.

Alteration of glycosyltransferase activities during proliferation of cultivated arterial endothelial cells and smooth muscle cells

The activities of glycosyltransferases involved in the biosynthesis of N-linked glycans of glycoproteins in cultivated endothelial and smooth muscle cells have been analysed. Both cell types contain galactosyl-, N-acetylglucosaminyl-, sialyl- and fucosyltransferases in decreasing order of activity, but the specific enzyme activity of glycosyltransferases is higher in endothelial cells. These differences are due neither to elevated glycosidase activities nor to enhanced hydrolysis of nucleotide sugars. Cell growth and differentiation have substantial influence on glycosyltransferase expression. Within 5 days after plating of endothelial cells all glycosyltransferase activities increase 3-10-fold. The highest activities are found in confluent cultures. In smooth muscle cells, however, the activities of all transferases except N-acetylglucosaminyltransferase, whose activity does not change during the logarithmic growth phase, increase by only 20-50%. Glycosidases are subject to variations but the specific activities are not strictly correlated to cell proliferation. Four days after the beginning of cultivation the activities of alpha-fucosidase and beta-N-acetylhexosaminidase are at a minimum in endothelial cells, whereas the activities of these enzymes attain their maxima in smooth muscle cells. The results suggest that the biosynthesis of glycoproteins in endothelial and smooth muscle cells is subject to growth-dependent regulation. Thus, substantial alterations of the cellular glycoprotein pattern are expected to occur during cell proliferation.

Galactosyltransferases: physical, chemical, and biological aspects

Galactosyltransferases (GTs) are one of the members of a family of enzymes called glycosyltransferases involved in the biosynthesis of complex carbohydrates. These enzymes catalyze the transfer of galactose from UDP-galactose to an acceptor (glycoprotein, glycolipid) containing terminal N-acetylglucosamine or N-acetylgalactosamine residue. GTs occur in soluble (milk, serum, effusions, etc.) and insoluble (membrane) forms. The GT activities on the outer surface of the cells have been correlated with a host of cellular interactions, including fertilization, cell migration, embryonic induction, chondrogenesis, contact inhibition of growth, cell adhesion, hemostasis, intestinal cell differentiation, and immune recognition. GTs have been purified to homogeneity using affinity chromatography. Most GTs are found active in the pH range 6 to 8 and at temperatures between 35 to 40 degrees C. Manganese is an essential co-factor for GT activity. Isoenzymes of GT have been recognized, especially in tumor tissues, malignant effusions, and sera of cancer patients using polyacrylamide gel electrophoresis in the presence and absence of SDS. Depending on the source of the enzyme, the molecular weights of GTs range between 40,000 to 80,000 daltons. Carcinoma-associated GT isoenzyme has been reported to have a higher molecular weight than the normal GT isoenzyme. Development of monoclonal antibody against the cancer-specific GT isoenzyme will provide help in the development of an immunoassay for the measurement of this isoenzyme in the sera and an aid in the radioimmunolocalization of the tumors in cancer patients.

Study of the conversion of GDP-mannose into GDP-fucose in Nereids: a biochemical marker of oocyte maturation

Homogenates of Perinereis cultrifera oocytes were found to transform GDP-D-mannose into another sugar nucleotide. Ultraviolet absorption spectra, chromatographic behaviour, gas-liquid chromatography coupled to mass spectrometry analysis revealed that GDP-D-mannose had been converted into GDP-L-fucose. This conversion is a multi-step reaction as proved by the involvement of two intermediates identified as GDP-4-oxo-6-deoxy-D-mannose and GDP-4-oxo-6-deoxy-L-galactose, this latter being reduced by NADPH to give GDP-L-fucose. It is shown that the enzymatic activities responsible for the conversion of GDP-D-mannose into GDP-L-fucose is recovered only in oocytes and is not present in the other coelomic cells (i.e. coelomocytes). More interesting is the fact that maximum activity is recovered at a well defined stage of the hormone-controlled oogenesis. Thus, this enzymatic system appears as a biochemical marker of the oocyte maturation in P. cultrifera.

On the presence of two non-specific nucleotide-sugar-hydrolysing enzymes in rat liver

Evidence is presented for the occurrence of two different non-specific nucleotide-sugar hydrolases in rat liver and other rat tissues. These two enzymes (I and II) were separated by chromatography on a 5'-AMP-aminohexyl-Sepharose column. Enzyme I is most probably identical with phosphodiesterase I (EC 3.1.4.1). Enzyme II appeared to be identical with an enzyme described in literature as 'CMP-sialic acid hydrolase' [Kean & Bighouse (1974) J. Biol. Chem. 249, 7813-7823], since almost all activity with CMP-N-acetylneuraminate as substrate was recovered in this enzyme fraction. CMP-N-acetylneuraminate was a poor substrate for Enzyme I, whereas deoxythymidine-5'-p-nitrophenyl phosphate and all nucleoside-diphosphosugars tested were good substrates for both Enzyme I and II. Therefore it is suggested that CMP-N-acetylneuraminate is used as an additional substrate to discriminate between the activities of Enzyme I and II in homogenates or membrane preparations. The various substrates appeared to be competitive inhibitors of each other, suggesting that, in each enzyme preparation, only one enzyme is responsible for the hydrolysis of the various substrates. The dissimilar properties of the two enzymes are substantiated by studying the subunit molecular masses (Enzyme I, 125 kDa; Enzyme II, 50-55 kDa), the sensitivity towards Triton X-100, Sarkosyl and sodium dodecyl sulphate and towards trypsin treatment. It is discussed whether the alpha-N-acetylglucosamine phosphodiesterase described by Varki & Kornfeld [(1981) J. Biol. Chem. 256, 9937-9943] is identical with one of the nucleotide-sugar hydrolases described here.

Inhibition of glycosyltransferases by bis-(p-nitrophenyl)phosphate: general effect and relation to their membrane integration

The effect of bis-(p-nitrophenyl)phosphate on various glycosyltransferases involved in protein glycosylation (sialyl-, fucosyl-, galactosyl-, mannosyl- and glucosyltransferases) have been studied using crude enzyme preparations solubilized from rat spleen lymphocytes. Bis-(p-nitrophenyl)phosphate appears as a common inhibitor for every glycosyltransferase reaction utilizing sugar nucleotides as direct donors. In most cases 10 mM inhibitor is sufficient to obtain a 90 per cent inhibition. Kinetic studies achieved with a purified galactosyltransferase preparation reveal that bis-(p-nitrophenyl)phosphate exerts a competitive inhibition towards UDP-galactose binding. Concerning membrane-bound enzymes, the interaction of bis-(p-nitrophenyl)phosphate depends on its accessibility to the enzyme active site. This is shown by the different effect obtained with two UDP-Glc utilizing membrane-bound enzymes : UDP-Glc : phospho-dolichyl glucosyltransferase and UDP-Glc : ceramide glucosyltransferase : the first one not being affected but the second one being markedly inhibited under the same condition, although both are inhibited when the membrane environment is disturbed by detergent. Bis-(p-nitrophenyl)phosphate appears to be a tool to study membrane topology of glycosyltransferases.

Treatment of human cells and interferon has no effect on the glycosylation of viral and cellular proteins

The effect of interferon on the glycosylation of viral and cellular proteins was examined in human cells. Vesicular stomatitis virus released from control and interferon-treated HeLa cells was found to be equally glycosylated. Likewise, interferon treatment of RPMI 8226 cells, a human cell line secreting immunoglobulin G, had no effect on protein glycosylation. In addition, treatment with interferon of RPMI 8226 cells and of lymphoblastoid Daudi cells had no effect on the incorporation of N-acetylglucosamine into dolichol derivatives in a cell-free assay. Similar treatment of HeLa and murine L cells showed an apparent inhibition of this glycosyltransferase activity. This effect of interferon in HeLa cells could at least in part by accounted for by a high nucleotide pyrophosphatase activity, which degraded the sugar nucleotide substrate. These results indicate that interferon does not inhibit protein glycosylation in human cells.

A UDP-glucose:glycoprotein glucose-1-phosphotransferase in embryonic chicken neural retina

A subclass of cell-surface glycoproteins from embryonic chicken neural retina contains a high mannose-type oligosaccharide that terminates with glucose linked via a phosphodiester bond to penultimate mannose. This unusual oligosaccharide seems responsible for the glycoprotein attachments to the cell-surface baseplate ligatin. Using beta-32P-UDP-3H-glucose, we demonstrate in retinal homogenates the existence of a UDP-glucose:glycoprotein glucose-1-phosphotransferase (GlcPTase) that catalyzes the synthesis of such a linkage. Characterization of the doubly labeled product resulting from activity of the transferase reveals a family of endoglycosidase H-sensitive oligosaccharides displaying a cation-exchange profile similar to that of oligosaccharides derived from ligatin-associated proteins synthesized in vivo. Further analysis confirms that the incorporation of label is due to a terminal 3H-glucose joined via a 32P-phosphodiester linkage to carbon 6 of a penultimate mannose. We propose that GlcPTase may be a controlling enzyme for the targeting of certain newly synthesized proteins to the cell surface.

Effect of bis-(p-nitrophenyl) phosphate on the biosynthesis and the utilization of lipid-intermediates

Incubations of rat spleen lymphocytes with the required labelled nucleotide sugars lead to the formation of the various lipid-intermediates involved in the N-glycosylation of proteins. The effect of bis-(p-nitrophenyl) phosphate on the different reactions involved in the dolichol pathway has been studied. Although dolichyl phosphate mannose, dolichyl phosphate glucose and dolichyl diphosphate N-acetylglucosamine synthesis is not affected at all by bis-(p-nitrophenyl) phosphate (20 mM), this product inhibits completely the addition of the second N-acetylglucosamine residue on the dolichyl diphosphate N-acetylglucosamine acceptor. The addition of the five innermost mannose residues from GDP-mannose as donor is also strongly abolished. However, the addition of the more distal sugars, i.e. the four mannose residues using dolichyl phosphate mannose as donors and the additional glucose residues are only slightly affected. The reactions involved in the utilization of dolichyl diphosphate oligosaccharide, i.e. transfer to the proteins or degradation into soluble phospho-oligosaccharides, are also strongly inhibited. Thus bis-(p-nitrophenyl) phosphate appears to affect only the reactions involving the presence of dolichyl diphosphate sugar as substrate.

Studies on the determination of extracellular galactosyltransferase in human intestinal tissue

The determination of extracellular galactosyl transferase (EC 2.4.1.38) activity in human intestinal tissue by assessment of the incorporation of label after incubation with UDP[3H]galactose was evaluated. Intestinal biopsy specimens were incubated with membrane-permeable L-[1-14C]fucose and non-permeable UDP-D-[6-3H]galactose (UDP[3H]Gal). Comparison of the amounts of 3H- and 14C-label incorporated into subcellular fractions showed uptake and incorporation of galactose formed by the hydrolysis of UDP[3H]Gal by brush-border enzymes. The results indicate that incorporation of galactose after incubation of the tissue with UDP[3H]Gal is not exclusively attributable to extracellular galactosyl transferase.

Fate of oligosaccharide-lipid intermediates synthesized by resting rat-spleen lymphocytes

Using conditions to avoid the utilization of labelled precursors by intracellular glycosyltransferases, experiments are described demonstrating that intact rat-spleen lymphocytes are capable of utilizing exogenous GDP-mannose and UDP-N-acetylglucosamine to synthesize dolichyl monophosphate mannose and dolichyl diphosphate oligosaccharides. Kinetic and chase experiments show that dolichyl diphosphate oligosaccharides are either utilized for the transfer of their carbohydrate moieties to protein acceptors or further degraded. Since glycosylation of proteins is limited in resting lymphocytes, the degradation pathway appears as a major event in the fate of the dolichyl diphosphate oligosaccharides synthesized in vitro. These dolichyl diphosphate oligosaccharides are degraded into phospho-oligosaccharides and oligosaccharides which are released in the medium. This enzymatic cleavage of the phosphodiester bond is inhibited by bacitracin. The phospho-oligosaccharides are susceptible to alkaline phosphatase giving neutral oligosaccharides and they are cleaved by endo-N-acetyl-beta-D-glucosaminidase H leaving N-acetylglucosamine 1-phosphate and neutral oligosaccharides. These data suggest that splitting of the phosphodiester bond of colichyl diphosphate oligosaccharides, dephosphorylation and/or endo-N-acetyl-beta-D-glucosaminidase hydrolysis of the phosphorylated oligosaccharides could represent the beginning of the catabolic pathway of dolichyl diphosphate oligosaccharides.

Glycoprotein biosynthesis in intestinal epithelial cells during differentiation. Incorporation of [14C]mannose from GDP-[14C]mannose into dolichol derivatives

Epithelial cells of the rat small intestine were collected as a gradient of villus to crypt cells. Homogenates of these cells incubated with GDP-D-[14C]mannose in the presence of MnCl2 incorporated radioactivity into dolichyl mannosyl phosphate and a mixutre of dolichyl pyrophosphate oligosaccharides varying in the size of their oligosaccharide moiety. The labeled oligosaccharides formed in villus cell homogenates appeared shorter than those formed in crypt cell homogenates. The addition of dolichyl phosphate greatly stimulated the synthesis of dolichyl mannosyl phosphate. The initial rate of synthesis of dolichyl mannosyl phosphate from GDP-D-[14C]mannose and exogenous dolichyl phosphate was highest in an intermediate cell fraction having a low specific activity of sucrase and alkaline phosphatase and an intermediate specific activity of thymidine kinase. To compare the rates of dolichyl mannosyl phosphate synthesis in the different cell fractions, it was essential to control degradation of GDP-D-[14]mannose by the addition of AMP to the incubation, since villus cells degraded GDP-D-[14C]mannose much faster than crypt cells.